PHY 2048 UNIVERSITY PHYSICS I .. ...... The department offers introductory
physics classes (PHY2048 University Physics 1 with. Lab and ...... Midterm Exam
3.
The University of West Florida
Program Self-Study
Department of Physics Review Period 2002-2008
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Table of Contents Introduction: Physics Everywhere ................................................................................... 4 History of the Department of Physics .............................................................................. 5 1. Program Vision, Mission, and Values ................................................................ 8 Vision ........................................................................................................................... 8 Mission and Purpose ................................................................................................... 8 Values.......................................................................................................................... 8 2. Program Goals and Objectives—Statements ..................................................... 9 2.1 Instruction/Learning ............................................................................................ 9 2.2 Scholarship and Creative Activity ....................................................................... 9 2.3 Service ............................................................................................................... 9 3. Program Goals and Objectives-Assessment and Related Actions ............................ 10 Instruction/Learning ................................................................................................... 10 Scholarship and Creative Activity (2002-2008) .......................................................... 13 Service....................................................................................................................... 17 4. Review of Curriculum ....................................................................................... 18 5. Review of Common Prerequisites .................................................................... 22 6. Articulation Within and Outside the University.................................................. 23 7. Enrollment, Retention, and Degree Productivity............................................... 23 8. Resources—Trends and Projection of Need .................................................... 23 8.1 Expense ........................................................................................................... 23 8.2 Personnel – Faculty, Staff, Other ..................................................................... 24 8.3 Library and Other Learning Resources ............................................................ 26 8.4 Information Technology .................................................................................... 26 8.5 Physical - Equipment & Facilities ..................................................................... 26 9. Summary of Major Changes since Previous Program Review ......................... 27 10. Strengths, Weaknesses, and Opportunities ..................................................... 27 10.1 Current Strengths of the Program ................................................................. 28 10.2 Current Weakness of the Program................................................................ 28 10.3 Opportunities ................................................................................................ 29 11. Recommendations/Proposed Action Plans ...................................................... 31 12.
Appendices
Student Learning Outcomes............................................................................... 3 12.1 Student Learning Outcomes (Measures) ..................................................................... 3 Academic Learning Compact ....................................................................................... 4 Assessment Plan(s) ..................................................................................................... 6 Physics Department – Departmental Assessment Plan (General) ........................... 6 Specific Assessment Criteria for Each individual Course ......................................... 9 12.2 Enrollment Trend Data: Headcount, Full Time Equivalent ............................... 11 Degree Productivity Trend Data (see also review of the curriculum)...................... 11 12.3 Retention Data ...................................................................................................... 12
3 12.4 Resource Data: Budget Trend and Personnel Trend Data ............................. 21 12.5 Resource Data: Library and Other Learning Resources Data ......................... 24 Available Scientific Journals Related to Natural Sciences ..................................... 25 12.5 Special Facilities, Special Equipment .................................................................... 30 12.6 Grant/Contract Acquisition Summary .................................................................... 34 External Grants .......................................................................................................... 34 Internal Grants: .......................................................................................................... 38 Summary ................................................................................................................ 38 List of all Internal Grants Applied for (2002-2008) .................................................. 39 12.7 CVs of Faculties of Department of Physics (in random appearance) .................... 40 Chandra Sekhar Prayaga .......................................................................................... 40 James Stephen Marsh ............................................................................................... 53 Brandon Murakami .................................................................................................... 62 Laszlo J. Ujj ............................................................................................................... 66 Guoqing Wu ............................................................................................................... 82 12.8 Syllabi of all Courses Affiliated to the Physics Department ................................... 92 EGM 2500 ENGINEERING MECHANICS-STATICS ................................................ 92 EGM 3401 ENGINEERING MECHANICS-DYNAMICS ............................................ 99 PHY 1020 INTRODUCTION TO CONCEPTS IN PHYSICS ................................... 101 PHY 1020L INTRODUCTION TO CONCEPTS IN PHYSICS LAB .......................... 104 PHY 2048 UNIVERSITY PHYSICS I ....................................................................... 107 PHY 2048L UNIVERSITY PHYSICS I LAB ............................................................. 110 PHY 2049 UNIVERSITY PHYSICS II ...................................................................... 114 PHY 2049L UNIVERSITY PHYSICS II LAB ............................................................ 117 PHY 2053 GENERAL PHYSICS I............................................................................ 121 PHY 2053L GENERAL PHYSICS I LAB .................................................................. 123 PHY 2054 GENERAL PHYSICS II........................................................................... 127 PHY 2054L GENERAL PHYSICS II LAB ................................................................. 129 PHY 3106 MODERN PHYSICS I ............................................................................. 133 PHY 3106L MODERN PHYSICS LAB ..................................................................... 136 PHY 3107 MODERN PHYSICS II ............................................................................ 139 PHY 3220 INTERMEDIATE MECHANICS .............................................................. 142 PHY 3424 OPTICS .................................................................................................. 145 PHY 4250 FLUID MECHANICS............................................................................... 147 PHY 4323 ELECTRICITY AND MAGNETISM I ....................................................... 150 PHY 4325 ELECTRICITY AND MAGNETISM II ...................................................... 154 PHY 4445 LASERS AND APPLICATIONS .............................................................. 158 PHY 4513 THERMODYNAMICS AND KINETIC THEORY ..................................... 161 PHY 4604 QUANTUM THEORY ............................................................................. 163 PHY 4910 INDEPENDENT RESEARCH ................................................................. 165 PHZ 3106 INTERMEDIATE-LEVEL PHYSICS PROBLEMS ................................... 167 PHZ 4113 MATHEMATICAL PHYSICS I ................................................................. 169 PHZ 4114 MATHEMATICAL PHYSICS II ................................................................ 173 AST 3033 MODERN ASTRONOMY ........................................................................ 176 PHZ 3601 SPECIAL RELATIVITY ........................................................................... 178
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Introduction: Physics Everywhere Let us start this self study of our physics program with a short statement about the role and place of physics in the society and in science in general. We feel that we need this statement because, among other reasons, our local area is lacking high tech industry and we encounter deep misunderstanding about natural sciences in every imaginable forum. We are part of the physics society of the nation, represented by the American Physical Society (APS), and honor every value of this society. Physics is crucial to understanding the world around us, the world inside us, and the world beyond us. It is the most basic and fundamental science. Physics challenges our imaginations and leads to great discoveries that change our lives. The computer that you are using and the laser that reads your CDs were developed as a result of basic physics research. Physics encompasses the study of the universe from the largest galaxies to the smallest subatomic particles. Moreover, it’s the basis of many other sciences, including chemistry, oceanography, seismology, and astronomy. All are easily accessible with a bachelor’s degree in physics. The importance of physics isn’t limited to the “hard sciences.” Increasingly, physicists are turning their talents to molecular biology, biochemistry, and biology itself. Even medicine has a niche for physicists, and since medical physicists are hard to come by, they are much in demand. Physics also undergirds many new technologies. Cell phones, the Internet, and MRIs are only a few examples of the physics-based technological developments that have revolutionized our world. Many theoretical and experimental physicists work as engineers, and many electrical and mechanical engineers have physics degrees. A physics education equips a person to work in many different and interesting places—in industrial and government labs, on college campuses, and in the astronaut corps. In addition, many physics grads leave the lab behind and work at newspapers and magazines, in government, and even on Wall Street—places where their problem-solving abilities and analytical skills are great assets. The use and distribution of any or all parts of this statement are encouraged by the American Physical Society.
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History of the Department of Physics The Physics Department opened its doors, along with the rest of the University, in 1967. The charter faculty members were Dr. Palmer L. Edwards*, the first chairman, and Dr. William B. Phillips. The next year they were joined by Drs. Robert N. Rigby* and Richard C. Smith. 1969 saw the arrival of Drs. Marsh and Stafford. All except for Edwards were more or less fresh out of graduate school. Stafford stayed only one year. Stafford was replaced by Dr. Pontius who stayed for several years. Pontius was replaced by Dr. Richard B. Fledderman*, who was transferred to the Physics Department after the dismantling of the Aeronautical Systems Department. When Fledderman suddenly passed on, the line was not filled and still remains as a forgotten vacant line. * Now deceased. The Department saw a period of stability until the retirement of the first University President, Harold B. Crosby. He was replaced by James A. Robinson in 1980. Phillips became interested in administration, and after a semester or two as an intern at Tallahassee he departed for a position west of the Mississippi. The department started a Masters' program, which started well but within a half dozen years had swept the area clear of potential candidates for the master's degree. After pondering a course of action for two years, Robinson completely scrambled the structure of the university, discarding Crosby's original vision. The reorganization involved combining some departments and the Physics Department found itself combined with the Systems Science (now called Computer Science) Department. As a much larger component, Systems Science furnished Dr. Miller as the chairman for the combined departments. Edwards who was replaced as the physics chair began phased retirement. This arrangement mercifully lasted only a year or so, but during this period the physics component of the department suffered another disaster from which it has not yet recovered. Rigby left and was replaced, over vehement protests by the physics component, by a computer type person designed to strengthen the systems part of the department. This replacement eliminated another line from the physics department, which shortly regained its identity. The reorganization soon turned out to be a disaster. This was quickly recognized by Robinson, who returned the university to a more traditional structure. Thus, did the Physics Department regain its independent existence, though now with faculty lines considerably reduced. For a year or so after the retro-reorganization the department was without a chairman and functioned as an Athenian democracy. Finally Smith agreed to assume the Chair. Shortly after Smith had become Chair Harold Norton, a retired Air Force major and WWII bomber pilot, was hired to concentrate on general physics classes and labs. He was an enthusiastic lecturer and became a favorite of most of the students who took his classes and labs. At this time the faculty was reduced to four, Smith, Marsh, Fledderman, and Norton. The decade of Smith's chairmanship was perhaps the most difficult period in the department, due to reduced enrollments and a faculty well below critical mass for a physics department.
6 The Presidency of Morris Marx saw something of a slow turn-around for the department, despite budget problems, which caused the wreckage of the library. Smith was finally allowed to resign the chairmanship and was replaced by Dr. M. C. George, an experienced chairman. Then Dr. Prayaga was hired a year later. After Norton retired, Mr. Robert Brooks, another retired military person, was engaged to look after the general physics I classes and labs. Enrollments began to rise and every couple of years would see a graduating class of majors of half a dozen or more, interspersed with classes of several. Founding of the Physics Alliance of Northwest Florida and the institution of the yearly Physics Olympics had some beneficial influence on this trend. Some funds became available which allowed upgrading of computers to a level which is still below the state-of-the-art units available in other labs. Two new additional tracks, Engineering Physics and Physics with Computer Science option were introduced in 1993. Also, a course in "Independent Research" was added to the major requirement. These steps along with the practice of hiring Physics majors as lab assistants have substantially rejuvenated the program. The establishment of a laser research lab with about $250,000 grant from NSF and the establishment of a separate demonstration lab are two other academic accomplishments since 1993. However, the number of required contact hours increased to such a high level, that it has made significant research by faculty less feasible. In addition, the university's decision to pursue enrollment numbers and FTE's as the primary goal made it increasingly difficult to offer a coherent sequence of physics classes for physics majors. The result has been and is more of a junior college atmosphere than a University environment. After Smith retired, we were allowed to hire Dr. Carl Mungan, a young and energetic person fresh out of graduate school. However he left for an opportunity to teach at the Naval Academy after four years. He was replaced by Dr. Laszlo Ujj, an experienced physicist originally from Hungary. M. C. George will step down from chair at the end of this summer. We are awaiting the appointment of a new Chair by the Dean. The above is reproduced from the History of the Physics department prior to 2002. The period 2002 – 2008 saw several changes in the department. Since the last review period, M. C. George stepped down from Chair and Chandra Prayaga became Chair of the Physics department, primarily because of James Marsh’s reluctance to assume that position. The student strength, which had previously always been hovering around 25 majors spread out over the four years, jumped to forty, and then settled around 35. The primary reason for this change was the stepped up efforts by Chandra to visit the local high schools more often for recruitment. This extra student strength meant that undergraduate research started flourishing. Each batch of students could take up research from where the previous batch left off, leading to the establishment of a few research facilities fabricated by the students with faculty guidance. Notable is the setup of a successful Coherent Anti-Stokes Raman Spectroscopy (CARS)
7 measurement system, based on the Nd:YAG laser pumped Optical Parametric Oscillator (OPO), obtained by the NSF grant of Chandra Prayaga and M. C. George earlier. Laszlo Ujj used his considerable expertise and experience in laser physics and ultrafast spectroscopy to modify the OPO to produce broadband radiation which is essential for coherent Raman spectroscopy. Under his guidance many students learned the theoretical and experimental basis of nonlinear spectroscopy, especially CARS. Laszlo Ujj was tenured and promoted to associate professor in 2005 for his excellent teaching and scholarly activity. Chandra Prayaga supervised students in setting up a thin film spin-coating system, which started measurements of dielectric properties of organic thin films including liquid crystals, and a few waveguiding experiments. It is hoped that with a little help from the university, these measurements can reach the publication level. This period also saw the participation of our students in symposia and conferences in undergraduate research around the country, again under the supervision of Chandra Prayaga and Laszlo Ujj. A notable achievement was the Best Undergraduate Research award won by the poster presented by our students, under the supervision of Laszlo Ujj, at the SPS Zone 6 meeting at the Florida Institute of Technology (2007). The success in undergraduate research also led to a larger number of students getting interested in pursuing graduate studies in research in Physics, and since then our students have been successfully completing graduate studies in leading Universities (e.g. UCF, FSU, Johns Hopkins). Chandra Prayaga also developed an interest in Physics Education research, particularly in design of teaching aids at the K-12 school and college level. The pleasure of these successes has been mitigated by the continuous losses in faculty strength. A physics department with 35 majors is not small, as measured according to any relevant statistics of physics departments around the entire country. We entered the current review period with four full-line faculties (George, Marsh, Prayaga, and Ujj). When M. C. George retired in 2005, the administration saw fit to replace him with only a lecturer, even though the department pointed out that it is not possible to get a well trained physicist with a Ph.D. for a lecturer’s position. Brandon Murakami joined as lecturer in August 2005. He was a particle physics Ph.D., and as expected, once it became clear to him that he was stuck in a no-growth position here, he took the first opportunity to leave, in July 2008. His departure reduced the number of individuals who could teach the upper division courses, but the rest of the faculty (Marsh, Prayaga, Ujj) gamely decided to teach extra courses to keep the program going. Unfortunately, within a month, James Marsh found the increasing paper work that nowadays accompanies teaching not to his liking, and decided to retire, and the department lost one more faculty member, who had served the department practically from the beginning. With the loss of Murakami and Marsh in a short period of time, the department faculty was down to two, and once again, the administration replaced both of the opened positions with one lecturer. Dr. Guoqing Wu, a young fresh Ph.D. from UCLA, joined the department as lecturer in August
8 2008. Prayaga and Ujj are currently teaching at least 5 courses each, every semester, and at the same time trying to keep the research fires burning. In spite of the above facts Laszlo Ujj published several papers with external collaboration, presented scientific results on conferences with student involvement as well as he submitted and co-authored a few proposals. Chandra Prayaga also has been able to publish a number of articles and also submitted several grant proposals in Physics and Math Education in spite of this load. During the last two years, a restructuring of some of the Science departments saw a new entity, The School of Science and Engineering, emerge as a compendium of the Mathematics, Physics, Computer Science, and Electrical and Computer Engineering departments. Under the directorship of Leonard W. ter Haar, it is expected that the SSE will spawn an active interdisciplinary research environment. Hopefully, the Physics department will see some encouragement for all its enthusiasm under the new structure.
1. Program Vision, Mission, and Values
Vision The Physics Department should be a dynamic teaching and research center, which provides students with a challenging, strongly personalized training program while caring for their needs and aspirations, and maintains a creative research environment with significant contributions to the field.
Mission and Purpose 1. To provide high-quality instruction in physics and to train competent physicists who can contribute significantly to the physics and engineering environment in the country. 2. To develop and maintain high standard of research by the faculty and to involve the students in such front-line research activity. 3. To promote awareness of the physics program in the community by outreach and cooperative activities with local schools, community colleges, industries, and defense establishments.
Values The Physics Department is committed to: 1. Quality - of the teaching and research program 2. Integrity - in providing the right kind of training to the students 3. Caring - for the needs and aspirations of the students 4. Attention - to individual potential of each student 5. Innovation - in course development, design, and delivery 6. Involvement - with the community, local schools and industries 7. Teamwork - with faculty, staff, and students working together, and departments working together
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2. Program Goals and Objectives—Statements The program goals of the Department of Physics comply with the goals and objectives of the University: continually developing UWF as a distinctive, comprehensive public university, focused on meeting the educational, research, and service needs of the region.
2.1
Instruction/Learning
a. The goal of the baccalaureate degree of physics programs is to prepare students to embark upon a professional career in physics or a closely related field and to prepare the qualified students for graduate study. b. To provide systematic, high quality training to all physics majors. The minimal list of topics to include is as follows: A. Classical mechanics, B. Electrodynamics, C. Thermodynamics, D. Optics/Photonics, E. Mathematical methods of physics, F. Quantum mechanics, and G. Modern physics. c. To teach i. a whole spectrum of analytical tools to model reality in terms of abstract objects and physical laws, ii. how to analyze and solve many practical problems that will serve the students well in a broad range of professions. d. To generate lifetime interest for a deeper understanding of nature, therefore preparing students to be scientific thinkers in society.
2.2
Scholarship and Creative Activity
Creative activity is an important aspect of the department. Faculties are expected to be involved in scientific research activities in a broader sense. Such research may be in experimental or theoretical physics, teaching methodology, or applied research of industrial and engineering problems. Research should involve undergraduate students.
2.3 Service a. Providing educational support for non-physics major programs within the university by teaching general educational and introductory physics classes.
10 b. Providing technical and consulting support on the fields of expertise for the local higher educational and industrial organizations. c. Promoting and supporting K-12 education on the field of natural sciences within the Pensacola area and beyond. d. Acting on behalf of the university on local and national forums and competitions related to natural sciences, especially to physics.
3. Program Goals and Objectives-Assessment and Related Actions
Instruction/Learning The University of West Florida, College of Science and Technology, and the Physics Department are committed to the assessment process in instruction. Several collegewide and university-wide workshops were conducted to help departments work out an assessment plan. a. Individual class assessment A departmental assessment plan (see appendix pg. 6-10) has been developed in order to help us enhance the teaching effectiveness of specific physics classes. Basically, the assessment process follows the steps: (i) (ii) (iii)
(iv) (v)
Identify student Learning Outcomes (SLO) for each course. Classroom instruction should reflect the SLOs Classroom assessment should be continuous and not based on just exams. Active Learning and Student Engagement should be the main features of the teaching style. Assessment should be based on SLO. At the end of every semester, the faculty meets to discuss the status of our teaching and assessment procedures.
This assessment, together with careful considerations by our faculties, has been used to identify shortfalls in specific classes by content, quality, or teaching methods and it has resulted in several improvements. Most notably, our University Physics classes are taught from the best physics book available, a textbook which came out from an NSF funded didactic and active-learning focused research. Several other, up to date textbooks also have been adapted: Conceptual physics, Thermal Physics, Laser Fundamentals, etc. We do continue to enhance every course in every imaginable way possible.
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b. Assessment of the physics program The most concrete evidence of the success of the overall program lies in the way its students are placed after graduation. During the last six years, the physics program has Number of Students 4
2003 2004 2005 2006 2007 2008
4 1 12 4 4 6
14 Number of Graduated Students
Year of Graduation 2002
Table 1 Histogram of the Graduated Students
12 10 8 6 4 2 0 2002
Figure 1 Histogram of the Graduated Students
2003
2004
2005
2006
2007
2008
Year of Graduation
achieved significant success in student placement. Our best students now are welcome in many industrial and academic institutions. The graduation trend of our physics program is summarized in Table 1 and Figure 1. The department produced 35 BS degrees, an average about 5 per year. The list of the graduated students is in Table 2. As of March 15th 2009, we have only partial information about the exact job or schools of many of our alumni. The last column of the table will be updated as we obtain information. Out of 35 graduated students some are pursuing graduate studies, some already have received Ph.D. or MS degree, some are employed as scientists in research labs, some are holding positions as engineers or company managers, and some are teaching physics or science courses in high schools. Table 2 List of Physics Alumni 2002-2008 Name
Mr. Mark Starling McDaniel Mr. Dmitri Yevgenevitch Krivosheyev Mr. Joshua Ryan Kelly
City
State
Grad year
Degree
Latest Position
Milton
FL
1999 2002
AA BS
Associate of Arts Physics/Engineering
To be updated
Pensacola
FL
2002
BS
Physics
Company Manager
Miami
FL
2008 2008
BS MS
Physics/Comp. Sci. Math. Sci.
MS
12 Mr. Scott Edward Granade Mr. Douglas Troy Durant Mr. Aaron Thomas Wade Mr. Robert Joseph Gurski Ms. Heather Ann Hanson Mr. Ian Curmond Deravariere Mr. Vincent Alexander Ms. Carmela Ann Beslack Mr. Vito Vincenzo Bonelli Mr. Brian Edward Carlton Mr. Daniel Joseph Coker Mr. John Samuel Ezell Mr. David Kenneth Fehling, Jr Ms. Angela Marie Rohrer Ms. Jonida ShtrepiHendricks Ms. Natalie Michelle Simmons Mr. Kevin Andrew Stilwell Mr. Joshua E Barbee Mr. Paul James Harrington Mr. Aaron Lee Williams Mr. Casey Ashford Jones Mr. Christopher
Pensacola
FL
2002
BS
Physics/Engineering
To be updated
Eugene
OR
2003
BS
Physics
High school teacher
Physics
Received Ph.D. from FSU 2008 Physics, post-doctoral position at the University of Cincinnati as of mid October 2008
Tallahassee
FL
2003
BS
Pensacola
FL
2003
BS
Fort Lauderdale
FL
2000 2003
AA BS
Physics/Physical Els. Associate of Arts Physics
Pensacola
FL
2004
BS
Physics/Engineering
To be updated
Pensacola
FL
2005
BS
Physics
Received MS (optics) and in PH.D. program
Altamonte Springs
FL
2005
BS
Physics/Engineering
MS (optics), Norton Groupman?
Pensacola
FL
2005
BS
Physics/Engineering
To be updated
Jay
FL
2005
BS
Physics
Ph.D. graduate student, Biophysics, University of Texas
Milton
FL
2005
BS
Physics/Engineering
Company manager
Shreveport
LA
2005
BS
Physics
To be updated
Baltimore
MD
2005 2003
BS AA
Physics Associate of Arts
Ph.D. graduate student, Physics and Astronomy, Johns Hopkins University, Baltimore
Apo
AE
2005
BS
Physics/Engineering
To be updated
Chesapeake
VA
2005
BS
PhysicsEngineering
Graduate student, MS?
Milton
FL
2005
BS
Physics/Engineering
Milton
FL
2005 2006
BS MA
Valparaiso
FL
2006
BS
Gulf Breeze
FL
2006
BS
Physics
Ph. D. student, Quantum Optics, University of New Mexico
Pensacola
FL
2006
BS
Physics
Military graduate school
Milton
FL
2006
BS
Physics
MS student, mechanical engineering program UAB
Pensacola
FL
2007
BS
Physics
Physics Political Sci./Pub. Ad. Physics
To be updated High school teacher
To be updated
To be updated To be updated
GE technician, company
13 Gilbert Clanton Mr. Bart John Clark Mr. Gary Lee Johns Mr. Tyler Webster Reese Mr. Benjamin Chromik Ms. Elisabeth Susanne Knowles Mr. Daniel James Mallernee Mr. Joshua David Olitzky Mr. Seth Andrew Stanley Mr. Douglas Paul Watson
manager To be updated
Niceville
FL
2007
BS
Physics
Defuniak Springs
FL
2007 2004
BS AA
Physics Associate of Arts
Hattiesburg
MS
2007
BS
Physics
MS program at UAB
Pensacola
FL
2008
BS
Physics/Engineering
To be updated
Pensacola
FL
2008
BS
Physics
Ph.D.
Pensacola
FL
2004 2008
AA BS
Associate of Arts Physics
Boynton Beach
FL
2008
BS
Physics
Milton
FL
2004 2008
AA BS
Associate of Arts Physics/Computatnl
Pensacola
FL
2008
BS
Physics/Engineering
PH.D student, Physics, JHU, Baltimore
Substitute teacher K12 school, Ana, Illinois. Heading to graduate school. Ph.D. student, Optics, University of Arizona Staff scientist at ANYAR incorporated, Niceville, Florida Cell: 850 313 6691 High school teacher, Panama City, starting mechanical engineering MS at UAB, Fall 2009.
Scholarship and Creative Activity (20022008) All members of the physics department are engaged in creative activities, e.g. instrument development, analyses, control, educational computer program development, or just solving an important theoretical problem. Many of our results are not published, because of the nature of the activities. However, all of these activities involve students and they learn a lot and enhance their problem solving abilities and instrumentation skills by solving partial problems one-by-one and working in a team where they can gather project management skills. We would be delighted to talk about these activities and show the actual instruments or outcome during the reviewer visit. Those results that are worth to be presented to the scientific community are published under the name of the authors in the following list. The results, published and unpublished, provide an overall assessment of the creative activities of the department (see also CVs of our faculties: Appendices pgs. 40-82.)
1. Chandra Prayaga Ph.D., Associate professor (tenured in 1994), Publications: Total 53, 22 in refereed journals, 2 articles in books, 29 in proceedings of symposia
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Recent Publications (2002-2008): 1. Carol Briscoe and Chandra Prayaga, Developing a Physics Course for Elementary & Middle level Education Majors: Evolution of One Teacher’s Enacted Curriculum, 2002 AETS Annual International Meeting January 10-13, 2002 – Charlotte, NC 2. Carol Briscoe and Chandra S. Prayaga, Teaching Future K-8 Teachers the Language of Newton: A Case Study of A Physics Professor’s Beliefs and Practices, NARST 2002 Conference, New Orleans, April 7-10, 2002 3. Chandra Prayaga, “An interactive tutorial for Isothermal Processes” ELEARN2003 4. Chandra Prayaga, “An interactive tutorial for Oscillations” EDMEDIA-2004 5. Carol Briscoe and Chandra S Prayaga, "Teaching Future K-8 Teachers the Language of Newton: A Case Study of Collaboration and Change in University Physics Teaching," Sci Ed 88, pp 947-969 (2004). 6. Chandra Prayaga, “Monte-Carlo Method and the 2-d Ising Model” MAPLE Conference July 17-21, 2005, Waterloo, Canada 7. Chandra Prayaga, "A Visual Basic – VPython Interface", American Association of Physics Teachers Winter Meeting, 2007 8. Chandra Prayaga, "Interactive Simulation of Simple Harmonic Motion with VPython and Excel Controlled by VBA", ED-MEDIA 2007 conference, Vancouver, BC, Canada 9. "Preparing content-rich learning environments with VPython and Excel, controlled by Visual Basic for Applications", Phys. Educ. 35, 88-94 (2008)
2. James Marsh Ph.D., Professor Emeritus (tenured in 1973, retired in 2008), Total Number of publications 67, 22 Pier reviewed papers , 25 Conference digests, 20 unpublished Talks (2002-2008): “Derivation of a measuring master equation.” 31 October 2002. 69th annual meeting of the Southeastern Section of the American Physical Society, Auburn University, Auburn, Alabama
15 “Non-interactive measurement in quantum theory. Light Bombs.”, SPS meeting,UWF (2002) “Quantum Entanglement.”, SPS meeting (2002) “Holography for the seriously uninformed.”, SPS meeting (2002) “Left handed materials, and negative indices of refraction.”, SPS meeting (2002) “Non-interactive measurement in quantum theory. Light Bombs.” SPS meeting, UWF (2003) “Quantum Entanglement” SPS meeting, UWF (2003) “Holography for the seriously uninformed” SPS meeting, UWF (2003) “ Left handed materials and negative indices of refraction.”, SPS meeting, UWF (2003) “Quantum Teleportation: Is it the same as the usual kind?”March 16, 2005, UWF, The Socratic Society Unpublished Memoirs (2002-2008): “Rotating Straight String” (14 pages) (2005) “Some problems in Electricity and Magnetism than can be worked by elementary methods.” (18 pages) (2005) “Some problems in Electricity and Magnetism than can be worked by elementary methods.” (18 pages) (2006) “How to quantize a beam of light” (13 pages) (2006) “A Huygen’s principle for light waves” (17 pages) (2006) “The geometrical optics of left handed materials.” (22 pages) (2006) “Quantum measurement and the quantum eraser: Part 1 Measurements in quantum optics” (25 pages) (2006) “Quantum measurement and the quantum eraser: Part 2 The quantum eraser” (20 pages) (2006) “On the structure of the Photon” (35 pages) (2007)
16 3. Laszlo Ujj Ph.D., Associate Professor (tenured in 2005), Total Number of publications ~55, 37 Cited publications (see SciFinder) , Conference Presentations ~24, Number of Citations: ~400 Recent Publications (2002-2008): Laszlo Ujj, "The Physics of Coherent Raman Spectroscopy”, lecture at the March meeting of the American Physical Society, New Orleans, March 2008. D. Watson, J.D. Olitzky, E. Knowles, L. Ujj, "Polarization Sensitive CARS Analysis of Molecular Vibrational Spectra” at the SeaStars, UWF (2008). Josh Olitzky, Chris Clanton, Dr. Laszlo Ujj,”Investigations of Coherent Anti-Stokes Raman Spectroscopy”, Dean's Award for Collaborative Research, UWF (2007). J.D. Olitzky, C. Clanton, L. Ujj, "Development of Coherent anti-Stokes Raman Spectroscopy” at the SPS Zone 6 meeting at the Florida Institute of Technology, (2007). The poster won the best undergraduate research award. A . C. Terentis, L. Ujj, H. Abramczyk, G.H. Atkinson “Primary Events in Bacteriorhodopsin Photocycle: Torsional Vibrational Dephasing in the First Excited Electronic State”, Chemical Physics, 313, 51-62, (2005). A. C. Terentis, Y. Zhou, G. H. Atkinson, L. Ujj, “Picosecond Time-Resolved Coherent Ant-Stokes Spectroscopy of the Artificial Bacteriorhodopsin Pigment, BR6.11”, J. Phys. Chem. A, 107, 10787-10797 (2003). G. H. Atkinson,Y. Zhou, L. Ujj, A. Aharoni, M. Sheves, and M. Ottolenghi, Dynamics and Retinal Structural Changes in the Photocycle of the Artificial Bacteriorhodopsin Pigment BR6.9, J. Phys. Chem. A, 106, 3325-3336 (2002) Laszlo Ujj and George H. Atkinson, “Coherent Anti-Stokes Raman Spectroscopy”, in Handbook of Vibrational Spectroscopy, John Wiley & Sons., Ltd., January 2002 Laszlo Ujj, Colin G. Coates, John M. Kelly, Paul E. Kruger, John J. McGarvey, and George H. Atkinson, “Picosecond Coherent Vibrational Spectroscopy (CARS) of a DNAIntercalating Ru Complex”, J. Phys. Chem. B,106, 4854-4862 (2002).
4. Brandon Murakami Ph.D., Instructor (2005-2008), Total Number of Publications 8, Conference and workshop participation 16, Seminars 7.
17 Colloquium: “A Commercial Advertisement for Particle Physics,” University of West Florida, Pensacola, FL, June 24, 2005.
5. Guoqing Wu Ph. D., Instructor (2008 - present), Total Number of publications 34, Pier reviewed 13, Conference presentations 21, Number of Citations ~40. Journal Referee of Phys. Rev. B and Phys. Rev. Letters.
Service •
Conceptual Physics (Internet), General Physics 1 and 2, University Physics 1 and 2, and Physics Laboratory 1 and 2 classes offered for non physics majors every semester. These classes are always full and have 30-50 students enrolled in each.
•
Holography workshop for high school students and teachers.
•
Sponsorship of the annual “Physics Olympics” competition.
•
Several presentations and talks in local high schools (recruitment).
•
Participation in organizing and executive committees of the university
18
4. Review of Curriculum The curriculum focused around three connected Physics Tracks. Table 3 shows the distribution of students in each track. Our most popular track is the Regular Physics Track, but the track combined with Table 3 engineering classes is catching up. There Physics Track Number of Students is no time to teach too many advanced Physics 20 fields of physics within the 120 credit limit Physics/Engineering 12 of the BS degree. However, beyond the Physics/Computational 3 core classes (Modern Physics, Intermediate Mechanics, Electricity and Magnetism, Thermodynamics, Quantum Mechanics, and Mathematical Physics), we offer several attractive specializations: Optics, Engineering Mechanics, Lasers and Applications. Our faculties also offer elective classes for individuals or small groups of students (solid-state physics, system automation (LabView), Laser Spectroscopy, Quantum Optics, etc). Table 4 shows the curriculum of each track. Students who completed the lower division, 60-credit requirement can start the physics track. A copy of the syllabi of all classes is presented in the Appendices (chapter 12th). The content of each class follows the general requirements of a physics BS and sometimes goes beyond that in order to give a guide to students for future studies. The department offers introductory physics classes (PHY2048 University Physics 1 with Lab and PHY2049 University Physics 2 with Lab) every semester; therefore students can take these classes any time. Offering of the upper level (major) classes should be done in a sequence, considering the interdependences of the classes. In every university with enough qualified faculty, the core classes are offered every year, therefore students who completed the prerequisite can take the class. Unfortunately, our physics department cannot offer the core classes often enough. Probably, because of financial constraints of the university we encountered a decaying number of faculties over the 2002-2008 period (see Appendices pgs. 21-23, budget data). The course offering plan had to be revised to accommodate the new situation. A class offer plan had been developed by taking into account the prerequisites, the number of classes, and the maximum number of faculty loads available. As a final result we could offer the necessary core classes every second year. Some introductory classes were passed to adjunct faculties and all faculties of the department have been giving elective, independent studies, and research classes as voluntary contributions. Our faculties have the necessary scientific knowledge to offer several graduate-level physics classes on e.g. solid state physics and photonics and to start a master degree program. (See the Opportunities chapter for further details.) However, the establishment of this higher level program would require hiring new faculties and some investment for experimental labs. The tangible part of this problem will be solved when we move to the new SSE building in 2010.
19 Table 4 DEPARTMENT OF PHYSICS DEGREE PLAN - REGULAR TRACK CURRICULUM - 2008/2009 STUDENT NAME: STUDENT NUMBER:
DATE: CATALOG YEAR:
SPECIFIC REQUIREMENTS FOR GRADUATION (Check when completed) ( ) 24 SH UPPER DIVISION IN MAJOR ( ) 18 SH UPPER DIVISION IN MAJOR AT UWF ( ) 48 SH UPPER DIVISION ( ) 30 SH RESIDENCY AT UWF ( ) OVERALL GPA & MAJOR GPA OF 2.0 ( ) PHYSICS PROGRAM REQUIREMENTS ( ) SATISFY CLAST REQUIREMENT ( ) SUMMER HOURS REQUIREMENT: 9 HRS ( ) SATISFY GORDON RULE REQUIREMENT ( ) SATISFY FOREIGN LANGUAGE REQUIREMENT ( ) TOTAL OF 120 SH FOR DEGREE ( ) GENERAL STUDIES ( ) MULTICULTURAL REQUIREMENT (3SH)
REQUIRED PHYSICS
ADVISOR:
PHY 3106 MODERN PHYSICS I 3 PHY 3106L MODERN PHYSICS LAB 2 PHY 3107 MODERN PHYSICS II 3 PHY 3220 INTERMED. MECHANIC 4 PHY 3424 OPTICS 3 PHY 4323 ELECTRICITY & MAG. I 3 PHY 4325 ELECTRICITY & MAG. II 3 PHY 4445 LASER & APPLICATION 3 PHY 4513 THERMO 3 PHY 4604 QUANTUM THEORY 3 PHY 4910 INDEPENDENT RESEA 2 PHZ 3106 INTERM. PHY. PROBLEM 1 PHZ 4113 MATH PHYSICS I 3 PHZ 4114 MATH PHYSICS II 3 3000/4000 PHYS. ELECTIVE(PHY,PH 4 TOTAL PHYSICS 43 SH
LOWER DIVISION REQUIREMENTS MATHEMATICS/COMP SCI/ENGINEERING NATURAL SCIENCE CHM 2045 CHEMISTRY I/LAB CHM 2046 CHEMISTRY II/LAB
4 4 8 SH
PREREQUISITES MAC 2311 ANAL. GEOMETRY & CAL MAC 2312 ANAL. GEOMETRY & CAL MAC 2313 ANAL. GEOMETRY & CAL PHY 2048 UNIV. PHYSICS I W/LAB PHY 2049 UNIV. PHYSICS II W/ LAB COMP SCI ELEC. (JAVA,C++)
TOTAL LOWER DIVISION
4 4 4 4 4 3 23 SH
EEL 3111 CIRCUITS I EEL 3303L ELECTRIC CIRCUITS LA MAD 4401 NUMERICAL ANAL. MAP 2302 DIFF. EQUATIONS MAS 3105 LINEAR ALGEBRA 3000/4000 PHYSICS/MATH ELECTIV
3 1 3 3 3 4
TOTAL MATH/COMP SCI/ENG.
17 SH
TOTAL REQUIRED PHYSICS
60 SH
COURSE SUBSTITUTIONS:
60 SH
STUDENT SIGNATURE
DATE
TOTAL DEGREE SEMESTER HOURS
ADVISOR SIGNATURE
DATE
DEPARTMENT CHAIRMAN SIGNATURE
(REVISED 8/24/05)
120 SH
DATE
20 DEPARTMENT OF PHYSICS DEGREE PLAN - ENGINEERING TRACK CURRICULUM - 2008/2009 STUDENT NAME:______________________________ STUDENT NUMBER: __________________________
DATE: ___________________________ ADVISOR: ___________ CATALOG YEAR:
SPECIFIC REQUIREMENTS FOR GRADUATION (Check when completed) ( ) 24 SH UPPER DIVISION IN MAJOR ( ) 18 SH UPPER DIVISION IN MAJOR AT UWF ( ) 48 SH UPPER DIVISION ( ) 30 SH RESIDENCY AT UWF ( ) OVERALL GPA & MAJOR GPA ABOVE 2.0 ( ) PHYSICS PROGRAM REQUIREMENTS ( ) SATISFY CLAST REQUIREMENT ( ) SUMMER HOURS REQUIREMENT: 9 HRS ( ) SATISFY GORDON RULE REQUIREMENT ( ) SATISFY FOREIGN LANGUAGE REQUIREMENT ( ) TOTAL OF 120 SH FOR DEGREE ( ) GENERAL STUDIES ( ) MULTICULTURAL REQUIREMENT(3SH)
REQUIRED PHYSICS: EGM 3512 ENGINEERING MECHAN PHY 3106 MODERN PHYSICS I PHY 3106L MODERN PHYSICS LAB PHY 3107 MODERN PHYSICS II PHY 3424 OPTICS PHY 4250 FLUID MECHANICS PHY 4323 ELECTRICITY & MAGNET PHY 4325 ELECTRICITY & MAGNET PHY 4513 THERMODYNAMICS PHY 4910 INDEPENDENT RESEAR PHZ 3106 INTERMED PHY. PROBL PHZ 4113 MATH PHYSICS I PHZ 4114 MATH PHYSICS II
4 3 2 3 3 3 3 3 3 2 1 3 3
TOTAL PHYSICS
36 SH
LOWER DIVISION REQUIREMENTS: NATURAL SCIENCES CHM 2045 CHEMISTRY I/LAB CHM 2046 CHEMISTRY II/LAB
4 4 8 SH
PREREQUISITES: MAC 2311 MAC 2312 MAC 2313 PHY 2048 PHY 2049
ANAL. GEO. & CALCULU ANAL. GEO. & CALCULU ANAL. GEO. & CALCULU UNIV. PHYSICS I W/LAB UNIV. PHYSICS II W/ LAB
4 4 4 4 4 20 SH
STUDENT SIGNATURE
DATE
ADVISOR SIGNATURE
DATE
(REVISED 8/24/05)
MATHEMATICS/COMP SCI/ENGINEERING EEL 3111 CIRCUITS I 3 EEL 3303L ELECTRIC CIRCUITS LAB 1 EEL 3304 ELECTRONIC CIRCUITS 3 EEL 3701C DIGITAL LOGIC & COMP 4 EEL 4304L ELECTRONICS LAB 1 MAD 4401 NUMERICAL ANALYSIS 3 MAP 2302 DIFFERENTIAL EQUATIO 3 MAS 3105 LINEAR ALGEBRA 3 COP 2253 PROG. USING JAVA OR COP 2334 PROG. C++ NONMAJOR 3 SH TOTAL MATH/COMP SCI/ENG. 24 SH TOTAL REQUIRED 60 COURSE SUBSTITUTIONS:
TOTAL DEGREE SEMESTER HOURS
120 SH
DEPARTMENT CHAIRMAN SIGNATURE
DATE
21 DEPARTMENT OF PHYSICS DEGREE PLAN - COMPUTATIONAL PHYSICS TRACK CURRICULUM - 2008-2009 STUDENT NAME:
DATE:
STUDENT NUMBER:
CATALOG YEAR:
SPECIFIC REQUIREMENTS FOR GRADUATION
REQUIRED PHYSICS
ADVISOR:
(Check when completed) (
)
24 SH UPPER DIVISION IN MAJOR
(
)
18 SH UPPER DIVISION IN MAJOR AT UWF
PHY 3106
MODERN PHYSICS I
3
(
)
48 SH UPPER DIVISION
PHY 3106L
MODERN PHYSICS LAB
2
(
)
30 SH RESIDENCY AT UWF
PHY 3107
MODERN PHYSICS II
3
(
)
OVERALL GPA & MAJOR GPA OF 2.0
PHY 3220
INTERMEDIATE MECHANICS
4
(
)
PHYSICS PROGRAM REQUIREMENTS
PHY 4323
ELECTRICITY & MAG. I
3
(
)
SATISFY CLAST REQUIREMENT
PHY 4325
ELECTRICITY & MAG. II
3
(
)
SUMMER HOURS REQUIREMENT: 9 HRS
PHY 4513
THERMODYNAMICS
3 3
(
)
SATISFY GORDON RULE REQUIREMENT
PHY 4604
QUANTUM THEORY
(
)
SATISFY FOREIGN LANGUAGE REQUIREMENT
PHZ 4113
MATH PHYSICS I
3
(
)
TOTAL OF 120 SH FOR DEGREE
PHZ 4114
MATH PHYSICS II
3
(
)
GEN. EDUCATION/GEN. STUDIES/CORE
3000/4000 PHYSICS ELECTIVE
(
)
MULTICULTURAL REQUIREMENT (3SH)
3
LOWER DIVISION REQUIREMENTS
TOTAL PHYSICS
33
SH
MATHEMATICS/COMP SCI/ENGINEERING NATURAL SCIENCE CHM 2045 CHEMISTRY I/LAB
4
CHM 2046 CHEMISTRY II/LAB
4 8
SH
PREREQUISITES
COP 2253
PROGRAMMING USING JAVA
3
COP 3022
INTERMED. COMPUTER PROGRAMMING
3
COT 3100
APPLICATION OF DISCRETE STRUCTURE
3
MAD 4401
NUMERICAL ANALYSIS
3
MAP 2302
DIFFERENTIAL EQUATIONS
3
MAP 4103
MATHEMATICAL MODELING
3
MAP 4341
PARTIAL DIFFERENTIAL EQUATIONS
3
MAS 3105
LINEAR ALGEBRA
3
3000/4000 MATH OR PHYSICS ELECTIVE 3 MAC 2311 ANAL. GEOMETRY & CAL. I
4
MAC 2312 ANAL. GEOMETRY & CAL. II
4
MAC 2313 ANAL. GEOMETRY & CAL. III
4
PHY 2048 UNIV. PHYSICS I W/LAB
4
PHY 2049 UNIV. PHYSICS II W/ LAB
4
COMP SCI ELEC. (JAVA,C++)
3 23 SH
TOTAL LOWER DIVISION
27 SH
TOTAL REQUIRED PHYSICS
60 SH
COURSE SUBSTITUTIONS:
60 SH
STUDENT SIGNATURE
DATE
ADVISOR SIGNATURE
DATE
(REVISED 8/24/05)
TOTAL MATH/COMP SCI
120 SH
DATE
22
5. Review of Common Prerequisites Common Prerequisites (28 sh) State mandated common prerequisites must be completed prior to graduation, but are not required for admission to the program. Courses in brackets indicate substitutes from Florida public community/junior colleges and universities. +CHM 2045/L General Chemistry I/Lab ............................... 4 sh [CHM X045/L, CHM X045C, CHM X045E or both CHM X040 and CHM X041] +CHM 2046/L General Chemistry II/Lab .............................. 4 sh [CHM X046/L, CHM X046C, CHM X046E] +MAC 2311
Analytic Geometry & Calculus I .................... 4 sh [MAC X311, MAC X281]
+MAC 2312
Analytic Geometry & Calculus II ................ ... 4 sh [MAC X312, MAC X282]
MAC 2313
Analytic Geometry & Calculus III ................... 4 sh [MAC X313, MAC X283]
+PHY 2048/L University Physics I/Lab ..................................4 sh [PHY X048C, PHY X048/L] +PHY 2049/L University Physics II/Lab ..................................4 sh [PHY X049C, PHY X049/L] + Indicates common prerequisites which can be used to satisfy UWF General Studies requirements. Note: 1) The above common perquisites are for students in Bachelor of Science degree physics programs. 2) For students with Minor in physics programs the above common prerequisites are not needed prior to graduation. Instead, they are required to take 15 semester hours of physics courses above 3100 level to compliment their majors. 3) For Associate degree in physics programs, students must choose and complete 8 semester hours of the above common prerequisites in total prior to graduation, but are not required for admission to the program. Any of the above courses are accepted. 4) For future Master degree in physics program the common prerequisite would be the completion of the BS degree and a few additional classes e.g. crystallography.
23
6. Articulation Within and Outside the University See service activity of the Department.
7. Enrollment, Retention, and Degree Productivity There is an average about 35 BS degree seeking students (see Appendix pg.11) over the review period, 2002-2008. This number is increasing since 2007 and we have about 40-45 physics students in 2009. The number of non-degree seeking students is roughly 3 every year. The department awards 5-6 BS degrees every year, therefore the dropout rate is about 45-50% (see retention data Appendices pgs.12-20.). There are several natural reasons to leave the physics track, however, the main reason of this high dropout is that the department does not offer the upper division classes often enough. The students do not have the patience to wait a couple of semesters for the classes they need for graduating as physics majors. Because of the low number of faculty, the department cannot offer the upper division classes more often. Out of the remaining physics students about 80% are ready to enter graduate school with TA and research experience gathered by working under supervision of our faculties.
8. Resources—Trends and Projection of Need
8.1 Expense
The personal and budget data are summarized on pages 21- 23 in the appendices. The full time instructional 9-mth Faculty Salary without benefits follows the trend of change in the number of faculties and decreased from $259,113 to $157,202 over the 6-year period from 2002 to 2008. The department uses student assistants and adjunct instructors to compensate the increased faculty load and to make the department operational. The cost of student assistants increased from $12,330 (2002) to 28,441 (2008). The total adjunct cost is between $55,977 and $68,324. This variation is attributed to some rearrangements of the classes. No data is available for 2007 and 2008. The non-personal total budget of the department dropped to $13,500 (2008/2009) from $15,000 (2006/2008) as a result of the general budget cut of the university. Summer employment is an important part of the life of the department. The numbers in the chart on page A-21 reflect the instructional cost of the introductory (lower division) physics courses offered every summer.
24
8.2 Personnel – Faculty, Staff, Other FACULTY and STAFF of the Physics Department NAME
DEGREE
ACTIVE
NONACTIVE
PROFESSION
YEARS OF SERVICE
Chandra Sekhar Prayaga
Ph.D.
X
Chairman, Associate Professor
18 yrs
Laszlo Ujj
Ph.D.
X
Associate Professor
8 yrs
James S. Marsh
Ph.D.
Professor Emeritus
40 yrs
Guoqing Wu
Ph.D.
Instructor
6 mos.
Brandon Murakami
Ph.D.
Instructor
3 yrs
X
X
X
William Caplinger
X
Lab Manager
19 yrs.
Sharon Meador
X
Office Administrator
27 yrs.
25
Adjunct Faculties of the Department of Physics
NAME
James T. Burdette
William Brantley
DEGREE
ACTIVE
BS
Ph.D.
William W. Dyess
Ph.D.
Daniel T. Garber
Ph.D.
Alla Krivosheyeva
Ph.D.
James S. Marsh
Ph.D.
Greg Moore
BS
NonACTIVE
X
X
CLASSES TAUGHT
PHY 2048 Univ. Phy. I, PHY 2048L Univ. Phy. I Lab, PHY 2053L General Phy. I Lab PHY 2048L Univ. Phy. I Lab
X
YEARS OF SERVICE
10 yrs
1 yr.
PHY 4250 Fluid Mechanics
1 yr.
X
PHY 2048L Univ. Phy. I Lab, PHY 2053 Gen. Phy. I
6 yrs
X
PHY 2054L Gen. Phy. II Lab PHY 2049L Univ. Phy. II Lab
9 yrs
x
PHY 4323 Elect. & Mag. I PHY 4325 Elect. & Mag. II
3 yrs
X
PHY 2049L Univ. Phy II Lab
12 yrs.
PHY 2053L PHY 2054L PHY 2048L PHY 2049L PHY 1020L PHY 3106L
7 yrs
X
Gen Phy I Lab Gen Phy. II lab Univ. Phy. I Lab Univ Phy II Lab, Concepts in Phy. Lab, Mod Phy. Lab
Allen Richardson
MS
Arthur C. Schang
BS
X
PHY 2053L General Physics I Lab PHY 2048L University Physics I Lab
approx 15
Edward C. Taylor
Ph.D.
X
PHY 1020 Concepts in Physics
2 yrs
Jimmy Touma
Ph.D.
X
PHY 2054L Gen Phy II Lab PHY 2049L Univ Phy II Lab
1 yr
John W. Wooten
Ph.D.
X
AST 3033 Modern Astronomy
27 yrs.
Joseph Zayas
Ph.D.
X
EGM 2500 Eng Mechanics - Statics EGM 3401 Eng Mechanics - Dynamics
28 yrs
26
8.3 Library and Other Learning Resources
The University of West Florida Libraries include the John C. Pace Library, the primary facility on the main campus in Pensacola, the Emerald Coast Library, located in Fort Walton Beach, and the Curriculum Materials Library and the Music Library, which are also located on the main campus. Housing more than 752,000 volumes, 1.2 million microforms, 5,100 serial subscriptions and providing access to thousands of full-text electronic journals, the library is also designated as a regional depository for publications of the United States government and the state of Florida. Members of the library staff are available to assist in the use of all library materials and the expanding new information technology, including online catalogs and databases, the Internet, document delivery systems, and other computer-based reference sources. The library also provides research assistance for faculties and students. The list of physics related scientific journals directly accessible from online databases is on pages 25-29 in the Appendices. Because of the large subscription cost associated to these online journals (E-journals) there is a limited full page access available, although great progress was made during the last six years. We are dependent on the Interlibrary Loan System. The delivery time to get a copy of a “non-clickable” article varies from a few days to weeks. Interlibrary Loan system locates and delivers non-UWF owned materials to support the research needs of UWF faculty, students, distance learners and staff.
8.4 Information Technology Computers located at the physics department are linked directly to the university network system. Our physics labs use both Macs and PCs. There is no supercomputer access available for the department.
8.5 Physical Equipment & Facilities Our department is located in building 13, third floor. We have one teaching lab, a classroom combined with a lab, and several offices. Two rooms are reserved for research equipment facilities. This situation, however, will change when we will move to a new building, spring 2010. There will be several classrooms and new research facilities in the School of Science and Engineering. The present equipment list is presented in the Appendices (pgs. 30-A33).
27
9. Summary of Major Changes since Previous Program Review 1. The student strength, which had previously always been hovering around 25 majors spread out over the four years, jumped to forty, and then settled around 35. 2. More of our graduates have been admitted to graduate studies in Physics. 3. Start of new research program in Physics Education (specifically in design of computer aided teaching aids in Physics). 4. As indicated in the Department Strategic Plan (2002) the department has submitted a large number of (more than 10) proposals to USED, NSF and FLDOE during this period. One proposal (“Math Matters in Careers” with the award amount of $ 1.5 million from FLDOE) in which Chandra Prayaga was coPI, was granted. 5. Laszlo Ujj has successfully supervised undergraduate research, developed a CARS system, and expended our laser spectroscopy prospect in an effective way based upon our existing equipment. 6. Undergraduate research has progressed successfully. Notable achievement was the Best Undergraduate Research award won by the poster presented by our students, under the supervision of Laszlo Ujj, at the SPS Zone 6 meeting at the Florida Institute of Technology (2007). 7. A restructuring of some of the science departments saw a new entity, The School of Science and Engineering, emerge as a compendium of the Mathematics, Physics, Computer Science, and Electrical and Computer Engineering departments. This re-organization was done with a view to increase interdisciplinary collaboration. Indeed all the proposals submitted by the Physics department were in collaboration with other departments. 8. The department saw a gradual decrease in faculty strength. At the beginning of the current review period, the faculty strength was 4 full-line faculty plus one lecturer. Now it is down to 2 full-line faculty plus one lecturer. This reduction has resulted in the faculty teaching 5 courses in a semester, having to continue supervision of UG research, preparation of grant proposals, continuing their own research, and providing service for the university.
10.
Strengths, Weaknesses, and Opportunities
The BS physics program is comparable to any other physics programs available at other universities in the US. However, our program provides special training of specific fields (see below) and unique opportunities of continuing education for the qualified students.
28
10.1 Current Strengths of the Program •
Provides excellent service for non-physics major programs: the introductory (lower division) physics classes are well developed and our physics majors and faculties provide out-of-class tutoring
•
Offers specializations in material sciences, optics, laser physics, mechanics
•
Serves not only the local community but students from the nearby military base
•
Prepares for graduate school (see e.g. alumni achievement)
•
Provides an enhanced education of developing analytical skills that hiring officers strongly consider (if not physics)
•
Provides a comprehensive, high quality academic program
•
Offers three different tracks to cater to student needs and interests
•
Provides balance of theoretical and experimental training
•
Provides training by outstanding faculty
•
Offers opportunities to students to participate in research activities and in research symposia
•
Provides the training necessary to pursue graduate studies or to enter the job market.
•
Offers a research atmosphere in lasers and materials science research, which are among the foremost fields of research today. All the faculties are specialists in different areas of these fields.
10.2 Current Weakness of the Program •
There is some mismatch between the lower division laboratory classes and lecture classes.
29 •
The major courses are not offered frequently enough because of lack of sufficient number of faculties. Allocation of teaching duties also becomes uncertain.
•
The lack of faculty also makes it very difficult for the existing faculty, who are overloaded with teaching duties, to concentrate on research and grant proposal preparation activities.
•
We need to be able to offer a stable atmosphere to students. The continuous decrease in faculty strength generates a doubt in the students’ minds about our ability to offer a complete and well-rounded program.
•
Lack of faculty has also restricted our recruitment and grant seeking efforts. The same faculty member cannot teach 5 courses a semester, visit 4 or 5 schools a semester, carry out UG research supervision, continue his/her research, and prepare at least one grant proposal per semester.
•
The lack of a full-time active secretarial staff in the department further increases the load on the faculty, particularly in producing all the reports required by the administration.
10.3 Opportunities The fact that currently the Physics Department is low on faculty strength should not deter us from making plans for the future and acting on them. A well executed action plan which results in one or more of (a) increased FTE, (b) increased major strength, (c) successful research grants, will always result in a rewarding future for the department. With this in mind, we need to investigate the following possibilities: (a) Increased FTE: Current situation: Our efforts to increase FTE will need to concentrate on the service courses, including the Academic Foundations (Gen-Ed) courses. Of these classes, PHY1020 (Concepts in Physics) was originally started by Chandra Prayaga as a course intended for pre-service Science teachers, and has since been generalized as an online Academic Foundations course open to all by Laszlo Ujj, and is highly successful. The class is always full, often up to a strength of 60, and offered fall, spring and summer. A course on “Exotic Physics”, started by Brandon Murakami, had to be abandoned after his departure. Future prospects and opportunities: For the immediate future, Prayaga is about to offer the service courses General Physics I and II as online courses during summer 2009. Depending on the response, and the pedagogical suitability of the course, this e-learning class could be continued. If the course
30 is made sufficiently attractive, it could draw many of the students currently taking the equivalent courses in the Junior Colleges. Caution: The pedagogical suitability of an online course at this level needs to be carefully discussed. Also, we need to discuss the possibility and suitability of offering an online “Virtual Laboratory” in place of the lab courses being offered along with the General Physics I and II courses. Prayaga is also in the process of designing a “Physics of Current Technology” course at the Academic Foundations level to replace the discontinued Exotic Physics. (b) Increased major strength: Current situation: An undergraduate only Physics program with 35 – 40 majors is by no means a small program according to national standards. Every effort must be made to further increase the strength. The current enrollment is being maintained by strong recruitment efforts on the part of the faculty and staff. Prayaga and Caplinger are for the most part keeping up the visits to schools, whereas Ujj (and now Wu) are handling most of the visits made by schools to the department. The entire faculty and staff participate in the “Open House” and “Majors Fair” meetings held at the university. Prospects and opportunities: The recruitment efforts will be highly energized by further involvement of the local chapter of the SPS. Without its help, it is physically impossible for us (with our current faculty strength) to increase our recruitment efforts. We need to make specific moves to send teams of physics majors on recruitment visits to schools. Restructuring the curriculum into an integrated 5-year Masters degree program, perhaps with collaboration with UCF. The physics department could offer the Master of Science degree in Photonics/Material Technology, Physics (and Math) Teacher Certification, or both. Prayaga has started discussions with the teacher education department of UWF regarding the latter. Ujj has started to work on the details of the photonics program and Wu will work on the material technology part. Many of our graduates have enquired about a Masters degree offered by the department, and the EGLIN Air Force Base has also shown interest in such a program. The possibility of graduate studies will automatically increase the undergraduate enrollment.
(c) Successful Research Grants: Current situation: The strength of physics should be shown and seen in its high quality degree program (we have our graduates going to Johns Hopkins, Harvard, Stanford, UCF) and research (including obtaining research funds
31 through grant proposals). Prayaga has been very active in applying for research funds. He was co-PI in the successful “Math Matters in Careers” grant ($ 1.7 million) funded by FLDOE in 2007. Future prospects and opportunities: Since 2007 Prayaga has submitted more than a dozen proposals for state and federal grants. This year, he has applied for one grant, and two more are in the works. Ujj is working on an MRI/RUI proposal on the establishment of a vibrational/rotational laser spectroscopy project and facility. Wu is about to submit one career grant and has one more in the works. Ujj and Prayaga have one proposal in the works (NSF-CCLI), and Wu is joining us in making it a department-wide affair. We think we should push these efforts forward. Most of the proposals submitted by Prayaga are in the Education field. However, following the current research interest of the scientific world in Liquid Crystals and Phase Transitions, it will be advantageous to collaborate with one of the leading research groups in the field and submit a joint proposal. The existing research activities at this department in laser related sciences, spectroscopy (e.g. Raman), and material sciences also can be stepped up considerably by collaborating with well known laboratories and research groups. Ujj and Wu have several connections to very active research groups and collaborative works are on the way. The existing ties with these research departments should be strengthened, so that a stable research activity is established. Such collaboration also increases the recruitment and retention. The fact that the department has research ties with universities that offer graduate studies will be a big draw for students in the area.
11.
Recommendations/Proposed Action Plans
Keeping in mind the barriers to the growth, the following recommendations are made for the improvement of the Physics program: 1. Increase the faculty strength by creating two full-line faculty positions, a lecturer’s position, and a demonstrator/organizer/interpreter position. The need for these positions should be obvious from this self study or can be summarized as follows: The department should provide smooth, compact physics BS program (vide supra). The direct teaching load on the faculty should be sufficiently lower to allow them to pursue more research and creative activities, which can attract external funding. More service activity of faculties will benefit the entire university, too. The reduction of the dependence on adjunct instructors will increase the standards of the teaching laboratories.
32 2. Significantly increase the efforts of student recruitment. The outreach activities should be amplified, particularly with the involvement of the local chapter of the Society of Physics Students. 3. Increase efforts in research that attempts to attract external funding. More proposals should be prepared for research funding. 4. Increase seminar activities, both for students and faculty. 5. Exploitation of the above opportunities
We would be honored to take into consideration the wise recommendations of the reviewer team.
A1
12. Appendices Table of Contents 12.1 Student Learning Outcomes............................................................................... 3 Student Learning Outcomes (Measures) ..................................................................... 3 Academic Learning Compact ....................................................................................... 4 Assessment Plan(s) ..................................................................................................... 6 Physics Department – Departmental Assessment Plan (General) ........................... 6 Specific Assessment Criteria for Each individual Course ......................................... 9 12.2 Enrollment Trend Data: Headcount, Full Time Equivalent ............................... 11 Degree Productivity Trend Data (see also review of the curriculum)...................... 11 12.3 Retention Data ...................................................................................................... 12 12.4 Resource Data: Budget Trend and Personnel Trend Data ............................. 21 12.5 Resource Data: Library and Other Learning Resources Data ......................... 24 Available Scientific Journals Related to Natural Sciences ..................................... 25 12.5 Special Facilities, Special Equipment .................................................................... 30 12.6 Grant/Contract Acquisition Summary .................................................................... 34 External Grants .......................................................................................................... 34 Internal Grants: .......................................................................................................... 38 Summary ................................................................................................................ 38 List of all Internal Grants Applied for (2002-2008) .................................................. 39 12.7 CVs of Faculties of Department of Physics (in random appearance) .................... 40 Chandra Sekhar Prayaga .......................................................................................... 40 James Stephen Marsh ............................................................................................... 53 Brandon Murakami .................................................................................................... 62 Laszlo J. Ujj ............................................................................................................... 66 Guoqing Wu ............................................................................................................... 82 12.8 Syllabi of all Courses Affiliated to the Physics Department ................................... 92 EGM 2500 ENGINEERING MECHANICS-STATICS ................................................ 92 EGM 3401 ENGINEERING MECHANICS-DYNAMICS ............................................ 99 PHY 1020 INTRODUCTION TO CONCEPTS IN PHYSICS ................................... 101 PHY 1020L INTRODUCTION TO CONCEPTS IN PHYSICS LAB .......................... 104 PHY 2048 UNIVERSITY PHYSICS I ....................................................................... 107 PHY 2048L UNIVERSITY PHYSICS I LAB ............................................................. 110 PHY 2049 UNIVERSITY PHYSICS II ...................................................................... 114 PHY 2049L UNIVERSITY PHYSICS II LAB ............................................................ 117 PHY 2053 GENERAL PHYSICS I............................................................................ 121 PHY 2053L GENERAL PHYSICS I LAB .................................................................. 123 PHY 2054 GENERAL PHYSICS II........................................................................... 127 PHY 2054L GENERAL PHYSICS II LAB ................................................................. 129 PHY 3106 MODERN PHYSICS I ............................................................................. 133 PHY 3106L MODERN PHYSICS LAB ..................................................................... 136 PHY 3107 MODERN PHYSICS II ............................................................................ 139 PHY 3220 INTERMEDIATE MECHANICS .............................................................. 142
A2 PHY 3424 OPTICS .................................................................................................. 145 PHY 4250 FLUID MECHANICS............................................................................... 147 PHY 4323 ELECTRICITY AND MAGNETISM I ....................................................... 150 PHY 4325 ELECTRICITY AND MAGNETISM II ...................................................... 154 PHY 4445 LASERS AND APPLICATIONS .............................................................. 158 PHY 4513 THERMODYNAMICS AND KINETIC THEORY ..................................... 161 PHY 4604 QUANTUM THEORY ............................................................................. 163 PHY 4910 INDEPENDENT RESEARCH ................................................................. 165 PHZ 3106 INTERMEDIATE-LEVEL PHYSICS PROBLEMS ................................... 167 PHZ 4113 MATHEMATICAL PHYSICS I ................................................................. 169 PHZ 4114 MATHEMATICAL PHYSICS II ................................................................ 173 AST 3033 MODERN ASTRONOMY ........................................................................ 176 PHZ 3601 SPECIAL RELATIVITY ........................................................................... 178
A3
12.1 Student Learning Outcomes
Student Learning Outcomes (Measures) A student graduating from the Physics program should be able to do the following: Content • Recognize and apply basic principles in the main areas of physics, including Newtonian methods, quantum mechanics, and relativity • Recognize and apply mathematical tools useful to the practice of physics, including calculus, differential equations, vector algebra and calculus, variables and functions, and partial differential equations • Use the terminology of physics accurately • Describe possible career options related to physics Critical Thinking • Extract information from physics texts through analytical reading • Calculate and interpret the results of various physics problems • Solve real world engineering problems using physics principles • Develop models of physical systems Communication • Use computer-based strategies to illustrate and solve physics problems • Present findings of physics applications orally and in writing Ethics/Integrity • Demonstrate self-direction in learning. • Recognize ethical problems that may occur in the context of solving physics problems • Adhere to the values of science: objectivity, precision, persistence Project Management • Collaborate effectively with team members • Solve problems through skilled time management Instrumentation Expertise • Exhibit expertise in the use of modern experimental equipment such as continuous-wave or high power pulsed lasers, thin film coating equipments • Work effectively with computer controlled data acquisition devices to develop complex measuring systems
A4
Academic Learning Compact
PHYSICS Mission Statement The mission of the Physics Department is to provide high-quality instruction in Physics and to train competent Physicists who can contribute significantly to the Physics and Engineering environment in the country. To develop awareness of Physics as an ongoing activity through student involvement in research, thus providing students with a challenging, strongly personalized training program Student Learning Outcomes
UWF Physics graduates should be able to do the following: Content • Recognize and apply basic principles in the main areas of physics, including Newtonian methods, quantum mechanics, and relativity • Recognize and apply mathematical tools useful to the practice of physics, including calculus, differential equations, vector algebra and calculus, variables and functions, and partial differential equations • Use the terminology of physics accurately • Describe possible career options related to physics Critical Thinking • Extract information from physics text through analytic reading • Calculate and interpret the results of various physics problems • Solve real world engineering problems using physics principles • Develop models of physical systems Communication • Use computer-based strategies to illustrate and solve physics problems • Present findings of physics applications orally and in writing Integrity/Values • Demonstrate self-direction in learning • Recognize ethical problems that may occur in the context of solving physics problems • Adhere to the values of science: objectivity, precision, persistence
03/05
Project Management •
Collaborate effectively with team members
A5 •
Solve problems through skilled time management
Instrumentation • Exhibit expertise in the use of modern experimental equipments such as high power pulsed lasers and thin film coating equipments • Use computer controlled data acquisition devices to develop complex measuring systems. Job Prospects for Physics Majors Professional Physicist in research labs such as NASA or National research labs Physics teacher in a university, college, or high school Engineer in electrical-engineering firms Computer Programmer in research labs & programming companies Data Analyst in financial institutions Find Out More about Physics:
www.uwf.edu/physics
PHYSICS
College of Arts & Science
A6
Assessment Plan(s) Physics Department – Departmental Assessment Plan (General) Direct Measures: Initial assessment plan will be based on a capstone course: Independent Research PHY4095, taken by Physics majors in their senior year. (This has not yet been formally designated as a capstone course, but it will be so designated.) The course will assess Student Learning Outcomes in the following areas (each area is elaborated in the SLO): 1. Content a. Apply principles of Physics in problem solving b. Use appropriate Mathematical Methods 2. Critical Thinking a. Extract information from literature b. Calculate and interpret results c. Solve real world problems faced during research d. Develop models to explain results obtained 3. Communication a. Use computer based strategies to solve problems and illustrate findings b. Present research results orally and in writing 4. Integrity/Values a. Demonstrate self-direction b. Adhere to the values of Science: objectivity, precision, persistence 5. Project Management a. Collaborate effectively with team members b. Solve problems through skilled time management 6. Instrumentation a. Exhibit expertise in the use of modern experimental equipments b. Use computer controlled data acquisition devices to develop complex measuring systems. The assessment will be based on the following student outputs and performance. Each of the items below will be assessed for the outcomes listed against it. a. Project Progress Reports 1, 2, 3, 5 b. Final Project Report 1, 2, 3, 4, 5, 6 c. Final Results of Research 4 d. Seminar 3 Some of the projects will be theoretical in nature. In such cases the assessment will cover the following areas:
A7 a. Project Progress Reports 1, 2, 3 b. Final Project Report 1, 2, 3, 4 c. Final Results of Research 2, 4 d. Seminar 3 Measurement Strategy: For each of the instruments listed above as a, b, c, and d, a matrix will be specified for assessment. An example matrix for item a. Project Progress Reports, is given below a. Project Progress Reports: Student ID:
Assessor:
a. Project Progress Reports: Above expectations
Meets expectations
Below expectations
Content Principles Problem Solving Mathematics Critical Thinking Literature survey Calculations & interpretation Problem solving Model building Communication Computer models Writing skills Project Management Collaboration Time management b. Final Project Report: Student ID:
Assessor:
b. Final Project Report: Above expectations Content Principles Problem Solving Mathematics Critical Thinking Literature survey
Meets expectations
Below expectations
A8 Calculations & interpretation Problem solving Model building Communication Computer models Writing skills Integrity/Values Self-direction Values of science Project Management
Instrumentation
Collaboration Time management Expertise Design & development
c. Final Results: Student ID:
Assessor:
c. Final Results: Above expectations
Meets expectations
Below expectations
Integrity/Values Self-direction Values of science d. Seminar: Student ID:
Assessor:
d. Seminar: Above expectations
Meets expectations
Below expectations
Communication Computer models Writing skills
External Validation: For each student, the assessment will be done by a team consisting of the supervisor, at least one faculty from the department, and at least one faculty from outside the department.
A9 Monitoring Strategy: The project progress reports (item a) which will be submitted periodically by the student, and the assessment matrix for that item will help the monitoring process. Feedback: The data obtained from the evaluations described above will be examined to assess the effectiveness of our teaching methods as well as evaluation strategies Indirect Measure: Data for evaluation of our teaching methods and assessment strategies will be initially built up using results of: Exit interviews with graduating seniors
Date revised: June 24, 2005
Specific Assessment Criteria for Each individual Course CURRICULUM AUDIT OF COURSES Department: Physics
Date:
2/8/05
PROJECT CRITICAL COMMUNI- MANAGE- ETHICS/ INSTRUME MENT INTEGRITY NTATION CONTENT THINKING CATION COURSE # EGM 2500 EGM 3401 EGM 3512
COURSE NAME ENGINEERING MECHANICSSTATICS ENGINEERING MECHANICSDYNAMICS
SCH 2
X
X
3
X
X
4
X
X
3
X
X
X
1
X
X
X
PHY 2048 UNIVERSITY PHYSICS I PHY 2048L UNIVERSITY PHYSICS I LAB
3
X
X
X
1
X
X
X
PHY 2049 UNIVERSITY PHYSICS II PHY 2049L UNIVERSITY PHYSICS II LAB
3
X
X
X
1
X
X
X
PHY 2053 GENERAL PHYSICS I PHY 2053L GENERAL PHYSICS I LAB
3
X
X
X
1
X
X
X
PHY 2054 GENERAL PHYSICS II PHY 2054L GENERAL PHYSICS II LAB
3
X
X
X
1
X
X
X
PHY 3106 MODERN PHYSICS I PHY 3106L MODERN PHYSICS LAB
3
X
X
X
2
X
X
X
PHY 3107 MODERN PHYSICS II
3
X
X
X
PHY 3220 INTERMEDIATE MECHANICS
4
X
X
X
PHY 3424 OPTICS
3
X
X
X
PHY 4250 FLUID MECHANICS
3
X
X
X
ENGINEERING MECHANICS INTRODUCTION TO CONCEPTS PHY 1020 IN PHYSICS PHY INTRODUCTION TO CONCEPTS 1020L IN PHYSICS LAB
X
X
X
X
X
X
X
X
X
X
X
X
A10 PHY 4323 ELECTRICITY AND MAGNETISM I
3
X
X
X
PHY 4325 ELECTRICITY AND MAGNETISM II
3
X
X
X
PHY 4445 LASERS AND APPLICATIONS THERMODYNAMICS AND PHY 4513 KINETIC THEORY
3
X
X
X
3
X
X
X
PHY 4604 QUANTUM THEORY
3
X
X
X
PHY 4910 INDEPENDENT RESEARCH INTERMEDIATE-LEVEL PHYSICS PHZ 3106 PROBLEMS
2
X
X
X
X
X
1
X
X
X
X
X
PHZ 3601 SPECIAL RELATIVITY
3
X
X
X
PHZ 4113 MATHEMATICAL PHYSICS I
3
X
X
X
PHZ 4114 MATHEMATICAL PHYSICS II
3
X
X
X
X
A11
12.2 Enrollment Trend Data: Headcount, Full Time Equivalent Degree Productivity Trend Data (see also review of the curriculum)
A12
12.3 Retention Data
A13
A14
A15
A16
A17
A18
A19
A20
A21
12.4 Resource Data: Budget Trend and Personnel Trend Data
A22
A23
A24
12.5 Resource Data: Library and Other Learning Resources Data
A25
Available Scientific Journals Related to Natural Sciences Journal title AAPPS Bulletin Abstracts of selected solar energy technology ACM transactions on applied perception Acoustical science and technology Acoustics research letters online Acta astronautica Acta mechanica Acta mechanica Sinica Ad astra Advanced materials for optics and electronics Advances in space research Aerospace international Alternative energy digests American journal of physics Analog science fiction & fact The analyst Die Angewandte makromolekulare Chemie Annalen der Physik Annales Henri Poincaré Annals of physics Annals of the ICRP Annual Review of Astronomy and Astrophysics Antonie van Leeuwenhoek Apeiron Applications of Mathematics Applied mathematics and mechanics Applied physics. A, Materials science & processing Applied physics. B, Lasers and optics Applied physics letters Applied radiology Applied Spectroscopy Applied superconductivity Archive for history of exact sciences Archive for rational mechanics and analysis Archive of applied mechanics Archivos de la Sociedad Española de Oftalmología ASHRAE Journal Astrobiology Astronomische Nachrichten Astronomy The Astronomy and astrophysics review Astronomy education review Astronomy & geophysics Astroparticle physics Astrophysics Astrophysics and space science Astrophysics and Space Sciences Transactions Atmospheric chemistry and physics Atmospheric research Atomic data and nuclear data tables Australasian Science Batteries international Biophysical Journal
Boreas Brazilian journal of physics British Journal for the Philosophy of Science, The The British journal of radiology Broadband networking news Broadcasting & cable The Bucknell review Building services engineering research & technology Bulletin of the American Meteorological Society Bulletin of the American Physical Society Bulletin of the atomic scientists Bulletin of the New Jersey Academy of Science Canadian Journal of Physics Cardiovascular ultrasound CCD astronomy Celestial mechanics and dynamical astronomy Central European Journal of Physics Chalcogenide Letters Chemical Physics Chemical vapor deposition China Particuology Chinese astronomy and astrophysics Chinese Journal of Aeronautics Chinese journal of physics Chromatographia Color research and application Communications in mathematical physics Communications in nonlinear science and numerical simulation Compel Composites. Part B, Engineering Comptes rendus de l'Académie des sciences. Série I, Mathématique Comptes rendus de l'Académie des sciences. Série II, Mécanique Comptes rendus de l'Académie des sciences. Série II, Mécanique, physique, astronomie Comptes rendus de l'Académie des sciences. Série II, Mécanique, physique, chimie, astronomie Comptes rendus de l'Académie des sciences. Série III, Sciences de la vie Comptes rendus de l'Académie des sciences. Série IV, Physique, astrophysique Comptes rendus. Mecanique Comptes rendus. Physique Computers & structures Computing in science & engineering Concepts in magnetic resonance. Part A, Bridging education and research Condensed matter physics Continuum mechanics and thermodynamics Contributions to plasma physics Cosmic research Cryogenics Crystal engineering Current Science Czechoslovak Journal of Physics
A26 Digital review Doklady Dynamics and stability of systems e‐Journal of Surface Science and Nanotechnology Earth Island journal Earth, moon, and planets Eclética química Egyptian journal of solids Electric power systems research Electrical engineering Electromagnetic news report Electronic journal of theoretical physics Electronics letters Elettronica oggi Energy Energy Energy and buildings Energy design update Energy economist Energy & fuels Energy it Energy manager The Energy report Engineered systems Engineering fracture mechanics Engineering with computers Environmental conservation Environmental fluid mechanics EQ The European European energy report European journal of echocardiography European journal of mechanics European journal of mechanics European journal of solid state and inorganic chemistry European journal of ultrasound The European physical journal. A, Hadrons and nuclei The European physical journal. B The European physical journal. C, Particles and fields The European physical journal. D, Atomic, molecular and optical physics Exergy Experimental astronomy Experimental mechanics Experimental Techniques Experimental thermal and fluid science Experiments in fluids Few‐body systems Fiber optics news Fiber optics weekly update Fizika A Fizika B Fizika nizkikh temperatur Flow, turbulence and combustion Fluid dynamics Forecast Forecast Forecast Forschung Fortschritte der Physik
Foster electric report Foster natural gas report from Washington Foundations of computational mathematics Foundations of Physics Fuel cell technology news Functional analysis and its applications General Relativity and Gravitation Georgia Journal of Science Geothermics Global and planetary change Global cosmetic industry The global power report GLOBAL PRIVATE POWER Granular matter Heat and mass transfer Heat transfer: Japanese research Heating, piping, and air conditioning High energy chemistry High energy density physics Historical studies in the physical and biological sciences Hurricane Alice Hyperfine interactions Icarus IEEE aerospace and electronic systems magazine IEEE antennas & propagation magazine IEEE/ASME transactions on mechatronics IEEE circuits and devices magazine IEEE communications letters IEEE electron device letters IEEE journal of quantum electronics IEEE journal of selected topics in quantum electronics IEEE journal of solid‐state circuits IEEE photonics technology letters IEEE sensors journal IEEE transactions on applied superconductivity IEEE transactions on communications IEEE transactions on dielectrics and electrical insulation IEEE transactions on electromagnetic compatibility IEEE transactions on electron devices IEEE transactions on image processing IEEE transactions on magnetics IEEE transactions on medical imaging IEEE transactions on nanotechnology IEEE transactions on nuclear science IEEE transactions on plasma science IEEE transactions on speech and audio processing IEICE Transactions on Electronics III‐Vs review Imagine Imaging decisions Imaging update Independent energy Industrial laser solutions for manufacturing Infrared physics & technology Ingeniería energética Integral equations and operator theory International applied mechanics International coal report International communications in heat and mass transfer International journal for numerical and analytical methods
A27 in geomechanics International journal for numerical methods in engineering International journal of climatology International journal of fracture The International journal of heat and fluid flow International journal of hydrogen energy International Journal of Infrared and Millimeter Waves International journal of mass spectrometry International journal of mass spectrometry and ion processes International journal of mechanical sciences International journal of mechanics and materials in design International journal of micrographics & optical technology International journal of microwave and millimeter‐wave computer‐aided engineering International journal of non‐linear mechanics International Journal of Numerical Methods for Heat & Fluid Flow International journal of phytoremediation International journal of radiation oncology, biology, physics The international journal of rotating machinery International journal of simulation : systems, science & technology International journal of theoretical physics International Journal of Thermophysics Journal de mathématiques pures et appliquées Journal of aerosol science Journal of alloys and compounds Journal of analytical and applied pyrolysis Journal of applied clinical medical physics Journal of applied mathematics and mechanics Journal of applied mechanics and technical physics Journal of applied meteorology Journal of applied meteorology The Journal of chemical thermodynamics Journal of Climate Journal of climate and applied meteorology Journal of clinical ultrasound Journal of computational and applied mathematics Journal of Computational Physics Journal of computer‐aided materials design Journal of diagnostic medical sonography Journal of Electronic Materials Journal of engineering physics and thermophysics Journal of environmental radioactivity Journal of fusion energy Journal of Geometry and Physics Journal of inclusion phenomena and molecular recognition in chemistry Journal of light and visual environment Journal of lightwave technology Journal of low temperature physics Journal of Luminescence Journal of magnetic resonance. Series A Journal of magnetic resonance. Series B Journal of Magnetism and Magnetic Materials Journal of mathematical fluid mechanics jmfm Journal of medical ultrasonics Journal of meteorology Journal of microelectromechanical systems
Journal of molecular liquids Journal of Molecular Spectroscopy Journal of nanoparticle research Journal of non‐crystalline solids Journal of nonlinear science Journal of Nuclear and Radiochemical Sciences (JNRS) Journal of Nuclear Science and Technology Journal of phonetics The journal of physical chemistry. A Journal of Physical Oceanography The Journal of physics and chemistry of solids Journal of Physics ‐ Conference Series Journal of polymer science. Part B, Polymer physics Journal of Raman spectroscopy Journal of research in science teaching Journal of Russian laser research Journal of Science Education Journal of solid state electrochemistry Journal of Sound and Vibration Journal of statistical physics Journal of Surface Analysis Journal of synchrotron radiation Journal of testing and evaluation Journal of the American Academy of Audiology Journal of the American Geographical Society of New York Journal of the Atmospheric Sciences Journal of the Brazilian society of mechanical sciences and engineering Journal of the Colorado‐Wyoming Academy of Science Journal of the Illuminating Engineering Society Journal of the Mississippi Academy of Sciences Journal of the Optical Society of America. A, Optics, image science, and vision Journal of the Optical Society of America. B, Optical physics Journal of thermal analysis and calorimetry Journal of wind engineering and industrial aerodynamics Journal of Zhejiang University. Science JSME international journal. Ser. B, Fluids and thermal engineering Laser and particle beams Laser Focus World Laser physics letters Lasers in surgery and medicine Lasers & optronics Letters in mathematical physics Life science today Lighting dimensions Lightwave Living reviews in relativity Living Reviews in Solar Physics Magma Magnetic resonance in chemistry Mass spectrometry reviews Materials research Materials research bulletin Mathematical proceedings of the Cambridge Philosophical Society Mathematical programming Measurement techniques Mechanics research communications
A28 Mechatronics Medical dosimetry Medical dosimetry Medical Laser Application Mercury Meteorology and atmospheric physics Microelectronics and reliability Microlithography world MicroScope Microwave and optical technology letters Microwave engineering Europe Microwave Journal; International ed. Modern plastics Momentum Monthly notices of the Royal Astronomical Society Monthly Notices of the Royal Astronomical Society: Letters Monthly Weather Review Nature NDT & E international Nebula New astronomy New astronomy reviews New journal of physics New scientist Nieman reports Night Sky Nuclear data sheets Nuclear instruments & methods in physics research. Section A, Accelerators, spectrometers, detectors and associated equipment Nuclear instruments & methods in physics research. Section B, Beam interactions with materials and atoms Nuclear physics. B Nuclear physics. B, Proceedings, supplements Nuclear plant journal Ocean dynamics Optical and quantum electronics Optical information systems Optical Materials Optical memory news OPTICAL REVIEW Optics and photonics news Optics and spectroscopy Optics express Optik Optoelectronics report Organised sound Organization & environment Philips journal of research Philosophical perspectives Phonology Photo trade news Photonics and nanostructures Photovoltaics bulletin Physica A Physica. B, Condensed matter Physica. C, Superconductivity Physica D. Nonlinear phenomena Physica. E, Low‐dimensional systems & nanostructures Physica status solidi. A, Applied research
Physica Status Solidi ‐ B ‐ Basic Solid State Physics Physica status solidi. C, Conferences and critical reviews Physical chemistry chemical physics Physical review Physical review. A, Atomic, molecular, and optical physics Physical review. A, General physics Physical review. B, Condensed matter Physical review. B, Condensed matter and materials physics Physical review. C, Nuclear physics Physical review. D. Particles and fields Physical review. D, Particles, fields, gravitation, and cosmology Physical review letters Physical review special topics. Accelerators and beams Physics and chemistry of the earth Physics and chemistry of the earth Physics and chemistry of the earth Physics and chemistry of the earth Physics in perspective Physics letters. A Physics letters. B Physics of the earth and planetary interiors Physics Reports PHYSICS REVIEW The Physics teacher Physik in unserer Zeit Pigment cell research Planetary and space science Planning Plasma chemistry and plasma processing Plasma processes and polymers Plasmas & ions Polyhedron Polymer degradation and stability Population (English ed.) PoS ‐ Proceedings of science Powder technology Power Engineering POWER IN ASIA Pramāṇa Precision engineering Probability theory and related fields Proceedings in applied mathematics and mechanics Proceedings ‐ Modern Language Association of America Proceedings of the Indian Academy of Sciences. Earth and planetary sciences Proceedings of the Indiana Academy of Science Proceedings of the International Astronomical Union Proceedings ‐ Royal Society. Mathematical, physical and engineering sciences Progress in aerospace sciences Progress in nuclear energy Progress in Nuclear Magnetic Resonance Spectroscopy Progress in particle and nuclear physics Progress in photovoltaics Progress in physics Progress in Quantum Electronics Progress in solid state chemistry Progress in Surface Science Propellants, explosives, pyrotechnics
A29 Pure and applied geophysics The quarterly journal of mechanics and applied mathematics The quarterly journal of speech Quarterly journal of the Royal Meteorological Society Radiation and environmental biophysics Radiation physics and chemistry Radiochemistry Radiographics Radioisotopes Radiologia Brasileira Radiophysics and quantum electronics Railway age The Ramanujan journal Refractories and industrial ceramics Refrigerated transporter RENEWABLE ENERGY REPORT Research in science education Review of palaeobotany and palynology Reviews of modern physics Reviews on Advanced Materials Science Revista brasileira de cartografia Revista brasileira de ciências mecânicas Revista brasileira de ensino de física Revista Cubana de Física Revue générale de thermique Russian journal of nondestructive testing Russian microelectronics Russian physics journal Sādhanā School science and mathematics Science and technology of advanced materials Science progress Science weekly. Level E Scienceland Scientific international journal Semiconductor International The Sensible sound Sensors and actuators. A, Physical SESI Journal : Journal of the Solar Energy Society of India Single molecules Sky and telescope Sky watch Solar energy Solar physics Solar & renewable energy outlook Solar system research Solid State Communications Solid‐state electronics Solid State Ionics Solid State Nuclear Magnetic Resonance Solid state sciences Solid State Technology Southeast power report Space debris Space exploration technology Space science reviews Spectrochimica acta. Part B, Atomic spectroscopy Spectroscopy Stereo review's sound & vision
Storm data Strength of materials Structural chemistry Studia Geophysica et Geodaetica Studies in history and philosophy of modern physics Super collider news Surface science Surface Science Reports SYNERGY REPRESENTING RADIOGRAPHERS PROMOTING RADIOGRAPHY Systems & control letters Teaching pre‐K‐8 Tectonophysics Tellus. Series A, Dynamic meteorology and oceanography Tellus. Series B, Chemical and physical meteorology Terra nova Test & Measurement World Theoretical and applied mechanics Theoretical and applied mechanics Japan Theoretical and computational fluid dynamics Theoretical and mathematical physics Thin Solid Films Transactions of the Nebraska Academy of Sciences Transfusion science Tribology transactions Turkish journal of physics Ultramicroscopy Ultrasonic imaging Ultrasonics Ultrasonics Sonochemistry Ultrasound in medicine & biology Ultrasound in obstetrics & gynecology The ultrasound review of obstetrics and gynecology Uspekhi fizicheskikh nauk Vacuum Vakuum in Forschung und Praxis Vector & zoonosis week Veterinary radiology & ultrasound Vibrational Spectroscopy Vistas in astronomy Wave Motion Weather and forecasting Weatherwise Whole earth review Zeitschrift für angewandte mathematik und mechanik Žurnal fìzičnih doslidžen 気象集誌 混相流 日本レオロジー学会誌 プラズマ・核融合学会誌
A30
12.5 Special Facilities, Special Equipment Orgn 7210 7210 7210
P Tag 42316 42318 42321
7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210
42322 42324 42380 42381 42406 42416 42417 42418 42419 42428 42429 42447 42452
7210 7210 7210 7210 7210
42458 42459 42483 42490 42494
Asset Description Analyzer Multichannel 600f Serves Recorder Digital W/Option Col. Vacuum System‐Ion Pumped W/Accessor Series "W" Equip W/Flow Converter Amplifier Phase‐Lock W/Filter & Osc Microwave Lab Kit W/Option E03 Generator Signal Model 8654a Rf PrinterLetter Quality W/Disc Drive VacuumCollar Stainless Steel W/247 Vacuum Coater W/Bell 2r Mod 3116 Balance Electro 14740 Analyzer Sound & Vibration Recordin Air TrackSet Of Four W/Shop Vac Air TrackSet Of Four W/Shop Vac Videodisc Player Pioneer W/Keypad Bench Impedence Bridge Model 1608‐ A Oscilloscope Hewlett‐Packard 15mhzd Oscilloscope Hewlett‐Packard Dual C BenchWave Analyzer Optical/Instrument Bench/Air Suspen MicroscopeAmerican Optical Binocu
7210
42498
Holography System Mod 11
7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210
42500 42553 42564 42572 42573 42574 42577 42578 42579 42581 42582 42590 42595 42596 42811 42860 43886 48349
7210
48350
7210 7210
48351 48352
Enlarger W/Correct Mounting Plates Oscilloscope‐Tektronix 516 Wind Tunnel & Acc Aerolab Interferometer Michelson Mod 1‐1011 Interferometer Michelson Mod 1‐1011 Microscope Traveling Spectrum Analyzer Optical‐ A2 Mirr Interferometer Universal InterferometerUniversal #25‐9093 InterferometerUniversal 25‐9093 Interferometer Universal Camera 35mm W/Telephoto Lens TelescopeQuestar Mirror Pyrex Stan Mirror Wide Field Standard Questar Differential Volt Model 662 Guarde Telescope‐121/2" Transportable D F‐ Chromatagraph Gas Spectrometer Gaertner‐Peck Md#87015 Spectrometer Gaertner‐Peck Md#87015 Spectrometer Gaertner‐Peck 87015‐62 Spectrometer Gaertner‐Peck 87015‐62
Serial Number 148 33405538 950‐1167
Bldg 13 13 13
Room 324 324 102
13 13 13 70 13 13 13 13 13 13 13 13 13
307 324 320 OUT 321 102A 102A 324 311 311 324 311 102A
13 13 13 13 13
Missing
Book Amount Last Inv Date $ 5,295.78 11/5/2007 $ 1,637.16 11/5/2007 $ 4,214.01 4/10/2008 $ 3,500.00 $ 2,625.00 $ 11,988.27 $ 1,150.00 $ 1,864.80 $ 1,940.00 $ 4,461.00 $ 4,500.00 $ 2,626.00 $ 1,634.00 $ 1,634.00 $ 1,497.50 $ 1,305.00
4/10/2008 11/5/2007 11/1/2007 6/5/2008 1/25/2006 4/10/2008 4/10/2008 11/5/2007 4/25/2008 11/5/2007 11/5/2007 4/10/2008 4/25/2008
311 311 311 324 320
$ 2,235.20 $ 2,235.20 $ 2,457.00 $ 1,238.00 $ 1,680.00
4/25/2008 11/5/2007 4/10/2008 4/10/2008 4/10/2008
13
319
$ 2,536.00
11/5/2007
1248A00603 3859AW
13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13
319 324 100 307 307 307 303 324 324 303 324 324 320 324 311 324 324 311
$ 1,208.64 $ 1,075.72 $ 2,500.00 $ 1,762.00 $ 1,762.00 $ 1,191.00 $ 1,323.00 $ 1,140.00 $ 5,799.00 $ 1,662.00 $ 1,140.00 $ 3,000.00 $ 1,293.50 $ 1,240.00 $ 1,149.22 $ 1,720.00 $ 3,404.72 $ 2,138.00
11/5/2007 4/10/2008 11/1/2007 4/10/2008 4/10/2008 11/5/2007 11/2/2000 11/5/2007 4/10/2008 11/5/2007 4/10/2008 4/10/2008 11/1/2007 4/10/2008 11/5/2007 4/10/2008 4/10/2008 4/10/2008
3860AW
13
311
$ 2,138.00
4/10/2008
3829AW 3802AW
13 13
303 311
$ 2,138.00 $ 2,138.00
11/5/2007 4/10/2008
11846 1340A00708 931 26457453 14740 2430
EA3603325 1410 2306A20424 2306A20667
481071 NASA829 944AH & 232AJ 120388 4304 380 379 4056P (OLD 18244)
24711 Jan‐32 76039
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Missing07
Missing07
April , 2009
A31 Orgn 7210 7210 7210
P Tag 48353 49398 49438
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7210 7210 7210 7210 7210
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Disposition Monitor Film Thickness Telescope‐Celetron 8 Heliostat 8" W/Parts Series "A" Equip Aerodynalog Mod A5 MicroscopeLeitz Ortholux Binocula
7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210
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Desk/Workstation Laser Uniphase Helium‐Neon Laser Power Meter Generator 2nd Harmonic At‐1 Dcda‐10 Panel Sharp Computer Qa‐50 W/Cable Printer Apple Laser M6210 System Mainframe & Display Module Telescope High Power Beam Expanding Isolator Faraday W/Wave Retarder Sampling Mainframe Supports Hp Rotator Broadband Polarized Mechanical Fixturing For Prism Laser System Spectraphysics 1064mn Table Newport/Klinger Vibration Fre Generator Broadband Noise Nc6108 Characterization System/Model 90 Glan‐Laser Polarizer Glan‐Laser Polarizer Crystal 5x5x5mm Barium Titanate Pc P90 Desktop Pc P90 Desktop Thin Flim Deposition Trough Detector ‐ Ingaas Thermoelec Cooled Pc ‐ Apple Powermac 7600 Vibration Isolated Legs Vih28 Optical Taple Top Monochrometer Computer Controlled Oscilloscope Tektronix 400 Lens Kit Uncoated Film Analysis Instrument Software Data Acquisition Software Thin‐Film Analysis Pc ‐ 120mhz Pentium For Film Analys Pc ‐ Apple Power Macintosh 9600 Mechanical Assembly Hdwr Sdl‐8610 Spectrometer Student Spectrometer Student Spectrometer Student Spectrometer Student Spectrometer Student Printer Hp Laserjet 4000n Printer Hp Laserjet 4000n
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-31-
Bldg 13 13 13
Room 311 324 311
Missing
13 13 13 13 13
311 401 401 316 102
$ 1,227.21 $ 2,320.33 $ 8,042.83 $ 3,649.27 $ 3,986.20
4/10/2008 4/10/2008 4/10/2008 4/10/2008 4/10/2008
13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13
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$ 1,189.66 $ 1,252.03 $ 1,339.31 $ 1,262.67 $ 1,195.00 $ 2,715.00 $ 6,142.79 $ 1,351.00 $ 3,458.00 $ 20,581.00 $ 2,325.43 $ 1,953.76 $ 105,235.45 $ 15,589.02 $ 2,262.50 $ 27,103.83 $ 1,260.78 $ 1,260.77 $ 3,051.00 $ 2,160.00 $ 2,160.00 $ 34,064.75 $ 1,334.76 $ 3,651.90 $ 2,135.00 $ 2,185.00 $ 7,580.90 $ 4,752.72 $ 1,295.00 $ 5,000.00 $ 1,200.00 $ 3,097.25 $ 2,100.00 $ 3,404.00 $ 16,790.00 $ 1,813.00 $ 1,813.00 $ 1,813.00 $ 1,813.00 $ 1,813.00 $ 1,158.53 $ 1,158.53
4/10/2008 4/10/2008 6/1/2006 4/10/2008 6/1/2006 4/10/2008 4/10/2008 4/10/2008 4/10/2008 4/10/2008 6/1/2006 3/4/2008 4/10/2008 4/10/2008 4/10/2008 4/10/2008 3/4/2008 3/4/2008 3/4/2008 6/1/2006 11/5/2007 4/10/2008 4/10/2008 4/10/2008 4/10/2008 4/10/2008 4/10/2008 4/10/2008 4/10/2008 4/10/2008 3/4/2008 3/4/2008 4/10/2008 4/10/2008 4/10/2008 4/10/2008 4/10/2008 4/10/2008 4/10/2008 4/10/2008 4/10/2008 4/10/2008
Missing07 Missing07
Missing07
Missing07
Book Amount Last Inv Date $ 2,138.00 4/10/2008 $ 2,003.09 11/5/2007 $ 2,570.00 4/10/2008
April , 2009
A32 Orgn 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210
P Tag 61365 61366 61367 61914 61915 61975 62025 62723 62724 62783 62850 62911 63180 63190 63603
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7210 7210 7210
63609 64077 64181
Pc Dell 500 Gx1/T+ W/17" Monitor Inductor Generl Radio 1490c Decade Pc Apple Powerbook Laptop
7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210
64258 64344 64345 64346 64347 64348 64349 64354 64355 64356 64690 64691
Pc Dell Latitude Cpxh500g7 Laptop Spectrometer Student Spectrometer Student Spectrometer Student Spectrometer Student Spectrometer Student Spectrometer Student Pc Dell Optiplex Gx110 W/17" Mntr Pc Dell Optiplex Gx110 W/17" Mntr Pc Dell Optiplex Gx110 W/17" Mntr Projector Nec Vt540 Pc Ibm Thinkpad
7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210 7210
65603 65623 67039 67627 69187 69188 69763 69764 69809 69829 69880 69913 70780
Pc Dell Piii 933 Gx110 Pc Dell Piii 933 Gx110 Spectrometer Student Pc Dell Optiplex Gx260t W/Flt Mntr High Perform Translation Stage 1 Axis Display Controller Dual Channel Gated Photon Counter 300 Mhz Preamplifier Dell Latitude Laptop Pc Dell Optiplex Gx280 Pc Toshiba Portege M200 Laptop Pc Apple Imac G5 20" Pc Apple iMac G5 Pc
7210 7210 7210 7210 7210
71224 71225 71227 71228 71229
Dell Optiplex Gx620 Minitower Pc Dell Optiplex Gx620 Minitower Pc Dell Optiplex Gx620 Pc Dell Optiplex Gx620 Pc Dell Optiplex Gx620 Pc
Serial Number 98101699 98101740 98101738 37531 6443 12704552
8110874 PHU4 8PHSE XB9517W2HL A BFKE2 2963 QT01805UHK E 62IKV
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-32-
Bldg 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13
Room 320 301 303 303 303 315 303 303 313 303 303 303 307 324 319
13 13 13
102A 302 319
13 13 13 13 13 13 13 13 13 13 13 13
305 319 319 319 319 319 302 315 311 102A 305 303
41 41 13 79 13 13 13 58 13 13 13 13 13 13 13 13 13 13
Missing Missing07
Missing07
Book Amount Last Inv Date $ 1,360.00 11/1/2007 $ 1,532.00 4/10/2008 $ 1,392.00 4/10/2008 $ 3,984.41 4/10/2008 $ 1,004.15 4/10/2008 $ 2,248.00 4/10/2008 $ 5,992.50 4/10/2008 $ 3,271.00 3/4/2008 $ 2,139.50 1/25/2006 $ 5,033.54 3/4/2008 $ 5,642.00 4/10/2008 $ 1,135.95 4/10/2008 $ 1,366.00 4/10/2008 $ 1,366.00 4/10/2008 $ 1,619.00 4/10/2008 $ 1,366.00 $ 1,006.92 $ 2,518.00
4/10/2008 4/10/2008 4/10/2008
$ 3,009.00 $ 1,922.58 $ 1,922.58 $ 1,922.58 $ 1,922.58 $ 1,922.58 $ 1,922.58 $ 1,393.00 $ 1,393.00 $ 1,393.00 $ 3,700.00 $ 3,267.91
1/25/2006 4/10/2008 4/10/2008 4/10/2008 4/10/2008 4/10/2008 4/11/2008 11/5/2007 4/11/2008 4/25/2008 6/1/2006 11/5/2007
126 126 303 196 303 313 303 70 313 305 305 301 315
$ 1,137.00 $ 1,137.00 $ 2,001.00 $ 1,559.40 $ 3,690.62 $ 2,349.95 $ 5,350.00 $ 1,149.00 $ 2,084.82 $ 1,141.36 $ 2,843.48 $ 1,930.00 $ 1,974.00
5/20/2008 5/21/2008 4/11/2008 3/26/2008 4/11/2008 4/11/2008 4/11/2008 6/16/2008 4/11/2008 11/5/2007 11/5/2007 4/11/2008 11/5/2007
311 311 311 311 311
$ 1,096.90 $ 1,096.90 $ 1,096.90 $ 1,096.90 $ 1,096.90
4/11/2008 4/11/2008 4/11/2008 4/11/2008 4/11/2008
Missing07
Stolen05
April , 2009
A33 Orgn 7210 7210 7210 7210 7210 7210 7210 7210 7210
P Tag 71230 71231 71232 71234 71235 71253 71254 71441 71442
Asset Description Dell Optiplex Gx620 Minitower Pc Dell Optiplex Gx620 Minitower Pc Dell Optiplex Gx620 Minitower Pc Dell Optiplex Gx620 Minitower Pc Dell Optiplex Gx620 Minitower Pc Dell Optiplex Gx620 Minitower Pc Dell Optiplex Gx620 Minitower Pc Apple Imac G5 2.1 Power Pc Apple Imac G5 2.1 Power Pc
7210
71443
Apple Imac G5 2.1 Power Pc
7210
71444
Apple Imac G5 2.1 Power Pc
7210
71445
Apple Imac G5 2.1 Power Pc
7210
71446
Apple Imac G5 2.1 Power Pc
7210 7210 7210
71447 71448 71449
Apple Imac G5 2.1 Power Pc Apple Imac G5 2.1 Power Pc Apple Imac G5 2.1 Power Pc
7210
71450
Apple Imac G5 2.1 Power Pc
7210
71451
Apple Imac G5 2.1 Power Pc
7210
71452
Apple Imac G5 2.1 Power Pc
7210
71453
Apple Imac G5 2.1 Power Pc
7210
74152
Hp Laserjet 4250n Printer
Serial Number DWJYX81 DL9YX81 BXJYX81 2YJYX81 2SJYX81 9W2ZX81 6R2ZX81 QP55008PTAU W855002ETA U W855008YTA U W855002FTA U QP5500A9TA U QP5500A7TA U W855008JTAU QP55009ETAU QP55009CTA U W855008DTA U W855002KTA U W855002LTA U QP55008VTA U
-33-
Bldg 13 13 13 13 13 13 13 13 13
Room 311 311 311 311 311 311 311 302 302
Missing
Book Amount Last Inv Date $ 1,096.90 4/11/2008 $ 1,096.90 4/11/2008 $ 1,096.90 4/11/2008 $ 1,096.90 4/11/2008 $ 1,096.90 4/11/2008 $ 1,096.90 4/11/2008 $ 1,096.90 4/11/2008 $ 1,610.46 4/11/2008 $ 1,610.46 4/11/2008
13
302
$ 1,610.46
4/11/2008
13
302
$ 1,610.46
4/25/2008
13
302
$ 1,610.46
4/11/2008
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302
$ 1,610.46
4/11/2008
13 13 13
302 302 302
$ 1,610.46 $ 1,610.46 $ 1,610.46
4/11/2008 4/11/2008 4/11/2008
13
302
$ 1,610.46
4/11/2008
13
302
$ 1,610.46
4/11/2008
13
302
$ 1,610.46
4/11/2008
13
302
$ 1,610.46
4/11/2008
13
317
$ 1,132.36
4/11/2008
April , 2009
A34
12.6 Grant/Contract Acquisition Summary External Grants
-34-
April , 2009
A35
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April , 2009
A36
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April , 2009
A37
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April , 2009
A38
Internal Grants: Summary
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April , 2009
A39
List of all Internal Grants Applied for (2002-2008) 2002 ‘Nonlinear Fitting Procedures for Coherent Raman Spectroscopy’, not supported (Laszlo Ujj) 2002 UWF University Research Award. Summer '02. $6150 (James Marsh) 2003 ‘Advanced Quantum Physics Experiments‘, awarded $6250. (Laszlo Ujj) 2004 ‘Development of Nonlinear Optical Methodologies’, not supported (Laszlo Ujj) 2006-2007: Two students of the department (with the help of Dr. Ujj and Dr. Prayaga) submitted and secured two small undergraduate research grant proposals ($2000 each) from the UWF Honors Program Office: Experimental configuration to measure CARS. 2. Coherent anti-Stokes Raman Spectroscopy: This made possible to buy several necessary optical components and participate on a SPS meeting. 2008 Testing a Classroom Response System for Active Learning and Student Engagement (Prayaga)
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April , 2009
A40
12.7 CVs of Faculties of Department of Physics (in random appearance)
CURRICULUM VITAE
Chandra Sekhar Prayaga Department of Physics, University of West Florida Educational Qualifications: Ph.D., Physics, 1975, Indian Institute of Science, Bangalore, India. M.Se., Physics, 1970, Indian Institute of Technology, Delhi, India. B.Se., Special Physics, Mathematics and Chemistry, 1968, Osmania University, Hyderabad, India. Professional Societies: Member, Optical Society of America Professional Career: September 2002 - Present: Chairman/Associate Professor, Department of Physics, University of West Florida, Pensacola, Fl 32514 August 1991 -August 2002: Associate Professor, Department of Physics, University of West Florida, Pensacola, FL 32514 August 1989-August 1991: Associate Professor, Department of Physics, Alabama A&M University, Normal, AL 35762. August 1987-Aucust 1989: Research Assistant Professor, Physics Department, Alabama A&M University, Normal, AL 35762. February 1982-August 1987: Assistant Professor, Physics Department, Indian Institute of Science, Bangalore, India.
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April , 2009
A41 October 1977-February 1982: Lecturer, School of Physics, University of Hyderabad, Hyderabad, India. December 1975-October 1977: Indian Masonic Lodge Post Doctoral Fellow, Physics Department, Indian Institute of Science, Bangalore, India. Awards and Honors: (1) India Atomic Energy Merit scholarship during B.Sc. and M.Sc. (2) Martin Foster Gold Medal (Best thesis award) for Ph.D. thesis. (3) Junior Associate, International Center for Theoretical Physics, Trieste, Italy, 19761979. (4) Young scientist award of the Andhra Pradesh Academy of Sciences, India (1978). (5) Teaching Incentive Program Award, The University of West Florida, 1995. (6) Distinguished Teaching Award by the Students of The University of West Florida, March 1, 1996. (7) Golden Apple Award for Academic Excellence, Escambia County, 1996. Teaching Experience: 35 Years Courses Taught Prior to 1991 before joining The University of West Florida: Graduate Courses: Statistical physics, Electromagnetism, Laser physics, Laser applications, Optical properties of solids, Electronics (analog, digital and microprocessor), Electronics laboratory (analog, digital and microprocessor), Quantum mechanics, Crystal symmetry and physical properties, Light scattering and nonlinear optics. Undergraduate Courses: fundamentals of physics (Resnick and Halliday), Introductory physics laboratory, Physical Science, Modern Physics SERVICE AT THE UNIVERSITY OF WEST FLORIDA (Details in the Creative/Scholarly Activities Report in the Supporting Materials Section)
1. Teaching Courses Taught at The University of West Florida: (Repeated courses not listed separately) Phy 2048, and Phy 2048L University Physics I and Lab (Calculus based) Phy 2049, and Phy2049L University Physics 11and Lab (Calculus based) Phy 2053, and Phy2053L General Physics I and Lab (non-calculus based) -41-
April , 2009
A42 Phy2054, and Phy2054L General Physics 11, and Lab (non-calculus based) Phy1990 Concepts in Physics EGM 3512 Engineering Mechanics Phy 4323 Electricity and Magnetism I Phy 4325 Electricity and Magnetism 11 Phy 3101 and Phy 3101L Principles of Modem Physics and Lab Phy3107 Modern Physics II Phy4604 Quantum Theory Phz 4113 Mathematical Physics Phy 4513 Thermodynamics and Kinetic Theory Phy 3424C Optics (Includes a lab) Phy 3722 and Phy 3722L Electronics and Lab Phy 4250 Fluid Mechanics Phy 4910 Independent Research Cop4990 Software Methods for Remote Databases PHY3013 Physics and Mathematics for Game Programming New/modified teaching techniques New Experiments Introduced Into Laboratory Curriculum: (a) Measurement of Temperature of a flame by Spectroscopy (b) Making a Reflection Hologram Innovative Teaching Methods: Development of a computer graphics simulation program to demonstrate the Second Law of Thermodynamics. Computer control of University Physics and General Physics Teaching Labs
2. Active Research Projects Granted: (1) National Science Foundation Grant. Title: Acquisition of Equipment for Molecular Engineering and investigation of Selected Organic and Organometallic Materials with Potential Applications -42-
April , 2009
A43 in Photonic Devices. Grant amount: $230,000 (NSF); $108,152 (University Matching). Project duration: Sept. 15, 1994 - Aug 31, 1997 Co-investigator, with M.C. George, Dept. of Physics, UWF The first annual progress report of this research grant is included in this file.
(2) UWF Research and Creative Activities Small Grant Program Award. Title: Proposal for Partial Support to Purchase a Boxcar Averager for the Measurement of Fast Pulsed Signals from nonlinear Optical Processes in Organic Materials. Award amount: $2,500 Project Duration: March 1, 1994 - Nov 1, 1994 (3) UWF Research and Creative Activities Summer Research Position Title: Electro-Optic Effects and Optical Phase Conjugation in Solutions and Thin Films of Ferrocene Project Duration: Summer, 1992. (4) UWF Scholarly and Creative Activities Grant Title: Testing a Classroom Response System for Active Learning and Student Engagement Duration: Summer – Fall 2008 (5) Florida Department of Education Grant (co-PI) Title: Math Matters in Careers Award amount: $ 1,.5 million Duration : Jan –Sep 2007 (4) Collaboration with University of Malaya, Kuala Lumpur, Malaysia: Established a collaborative research program with the Institute of Advanced Studies, -43-
April , 2009
A44 University of Malaya, Malaysia, in the field of Nonlinear Optics. One visiting scientist from the University of Malaya spent the summer of 1995 in our laboratory. Currently, a PhD student from there is doing his experimental work with us, and will submit his thesis at his home University, based on the work done here. 3. Service to the University and Public (1) Member, COST council for two years (2) Member, The Principal Committee for Undergraduate Programs. (3) Member, Curriculum Planning Committee. (4) Presented "Lasers and Applications" Science Seminar for High School Students at Pensacola Junior College, Pensacola Campus, November 1991. (5) Member, CLAST Task Force of the Department of Education, State of Florida. RESEARCH EXPERIENCE Ph.D. Thesis: Critical phenomena in binary liquid mixtures, ferromagnetism and magneto electric systems. Current Interests: Nonlinear optics, optical phase conjugation, degenerate and nondegenerate four-wave mixing, second and third harmonic generation, stimulated Raman and Brillouin scattering in photorefractive materials, organic liquids and solutions, pure and doped inorganic and organic crystals, glasses, thin films. Laser light scattering spectroscopy (Raman, Brillouin and Rayleigh scattering) in binary liquid mixtures, ferroelectric crystals and crystals near structural phase transitions. Photon correlation studies of critical fluctuations. Laser induced fluorescence near structural phase transitions in pure and doped crystals. No. of Ph.D. Theses Directed: 6 (4joint supervision, 2 sole supervision, during l97791) No. of Master's Theses supervised: 5 (1977-91) No. of Undergraduate Research Students supervised: 12 (1991-present) No. of High School Research Projects supervised: 8 (1991-present) INSTRUMENTATION EXPERIENCE Design and fabrication of temperature controllers, thermostats and temperature measuring -44-
April , 2009
A45 units with millikelvin resolution using PID techniques, digital control circuits for instrumentation, microprocessor based digital photon counting correlation system, optical cryostats for low temperature laser spectroscopy, Nitrogen and dye lasers, ion and solid state lasers IEEE-488 and RS232C control of instruments. NEW RESEARCH LABORATORIES STARTED (1) Laboratory for Raman and Brillouin Scattering spectroscopy near structural phase transitions at the University of Hyderabad, India, (1977-82). One Ph.D. was trained in Raman spectroscopy during this period. (2) Laboratory for photon correlation spectroscopy near phase transitions, in optical phase conjugation in dye solutions, and in laser induced fluorescence spectroscopy near structural phase transitions in doped crystals, at the Indian Institute of Science, India, (1982-87). Two Ph.D.'s were trained during this period. (3) High power nonlinear optics laboratory including phase conjugation in organic materials at the Alabama A&M University, (1987- ). Two Ph.D.'s were trained during this period.
NEW TEACHING LABORATORIES AND PROJECTS STARTED (1) Teaching laboratories in new university (University of Hyderabad 1977) in optics and modern physics. Graduate (Masters) student projects on laser beam modulation using the Kerr effect, temperature control and light scattering near the critical point. (2) Electronics teaching projects including analog and digital control circuits, microprocessor based control and analysis systems.
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April , 2009
A46 Publications: Total 53, 22 in refereed journals, 2 articles in books, 29 in proceedings of symposia LIST OF PUBLICATIONS Recent Publications: (Peer reviewed) 1. Carol Briscoe and Chandra Prayaga, Developing a Physics Course for Elementary & Middle level Education Majors: Evolution of One Teacher’s Enacted Curriculum, 2002 AETS Annual International Meeting January 10-13, 2002 – Charlotte, NC 2. Carol Briscoe and Chandra S. Prayaga, Teaching Future K-8 Teachers the Language of Newton: A Case Study of A Physics Professor’s Beliefs and Practices, NARST 2002 Conference, New Orleans, April 7-10, 2002 3. Chandra Prayaga, “An interactive tutorial for Isothermal Processes” ELEARN2003 4. Chandra Prayaga, “An interactive tutorial for Oscillations” EDMEDIA-2004 5. Carol Briscoe and Chandra S Prayaga, "Teaching Future K-8 Teachers the Language of Newton: A Case Study of Collaboration and Change in University Physics Teaching," Sci Ed 88, pp 947-969 (2004). 6. Chandra Prayaga, “Monte-Carlo Method and the 2-d Ising Model” MAPLE Conference July 17-21, 2005, Waterloo, Canada 7. Chandra Prayaga, "A Visual Basic – VPython Interface", American Association of Physics Teachers Winter Meeting, 2007
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April , 2009
A47 8. Chandra Prayaga, "Interactive Simulation of Simple Harmonic Motion with VPython and Excel Controlled by VBA", ED-MEDIA 2007 conference, Vancouver, BC, Canada 9. "Preparing content-rich learning environments with VPython and Excel, controlled by Visual Basic for Applications", Phys. Educ. 35, 88-94 (2008)
Papers published in refereed Journals: (Authors include graduate students supervised )
(1) Preparation and Characterization of Langmuir-Blodgett Films of Mixtures of Arachidic Acid and Stilbene Dye," Sisko, R.; Wade, A.; Cook, J.; Ujj, L.; Prayaga, C.; Royappa, A. T., paper presented at the Symposium of Undergraduate Research in Mathematical Sciences, April 2001. (2) "Synthesis of Sulfonated Polyaniline by Polymerization of the Aniline Heterodimer 4aminodiphenylamine-2-sulfonic acid," Royappa, A. T.; Steadman, D. D.; Tran, T. L.; Nguyen, P. T.; Prayaga, C. S.; Cage, B.; Dalal, N., Synthetic Metals, 2001, 123, 273. (3) "Continuous-wave laser beam tanning in inorganic solutions: a novel phenomenon", Hossin Abdeldayem, William K. Witherow, Angela Shields, Benjamin Penn, Donald O. Frazier, Mehdi Moghbel, P. Venkateswariu, P. Chandra Sekhar, and M.C. George, Opt.Lett. Vol. 19, 2068 (1994). (4) "Nonlinear optical parameters of 7', 7'-dicyano-7'-apo-b-carotene in hexane by selfaction techniques", Hossin A. Abdeldayem, Wen Sheng, P. Venkateswariu, William K. Witherow, Don O. Frazier, P. Chandra Sekhar, M.C. George, Lowell Kispert, and Michael R. Wasielewski, Optics Commun., Vol. 95, 295 (1993). (5) "Transient multiple diffraction rings induced by ultrafast laser from chinese tea", K.X. He, H. Abdeldayem, P. Chandra Sekhar, P. Venkateswarlu, and M.C. George, Optics Commun., Vol. 81, 101 (1991). (6) "Laser induced fluorescence in potassium manganese sulphate single crystal", N. Manickam, P. Chandra Sekhar, P. S. Narayanan, H. L. Bhat, and C. K. Subramanian, Curr. Sci. (India) Vol. 57, p 187-8 (1988). (7) "Thermally induced optical phase conjugation by degenerate four wave mixing", E.R. Prasad, R. Krishna Mohan, P. S. Narayanan, C. K. Subramanian, and P. Chandra Sekhar, Curr. Sci. (India) Vol. 57, p 648-54 (1988).
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A48 (8) "Corrections to scaling from light scattering intensity measurements in a binary liquidmixture", K. Devanand, Vani Chaterjee, and P. Chandra Sekhar, Curr. Sci. (India) Vol. 55, p 400-2 (1986). (9) "Laser Raman spectroscopic study of ferroelastic LiCsSO4", A. G. K. Murthy, P. Chandra Sekhar, and A. K. Bhatnagar, Pramana (India) Vol. 24, p 545-57 (1985). (10) "A microprocessor based digital correllator", K. Devanand and P. Chandra Sekhar, J. Phys. E. Sci. Instrum. Vol. 55, p 904 (1985). (11) "Light scattering investigations of Cs2ZnCl4 at high temperatures", A. G. K. Murthy, P. Chandra Sekhar, and A. K. Bhatnagar, Curr. Sci. (India) Vol. 16, p 857-62 (1984). (12) "Light scattering from (NH4)2ZnBr4 in the incommensurate phase", A.G.K. Murthy, P. Chandra Sekhar, and A. K. Bhatnagar, Curr. Sci. (India) Vol. 53, p 1197-8 (1984). (13) "Vibrational spectroscopic study of the structural phase transition in LiCsSO4", A.G.K. Murthy, P. Chandra Sekhar, and A. K. Bhatnagar, Curr. Sci. (India) Vol. 53, pp 980-2 (1984). (14) "Raman scattering investigation of the phase transitions in (NH4)2ZnBr4", A.G.K. Murthy, P. Chandra Sekhar, and A. K. Bhatnagar, Ferroelectrics. Lett. Sect. (GE) Vol. 3, p 9-13 (1984). (15) "Critical behavior of electrical resistivity in polar + nonpolar binary liquid systems", J. Ramakrishnan, N. Nagarajan, A. Kumar, E. S. R. Gopal, P. Chandra Sekhar, and G. Ananthakrishna, J.Chem.Phys. Vol. 68, p 4098-194 (1978). (16) "Critical behavior of electrical resistivity in five binary liquid systems", E.S.R. Gopal, M. V. Lele, N. Nagarajan, J. Ramakrishnan, and P. Chandra Sekhar, Phys. Lett. Vol. 63 A, p 139-40 (1977). (17) "Two-phase asymmetry in the phase diagram of the critical binary liquid systems: carbondisulphide + nitromethane and cyclohexane + acetic anhydride", E.S.R. Gopal, P. Chandra Sekhar, G. Ananthakrishna, R. Ramachandra, and S. V. Subramaniam, Proc. R. Soc. (GE) Vol. 350A, p 9l-106 (1976). (18) "Critical phenomena in the electrical resistivity of binary liquid systems: CS2 + CH3CN and CS2 + CH3NO2", E.S.R. Gopal, M.V. Lele, J. Ramakrishnan, P. Chandra Sekhar, and S. V. Subramaniam, Pramana, Vol. 7, p 266-76 (f 976). (19) "Scaling for binary liquid systems and ferromagnets under pressure", P. Chandra Sekhar, G. Ananthakrishna, E. S. R. Gopal, Physica (Netherlands) Vol. 77, p 563-9 (1974). (20) "Critical exponent and rectilinear diameter of the binary-liquid system carbondisulfide + nitromethane", E.S.R. Gopal, R. Ramachandra, P. Chandra Sekhar, K. Govindarajan, and S. V. Subramaniam, Phys. Rev. Lett. Vol. 32, p 284-6 (1974). (21) "On optical properties of crystals", P. Chandra Sekhar, and T. P. Srinivasan, J.Phys.C (GB) Vol. 6, p 1085-90 (1973). (22) "Harmonic generation and selection rules in nonlinear optics", S. Bhagavantam, and P. Chandra Sekhar, Proc. Indian Acad. Sci. Vol. A76, p l3-20 (1972). (23) "Invariant magneto-electric and piezomagnetic coefficients", P. Chandra Sekhar and T. P. Srinivasan, Acta Crystallogr. (Denmark) Vol. A28, p 594-7 (1972).
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A49 Articles in Books: (23) "Phase conjugate resonator and bistabilities", P. Venkateswarlu, M. Dokhanian, P. Chandra Sekhar, and M.C. George, in Nonlinear Optical Materials, Eds., Hans Kuhn and Jean Robillard, CRC Press (1992). (24) "Optical phase conjugate resonators, bistability, and applications", P. Venkateswariu, M. Dokhanian, P. Chandra Sekhar, and M.C. George, SPIE Advent Technology Series, Vol. AT2, Ed., R. Friberg, pp 186-207 (1991). Presentations in Conferences: (25) "High Fidelity Phase Conjugate Mirror", H. Abdeldayem, P. Chandra Sekhar, P. Venkateswariu, M.C. George, Annual Meeting of the Optical Society of America, Albuquerque, NM, 1992. (26) "Phase conjugate resonators and bistabilities in BaTiO3", P. Venkateswariu, M. Dokhanian, P. Chandra Sekhar, and M.C. George, OSA Annual Meeting Technical Digest Series, Vol. 18, 83 (1991).
(27) "Third order nonlinear optical properties of donor sigma acceptor molecules", H. Abdeldayem, P. Chandra Sekhar, P. Venkateswarlu, M.C. George, M.V. Joshi, M.P. Cava, M.V. Lakshmikantham, and R.M. Metzger, Fourth Annual Alabama Materials Research Conference, Tuscaloosa, Al, 1990. (28) "Third order optical nonlinearities in 7-dicyano apocarotene", H. Abdeldayem, Wen Sheng, P. Venkateswariu, P. Chandra Sekhar, M.C. George, L. Kispert,, and MR. Wasielewski, Fourth Annual Alabama Materials Research Conference, Tuscaloosa, Al, 1990. (29) "Phase conjugate resonators and bistable oscillations in BaTiO3", P. Venkateswariu, M. Dokhanian, P. Chandra Sekhar, and M.C. George, Proceedings of the topical meeting on "Photorefractive materials, effects, and devices", Aussios, France, pp 226-229 (1990)
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A50 Papers published in OSA Annual Meeting, 1990 Technical Digest Series, Vol. 15 (Optical Society of America, Washington, D.C., 1990): (Refereed papers) (30) "Parametric Study of coherent beam coupling through pulsations and oscillations in self-pumped phase conjugation and transmission", P. Venkateswarlu, Mehdi Moghbel, P. Chandra Sekhar, and V. K. Mago, and M. C. George, p 39. (31) "Third-order nonlinearity in chinese tea- a good phase conjugator", Hossin Abdeldayem, P. Chandra Sekhar, V. K. Mago, P. Venkateswariu, and M. C. George, p 39. (32) "Coupling of self-pumped phase conjugate oscillations to reflections and transmissions of incoherent beams in barium titanate", P. Venkateswarlu, Mehdi Moghbel, P. Chandra Sekhar, and V. K. Mago, and M. C. George, p 40. (33) "Triplet-state gratings and degenerate four-wave mixing in disodium fluorescein doped boric acid glass", Hossin Abdeldayem, P. Chandra Sekhar, V. K. Mago, P. Venkateswarlu, and M. C. George, p 258.
Papers presented at International Symposium on Non Linear Optical Materials, The University of Texas at El Paso, October 28 - November 2, 1990: (15-24) (34) "An estimate of the third order nonlinear susceptibility of 7-dicyano apocarotene in hexane by self-phase modulation", H. Abdeldayem, Wen Sheng, P. Venkateswariu, P. Chandra Sekhar, M.C. George, L. Kispert,, and M.R. Wasielewski. (35) "Third order nonlinear susceptibility of poly methyl methacrylate and rhodamine 6G in chloroform by DFWW', H. Abdeldayem, P. Chandra Sekhar, P. Venkateswariu, and M.C. George. (36) "Third order nonlinear susceptibility measurements of 7'-dicyano apocarotene by self trapping", H. Abdeldayem, P. Chandra Sekhar, P. Venkateswarlu, M.C. George, L. Kispert, and M.R. Wasielewski. (37) "Surface enhanced two photon fluorescence and second harmonic generation on interface of air/dye thin films of organic dyes", K. X. He, Hossin Abdeldayem, P. c' Venkateswarlu, and P. Chandra Sekhar. (38) "Second and third-order nonlinear optical properties on surface of lead-tin -50-
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A51 fluorophosphate glass doped with organic dyes", P. Venkateswarlu, William Bryant, K. X. He, and P. Chandra Sekhar. (39) "Beam fanning in organic solutions-a new nonlinear phenomenon", H. Abdeldayem, P. Chandra Sekhar, P. Venkateswarlu, and M.C. George. (40) "Phase conjugate resonators and bistable oscillations in BaTiO3", P. Venkateswarlu, Mostafa Dokhanian, P. Chandra Sekhar, V. K. Mago, and M. C. George. (41) "Transient multiple diffraction rings induced by ultrafast laser from chinese tea", K. X. He, Hossin Abdeldayem, P. Venkateswariu, and P. Chandra Sekhar. (42) "Phase conjugate effects in reflection and transmission in BaTiO3", P. Venkateswarlu, Mostafa Dokhanian, P. Chandra Sekhar, V. K. Mago, and M. C. George (43) "Estimation of the third order nonlinear susceptibility by self trapping and spatial self phase modulation for a variety of organic solutions", H. Abdeldayem, P. Chandra Sekhar, P. Venkateswariu, and M.C. George. Papers published in OSA Annual Meetings, 1989 Technical Digest Series, Vol. 18 (Optical Society of America, Washington, DC, 1989) (Refereed papers) (44) "Effect of self-pumped phase conjugation on reflection and transmission in BaTiO3 and incoherent beam couplings, P. Venkateswarlu, Mehdi Moghbel, P. Chandra Sekhar, V. K. Mago, and M. C. George, p 82-83. (45) "Color selective self pumping of multicolor beams in barium titanate", P. Venkateswariu, Mostafa Dokhanian, P. Chandra Sekhar, and M. C. George, p 83. (46) "Coupling of self-pumped phase conjugate oscillations to reflections and transmission of incoherent beams in barium titanate", P. Venkateswarlu, Mehdi Moghbel, P. Chandra Sekhar, and M. C. George, p 83. (47) "Laser-induced combustion and spectroscopic studies of coal", P. Venkateswarlu, Mehdi Moghbel, P. Chandra Sekhar, and M. C. George, p 91. (48) "Interaction of coherent beams in electrically poled BaTiO3 crystal", P. Venkateswarlu, Mehdi Moghbel, P. Chandra Sekhar, and M. C. George, p 113.
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A52 (49) "Bird-wing phase conjugator with coherent beams", P. Venkateswariu, Mostafa Dokhanian, P. Chandra Sekhar, and M. C. George p 137. (50) "Ring passive phase conjugator and self-pumping in barium titanate", P.Venkateswarlu, Mostafa Dokhanian, P. Chandra Sekhar, and M. C. George, p 137. (51) "Beam couplings in self-pumping, transmission and reflection", Conference of Lasers and Electro-Optics, 1989 Technical Digest Series, Vol. 11 (Optical Society of America, Washington, D.C. 1989) p 198. (52) "Coherent beam coupling and pulsations in self-pumped BaTiO3", Conference of Lasers and Electro-Optics, 1988 Technical Digest Series, Vol. 7 (Optical Society of America, Washington, D.C. 1988) p 220. (53) "Investigation of critical phenomena in the binary System CS2 CH3NO2 by resistivity measurements", J. Ramakrishnan, Anil Kumar, and P. Chandra Sekhar, Phase transitions and phase equilibria, Bangalore, India p 40 (1975).
Undergraduate Research Papers presented by students: At the Mini-Symposium on Undergraduate Research in the Mathematical Sciences, University of South Alabama, 1996 1. Design and construction of a spin coating system for the preparation of organic thin films Warren Cluff, P. Chandra Sekhar, and M. C. George 2. Degenerate four-wave mixing and phase conjugation in solutions of ferrocene in acetone Jeffrey Wrighton, Anandan Shanmugam, P. Chandra Sekhar and M. C. George At the Mini-Symposium on Undergraduate Research in the Mathematical Sciences, University of South Alabama, 2000 3. Determination of linewidth of a diode laser using autocorrelation and FFT techniques Dmitri Krivosheyev, Carl Mungan, Chandra Prayaga 4. Synthesis of nonlinear optical material n-decyl ferrocenoate (n-decyl ferrocene carboxylate) Thomas Austin, Tim Royappa, Carl Mungan, Chandra Prayaga At the Mini-Symposium on Undergraduate Research in Mathematical Sciences, University of Southern Mississippi, 2001 5. Thin films of polymethylmethacrylate doped with rhodamine 6G dye John Thurmond, Troy Durant, Laszlo Ujj, Chandrasekhar Prayaga
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James Stephen Marsh
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A66 Laszlo Ujj
CURRICULUM VITAE Laszlo J. Ujj, Ph.D. Home Address: 151 Euclid St., Pensacola, Florida, 32503 Telephone: (850) 437-0967 (home), (850) 474-2645 (work) E-mail:
[email protected], Web: www.uwf.edu/LUJJ/index.cfm
SUMMARY of QUALIFICATIONS:
• Research Experience: Over 15 years of professional experience in scientific research with international recognition. Published more than 50 papers in nonlinear optics, ultrafast laser spectroscopy, and coherent Raman spectroscopy of photoactive proteins in scientific journals and books. Cited more than 320 times until 2004, and this number is growing. • Teaching Experience: Over ten years of college and graduate level teaching experience. Lectured in general and university physics, mathematical physics, ordinary differential equations, thermodynamics, analytical mechanics, laser physics, and optics. Prepared and supervised laboratory practices. • Optical and Laser Engineering Experience: Supervised and developed state of the art tabletop optical and laser systems. Co-author of a patented spectroscopic method. • Software Engineering Experience: Supervisor of development and designer of data analyzer and instrument control programs. Designed the control software for an automated gas standard. • Conferences. Organized scientific conferences. Presented scientific results at international meetings.
EDUCATION: Post-Doctoral, University of Arizona, with Prof. George H. Atkinson (1991-1994); Ph.D. (Summa Cum Laude), Physics, Thesis: “Time-Resolved Ultrafast Laser Spectroscopy of PhotoActive Proteins”, University of Szeged, Hungary, 2001; Ph.D. (Doctor of the University (Summa Cum Laude)), Nonlinear Optics, Thesis: “Condensed Phase Coherent anti-Stokes Raman Spectroscopy” JPTE University, Hungary, with Prof. I Santa, 1990; Master of Science (Physicist), Thesis: “Free Electron Scattering on Standing Electromagnetic Wave”, JATE University, Szeged, Hungary, with Prof. J. Bergou, 1983. Transcripts and US equivalents of the degrees are available from the Arizona Department of Education and directly from the University of Szeged.
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PROFESSIONAL EXPERIENCE: Associate Professor of Physics, University of West Florida (UWF), Dept. of Physics, Pensacola, FL, 08/2005-present, Assistant Professor of Physics, University of West Florida (UWF), Dept. of Physics, Pensacola, FL, 08/2000-08/2005, Adjunct Faculty, PCC, Tucson, AZ, 01/00-05/00, Scientist, Research Scientist University of Arizona, Tucson, AZ, 1994-2000, Sr. Research Scientist, Innovative Lasers Corporation, Tucson, AZ, 02/1997-05/2000, Assistant Professor of Physics, JPTE Univ., Dept. of Physics, Hungary, 08/90-04/94, Assistant Lecturer, Research Assistant, JPTE Univ., Dept. of Physics, 09/83-08/90.
COLLEGE LEVEL TEACHING EXPERIENCE at UWF: 2009 Spring PHY- 1020 Conceptual Physics (Internet Course), Enrolled 42 PHY- 2048 University Physics I (3 hours/week), Enrolled 50 PHY- 4445 Lasers and Applications (3 hours/week), Enrolled 10 PHZ- 4114 Mathematical Physics II (3hours/week), Enrolled 6 PHY-4910-Independent Research, Enrolled 4 PHY- 4905 Directed Study, Enrolled 1 2008 Fall PHY- 1020 Conceptual Physics (Internet Course), Enrolled 46 PHY- 2049 University Physics II (3 hours/week), Enrolled 24 PHY-3220 Intermediate Mechanics (4 hours/week), Enrolled 6 PHZ- 4113 Mathematical Physics I (3 hours/week), Enrolled 11 PHY- 4905 Directed Study, Enrolled 1 PHY- 4910 Independent Research, Laser Spectroscopy, Enrolled 1 2008 Summer PHY- 1020 Conceptual Physics (Internet Course), Enrolled 24 PHY- 4910 Independent Research, Enrolled 1 2008 Spring PHY- 1020 Conceptual Physics (Internet Course), Enrolled 56 PHY- 2054 General Physics 2 (3 hours/week), Enrolled 43 PHY- 4413 Thermodynamics and Kinetic Theory (Thermal Physics) (3 hours/week), Enrolled 12 PHY- 4905 Directed Study, System control programming with LabView, Enrolled 5 PHY- 4910 Independent Research, Laser Spectroscopy, Enrolled 1 2007 Fall PHY- 1020 1466 Conceptual Physics (Internet Course), Enrolled 54 PHY- 2048 University Physics I (3 hours/week), Enrolled 26 PHY-2053 General Physics I (3 hours/week), Enrolled 39 PHY-3224 Optics (3hours/week), Enrolled 9 PHY-4905 Directed Study, System control programming with LabView, Enrolled 1 PHY- 2905 Directed Study, General Physics, Enrolled 1 2007 Summer PHY- 1020 Conceptual Physics (Internet Course), Enrolled 36 2007 Spring
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A68 PHY- 1020 1404 Conceptual Physics (Internet Course) PHY- 1020 1405 Conceptual Physics (Internet Course) PHY- 2048 University Physics I (3 hours/week) PHY- 4445 Lasers and Applications (3 hours/week) PHY- 4905 Optics, Directed Study 2006 Fall PHY- 1020 1480 Conceptual Physics (Internet Course) PHY- 1020 1481 Conceptual Physics (Internet Course) PHY- 2049 University Physics II (3 hours/week) PHY- 4905 Laser Spectroscopy, Directed Study 2006 Summer PHY- 1020 5666 Conceptual Physics (Internet Course) PHY- 4905 Laser Spectroscopy, Directed Study PHY- 4910 Independent Research 2006 Spring PHY- 1020 Conceptual Physics (Internet Course) PHY- 2048 University Physics I (3 hours/week) PHY-4445 Lasers and Applications (3 hours/week) PHY-4905 Laser Spectroscopy, Directed Study 2005 Fall PHY- 1020 Conceptual Physics (Internet Course) PHY- 2048 University Physics I (3 hours/week) PHY-3220 Intermediate Mechanics (4 hours/week) 2005 Summer PHY- 2048 University Physics II (3 hours/week), PHY- 1020 Conceptual Physics (Internet Course) 2005 Spring PHY- 1020 Conceptual Physics (Internet Course) PHY- 2048 University Physics II (3 hours/week) PHY-4445 Lasers and Applications (3 hours/week) 2004 Fall PHY- 1020 Conceptual Physics (Internet Course) PHY- 2048 University Physics I (3 hours/week) PHY-3220 Intermediate Mechanics (4 hours/week) 2004 Summer PHY- 2048 University Physics II (3 hours/week), PHY- 1020 Conceptual Physics (Internet Course) 2004 Spring PHY- 1020 Conceptual Physics (Internet Course) PHY- 2048 University Physics II (3 hours/week) PHY- 4513 Thermodynamics and Statistical Physics (3 hours/week) 2003 Fall PHY- 1020 Conceptual Physics (Internet Course) PHY- 3220 Intermediate Mechanics (3.75 hours/week) PHY- 2053 General Physics II (3 hours/week) 2003 Spring PHZ- 4114 Mathematical Physics II (3hours/week) PHY- 2053 General Physics I (3 hours/week) PHY- 4513 Thermodynamics and Statistical Physics (3 hours/week)
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A69 2002 Fall PHZ- 4113 Mathematical Physics I (3 hours/week) PHY- 3220 Intermediate Mechanics (3.75 hours/week) MAP-2302 Ordinary Differential Equations (3 hours/week) Supervised Independent Research Supervised Independent Study 2002 Summer PHY- 2053 General Physics II (3 hours/week) 2002 Spring Mathematical Physics II, UWF, (3 hours/week), Special Relativity, UWF, (Internet Course) Modern Physics Lab, UWF, (6 hours/week), 2001 Fall Optics, UWF, (3 hours/week), General Physics II, UWF, (3 hours/week) General Physics I Lab, UWF, (3 hours/week) 2001 Summer General Physics II, UWF, (3 hours/week) General Physics I Lab, UWF, (3 hours/week) 2001 Spring Mathematical Physics II, UWF, (3 hours/week) Thermodynamics, UWF, (3 hours/week) University Physics Lab II, UWF, (3 hours/week) 2000 Fall Mathematical Physics I, UWF, (3 hours/week) Optics, UWF (3 hours/week) General Physics I, UWF, (3 hours/week)
EARLIER TEACHING EXPERIENCES (2000-1984) • Physics 216 (Electricity and Magnetism), lecture (recitation) and laboratory practice (6 hours/week), PCC, Tucson, 2000 • Lasers and Vision (substitute lectures), University of Arizona (UofA), 2 hours, 1999 • Laser spectroscopy, membrane protein preparation (educated new personnel), University of Arizona, 1996-2000 • Undergraduate research supervisor (diploma works), J.P.T.E. Physics Dept., 1989-1990 • Laser fundamentals for graduate medical students (practice), J.P.T.E. Physics Dept., 1 semester 1990 • One semester undergraduate optics and thermodynamics laboratory set up (lab manuals and experimental equipments), J.P.T.E. Physics Dept., 1988-1989 • Lectures and lab practices (optics, thermodynamics, electricity, calculus), J.P.T.E. Physics Dept., 1984-1991
GRANT APPLICATIONS UWF Summer Grants:
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A70 2002 ‘Nonlinear Fitting Procedures for Coherent Raman Spectroscopy’, not supported 2003 ‘Advanced Quantum Physics Experiments‘, awarded $6250. 2004 ‘Development of Nonlinear Optical Methodologies’, not supported Submitted a research proposal to the Research Corporation (2003 May): “Interferometric Coherent Raman Scattering for Quantum Information Processing”. The proposal was not funded though I got very high rank reviewer assessments. Submitted a research proposal to the Research Corporation (2004 May): “Nonlinear Optical Investigations: Development of a Super Broadband Coherent Raman Spectrometer”. The proposal was not supported. S ubmitted proposal: Co-principal Investigator of “NUE Nanotechnology in the First-Year Physical Science Curriculum” proposal”, submitted to NSF, not supported (2006). Amount requested: $200,000.00 Two students with my help submitted and secured two small undergraduate research grant proposals ($2000 each) from the UWF Honors Program Office (2007). 1. Experimental configuration to measure CARS 2. Coherent anti-Stokes Raman Spectroscopy
Co-principal Investigator of “Collaborative Project for Photonics and Laser Physics Education” Proposal submitted to US Department of Education, rejected in 2008. Requested Amount: $1,896,245.00.
SERVICE ACTIVITY AT UWF 1. Student advisor (2001-present) 2. Presented several lectures at the UWF science seminars about the recent advances of the science of vision 3. Presented lectures and experiments on the “Open House” meetings at the Department of Physics (2001-2009) 4. Judge in the Physics Olympics Competition (2001-9 every year) 5. Lead judge in Sciences Fairs (2003,2008) 6. Phone-A-Thon (2003-2008) 7. Lectures about CARS and Quantum computing at the seminars of the Department of Physics (2003) 8. Member of the CAS council (2003-2005) 9. Member of the SSE planning committee (2004-) 10. Adviser of the Society of Physics Student (2004-present) 11. Member of the SeaStars planning committee (2005-present)
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PUBLICATIONS A. Papers in Preparation “CARS spectroscopy of a Molecular Rotor DCVJ”, with colleagues and students, e.g. J. of Raman Spectroscopy B. Published Papers (see list of publications) By 2008: 38 referred, cited publications (see SciFinder Scholar), ~ 350 citations, 2 book chapters, ~29 Conference presentations (lecture, poster, and proceedings).
PHOTO-BIOPHYSICS and PHOTO-BIOCHEMISTRY EXPERIENCE: Published scientific results on the studies of • aromatic compounds in solutions and diphenilhexatriene • photo-active proteins: Bacteriorhodopsin, Rhodopsin, Photoactive Yellow Protein Experience in laser spectroscopy of proteins and membrane protein extractions, preparations.
EXPERIENCE WITH STATE of the ART SPECTROSCOPY METHODS • • • • •
Femtosecond, picosecond, and nanosecond transient absorption Laser induced fluorescence Intra-cavity absorption Raman spectroscopy: cw or pulsed, resonance enhanced, UV, Vis Coherent Raman spectroscopy: Coherent anti-Stokes (Stokes) Raman scattering (CARS), 4Wave mixing Raman induced Kerr effect Polarization sensitive CARS Picosecond Time-resolved Resonance Coherent anti-Stokes Raman Spectroscopy
EXPERIENCE WITH STATE of the ART LASER SYSTEMS • • •
Ti:Sapphire laser system (OSC 1999) (100 fs temporal resolution) Diode-laser pumped cw Tb, Tm:YLF laser with diode array detection (ILC 1998) Passive or active Qs or ML Nd:YAG laser pumped dye lasers and time correlated single photon counting detection system (40-100 ps temporal resolution) (NOD 1987) • Gas lasers (Ar, Nitrogen, Excimer) with PMT detection (JPTE, UFA) • ML Nd:YLF (and/or YAG) laser based synchronously pumped dye lasers and multichannel detection system (LN CCD) (UofA 1990-2000) ( 2-10 ps temporal resolution)
COMPUTER SCIENCES: Program languages: Basic, Fortran, C++, LabView Experienced LabView programmer of system control devices (LV3.48-6.i, LV8.5) in practical lab environment.
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CO-AUTHOR of a HUNGARIAN/EUROPEAN PATENT: Method and apparatus for a spectrometric study of substances based on coherent anti-Stokes Raman dispersion. Santa, Imre; Ujj, Laszlo; Kozma, Laszlo; Almasi, Gabor. (Janus Pannonius Tudomanyegyetem, Hung.). Hung. Teljes (1988), 21 pp. CODEN: HUXXBU HU 44338 A2 19880229 Patent written in Hungarian. Application: HU 86-1574 19860415. Priority: . CAN 109:45864 AN 1988:445864 CAPLUS
WORKED in ACADEMIC PROJECT (S) as RESEARCH SCIENTIST: • Characterization of the first intermediates of rhodopsin (National Institute of Health grant), University of Arizona, 1994-1998 • Electronic and vibrational spectroscopy of bacteriorhodopsin (National Scientific Foundation grant), University of Arizona, 1991-1997 • Transient hologram decay time measurement on bacteriorhodopsin films (German and US joint project), University of Arizona, 1992 • Medical applications of lasers (Biophysics Department Project), Medical University, Pecs, Hungary, 1989-1990 • Investigation of human neuron answer initiated by short laser pulses (Neurology Department project), Medical University, Pecs, Hungary, 1990 • Picosecond Coherent Raman Investigation of the isomerization processes in trans-stilbene (Nonlinear Optics Department), Lomonosov Moscow State University, Moscow, USSR, 1987
SPECIFIC THEORETICAL STUDY: • • • • •
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Free electron scattering on standing EM wave Nanosecond dye lasers and lasers amplifiers Computer modeling and designing of electric discharge tubes and laser resonators Short pulse (picosecond, femtosecond ) generation in solidstate and dye laser, femtosecond lasers and femtosecond optics Laser spectroscopy ( time resolved ( TR) fluorescence, transient absorption, Raman , TR Raman, Coherent Raman: CARS, RIKE, Polarization Sensitive Picosecond Stokes/antiStokes Coherent Raman, TR Coherent Raman) Nonlinear optical spectroscopy (Liouwille-space description)
VISITING, SCHOLARSHIPS: • • • •
Medical University, Royal Institute of Great Britain, London, 07/1986 Central Institute of Academy of Science, Berlin, GDR, 04/1985 Quantum Optics Department, Jena, GDR, 04/1985 Lomonosov Moscow State University, Moscow, USSR, 04-06/1987, 08-12/1987
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University of Jerevan, Jerevan, Armenia, 06/1987 Technical University, Hannover, FRG, 09/1988 Max Planck Institute, Gottingen, FRG, 08/1989 University of Prague, Prague, CSSR, 12/1989 Medical University, University of Bologna, Bologna, Italy, 07/1990 Lomonosov Moscow State University, Moscow, USSR, 08/1990 University of Arizona, Tucson, AZ, USA, 01/1991 University of California, Los Angeles, CA, USA, 07/1992 Technical University of Munich, Munich, FRG, 01/1993 Max Planck Institute, Munich, FRG, 01/1993 Albert Szentgyorgyi Biological Research Centre, Szeged, Hungary, 07/1996 Georgia Institute of Tech., Georgia, USA, 06/1997
•
UCSD, San Diego, USA, 07/1997
ORGANIZING COMMITTEES: • • • •
1st Symposium of Laser Spectroscopy, Pecs, Hungary, Organizing Committee, 1986 2nd Symposium of Laser Spectroscopy, Pecs, Hungary, Organizing Committee, 1989 Int. School on Applied Laser Spectroscopy, Pecs, Hungary, Org. Committee, 1990 Int. Conf. on Quantum Optics, Pecs-Siklos, Hungary, Conference Secretary, 1990
AWARD: Awarded an international scholarship from the Hungarian Cultural Ministry to study nonlinear optical spectroscopy at the Nonlinear Optics Department of the Lomonosov Moscow State University, Moscow, USSR. N. I. Koroteev and A.V. Akhmanov had supervised the six months research in 1987.
MEMBERSHIPS: • •
Eotvos Lorand Physical Society, Hungary American Physical Society, USA
SPECIFIC INDUSTRIAL EXPERIENCE: Optical and Laser Engineering Project: Research and development of a gas analyzer for extremely low concentration trace gas measurement. Innovative Lasers Cooperation, Tucson, AZ (09/1996-01/1997, 03/1997) • Diode pumped cw solid-state laser (Tb, Tm: YLF laser) for intra-cavity absorption spectroscopy • Laser crystal testing (polarization dependence of the absorption spectrum, geometrical parameters,
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A74 quality, emission spectrum) • Diode laser mode shaping (divergence, focusing) for solid-state laser pumping (12/1995-04/1996) Project: R&D of Warner Lambert Inc. • UV Raman setup design for characterization of chemical ingredients, impurity investigations in commercial products Project: Development of a UV-Visible Lasers Fluorimeter with subnanosecond temporal resolution for biological and medical application. Joint project between the Medical & Optical Inc. and the Physics Research Group at the J.P.U, Pecs, Hungary. (06/1987- 12/1989) Optical and mechanical engineering. Project: Complete optical set development for research and industry. System Engineering Inc., Pecs, Hungary (02/1988 - 01/1990) • Designing optics and mechanical components (mounts for mirrors, lenses, and rotators, Sine drivers, beam-shaping (cylindrical and spherical) devices
Software Engineering Designed system control and data analyzer softwares. Project: Development of a Coherent Raman Spectrometer, Control and data processing software in LebView 6.i and 8.5, Dept. of Physics, UWF, 2005-present Project: R&D at Innovative Lasers Corporation, Tucson, AZ (02/1998-01/2000) • Monochromator control software (McPherson 1000) and data acquisition with Lock-In amplifier (Princeton Instruments), data handling, automatic spectrum recording • Picomotor control software (New Focus) • Oscilloscope Control and data acquisition software (LeCroy scope) • Laser control software (Polus fiber laser, diode laser) • Communication protocol for remote control of a gas standard (Automated Gas Standard) • Automated Gas Standard control software, data handling, noise analyzing, valve and solenoid and mass flow controller controls, temperature measure and control, scheduler • Super gas flow control with eight mass flow lines • Data Analyzer (data processor, statistic maker) • Control and data processor software for automated gas analyzer and sensor (diode laser control, system parameter setup, calibrator, time synchronizer, gas parameter calculator), file and screen appearance handling, linear and nonlinear fitting Computer language: LabView 5.01 and earlier versions
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LIST OF PUBLICATIONS OF DR. Laszlo J. Ujj Years 2009 Scientific papers in progress: Rotational Blockage Influence on Internal Vibrational Motion of a Charge Transfer Molecular Rotor DCVJ, J. of Raman Spectroscopy, or a similar journal
Years 2008-2005 Laszlo Ujj, "The Physics of Coherent Raman Spectroscopy”, lecture at the March meeting of the American Physical Society, New Orleans, March 2008. D. Watson, J.D. Olitzky, E. Knowles, L. Ujj, "Polarization Sensitive CARS Analysis of Molecular Vibrational Spectra” at the SeaStars, UWF (2008). Josh Olitzky, Chris Clanton, Dr. Laszlo Ujj,”Investigations of Coherent Anti-Stokes Raman Spectroscopy”, Dean's Award for Collaborative Research, UWF (2007). J.D. Olitzky, C. Clanton, L. Ujj, "Development of Coherent anti-Stokes Raman Spectroscopy” at the SPS Zone 6 meeting at the Florida Institute of Technology, (2007). The poster won the best undergraduate research award. A. C. Terentis, L. Ujj, H. Abramczyk, G.H. Atkinson “ Primary Events in Bacteriorhodopsin Photocycle: Torsional Vibrational Dephasing in the First Excited Electronic State”, Chemical Physics, 313, 51-62, (2005).
Years 2003-2002 A. C. Terentis, Y. Zhou, G. H. Atkinson, L. Ujj, “Picosecond Time-Resolved Coherent Ant-Stokes Spectroscopy of the Artificial Bacteriorhodopsin Pigment, BR6.11”, J. Phys. Chem. A, 107, 10787-10797 (2003). L. Ujj, A. C. Terentis, G. H. Atkinson, “Time-Resolved Resonance Coherent Anti-Stokes Raman Spectroscopy Investigations: Structural Dynamics of Photo-Active Proteins: Bacteriorhodopsin 6.11”, in Proceedings of XVIIIth International Conference on Raman Spectroscopy, John Wiley & Sons. Ltd. (2002). G. H. Atkinson, Y. Zhou, L. Ujj, A. Aharoni, M. Sheves, and M. Ottolenghi, “Dynamics and Retinal Structural Changes in the Photocycle of the Artificial Bacteriorhodopsin Pigment BR6.9”, J. Phys. Chem. A, 106, 3325-3336 (2002).
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A76 Laszlo Ujj, Colin G. Coates, John M. Kelly, Paul E. Kruger, John J. McGarvey, and George H. Atkinson, “Picosecond Coherent Vibrational Spectroscopy (CARS) of a DNA-Intercalating Ru Complex”, J. Phys. Chem. B,106, 4854-4862 (2002). Laszlo Ujj and George H. Atkinson, “Coherent Anti-Stokes Raman Spectroscopy”, in Handbook of Vibrational Spectroscopy, John Wiley & Sons. Ltd. (2002).
Years 2000-2001 Y. Zhou, L. Ujj, T. E. Meyer, M. A. Cusanovich, G. H. Atkinson, “ Photocycle Dynamics and Vibrational Spectroscopy of the E46Q Mutant of Photoactive Yellow Protein”, J. Phys. Chem., A 105, 23, 5719-5726 (2001). L. UJJ, Y. Zhou, M. Sheves, M. Ottolenghi, and G. H. Atkinson, A Vibrational Spectrum of a J-Like Bacteriorhodopsin Intermediate: Picosecond Time-resolved CARS of T5.12 in the Artificial BR5.12 Photo-reaction@, J. Am. Chem. Soc., 122, 1, 96-106 (2000). G. H Atkinson, L. Ujj, and Y. Zhou, AVibrational Spectrum of the J-625 Intermediate in the Room Temperature Bacteriorhodopsin Photocycle@, J. Phys. Chem. A, 104, 18, 4130- 4139 (2000).
Year 1999 Savita Devanathan, Andrew Pacheco, Laszlo Ujj, Michael A. Cusanovich, Gordon Tollin, and Su Lin, Neal Woodbury, AFemtosecond Spectroscopic Observations of Initial Intermediates in the Photocycle of the Photoactive Yellow Protein from E. Halophila, Biophysical Journal, 77, 1017-1023 (1999). G. H. Atkinson, F. Jager and L. Ujj, AReactive Intermediates in the Room Temperature Rhodopsin Photo-reactions: Picosecond Time-Resolved CARS@, Laser Chemistry, 19, 1-4, 127-132 (1999). Y. Zhou, L.Ujj, J.Lou, F. Jäger, K. Nakanishiand G.H.Atkinson. , ACoherent Anti-Stokes Vibrational Raman Spectra of Artificial Rhodopsin Pigments Containing Ring Structures Blocking 13-cis Isomerization@, Journal of Molecular Structure, 478, 1-3, 107-119 (1999)
Year 1998 L. Ujj, F. Jager, G. H. Atkinson, "Vibrational Spectrum of the Lumi Intermediate in the Room Temperature Rhodopsin Photo-Reaction", Biophysical Journal, 74, 1492-1501 (1998).
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A77 L. Ujj, S. Devanathan, T.E. Meyer, M.A. Cusanovich, G. Tollin, and G. H. Atkinson, "New Photocycle Intermediates in the Photoactive Yellow Protein from Ectothiorhodospira Halophila: Picosecond Transient Absorption Spectroscopy", Biophysical Journal, 75, 406-412 (1998). F. Jager, J. Lou, K. Nakanishi, L. Ujj, G. H. Atkinson, "Vibrational Spectroscopy of a Picosecond, Structurally Restricted Intermediate Containing a 7-Membered Ring in the Room-Temperature Photo-Reaction of an Artifical Rhodopsin", J. Am. Chem. Soc., 120,15, 3739-3747(1998).
Year 1997 Olaf Weidlich, Laszlo Ujj, Frank Jager, G. H. Atkinson,"Nanosecond Retinal Structure Changes in K-590 During the Room-Temperature Bacteriorhodopsin Photocycle: Picosecond Time-Resolved Coherent Anti-Stokes Raman Spectroscopy", Biophysical Journal, 72, 2329-2341 (1997). Edgar Ligon, Laszlo Ujj, Olaf Weidlich, Andreas Popp and G. H. Atkinson,"Vibrational Spectra of Blue-Membrane Bacteriorhodopsin: Picosecond Resonance Coherent Anti-Stokes Raman Spectroscopy ", Journal of Raman Spectroscopy, 28, 347-353 (1997). F. Jager, L. Ujj, G. H. Atkinson, "Vibrational Spectrum of Batho in the Room-Temperature Rhodopsin Photo-Reaction", J. Am. Chem. Soc.,119,51, 12610-12618 (1997).
Year 1996 L. Ujj, F. Jager, A. Popp, G.H.Atkinson, "Vibrational Spectrum of the K-590 Intermediate in the Bacteriorhodopsin Photocycle at Room Temperature: Picosecond Time-Resolved Resonance Coherent Anti-Stokes Raman Spectroscopy", Chemical Physics, 212, 421-436 (1996). F. Jager, L.Ujj, G.H. Atkinson, M. Sheves, M. Ottolenghi, "Vibrational Spectrum of K-590 Containing 13 C14-13C15 Retinal: PTR/CARS of the Room Temperature Bacteriorhodopsin Photocycle", J. Phys. Chem., 100, 29,12066-12075 (1996). A. Popp, L. Ujj and G.H. Atkinson,"Batho-Rhodopsin in the Room-Temperature Energy Storage Mechanism of Vision", Proc. Natl. Acad. Sci. USA, 93,372-376 (1996). J. Popp, A. Popp, L. Ujj, G.H. Atkinson, M. Sheves, M. Ottolenghi, "Vibrational Analysis of Coherent Anti-Stokes Resonance Raman Spectra from Bacteriorhodopsin Containing Isotopically-Substituted Retinal Chromophores", Journal of Raman Spectroscopy, 27,87-95 (1996).
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Year 1995 L. Ujj, F. Jager, A. Popp, R. Ligon & G. H. Atkinson, "Picosecond Time-Resolved Resonance Coherent Anti-Stokes Raman Spectroscopy of Bacteriorhodopsin: Experimental Challenges and the K-590 Spectrum", in Proceedings of the 7th Int. Conf. on Time-Resolved Vibrational Spectroscopy, Los Alamos, LA-13290-C, UC-901 and UC-910, 281-282 (1995/1997). Popp, L. Ujj, G.H. Atkinson, "Picosecond Dynamics of Photo to Batho Transformation with Room Temperature Rhodopsin Photosequence", J. Phys. Chem., 10043-10045 (1995). Popp, L. Ujj, G.H. Atkinson, "Vibrational Spectra of Room Temperature Rhodopsin: Concentration Dependence in Picosecond Resonance Coherent Anti-Stokes Raman Scattering", Biophysical Chemistry, 56, 129-135 (1995). G. H. Atkinson, L. Ujj, A. Popp, J. Delaney, F. Jager, and R. Ligon, "Picosecond Time-Resolved Coherent Anti-Stokes Raman Spectroscopy: Studies in the Room Temperature Bacteriorhodopsin and Rhodopsin Photo-Reactions", in Proceedings of the 7th Int. Conf. on Time-Resolved Vibrational Spectroscopy, Los Alamos, LA-13290-C, UC-901 and UC-910, 15-19 (1995/1997). R. Ligon, L. Ujj, A. Popp, F. Jager, and G. H. Atkinson, "Picosecond Resonance CARS Spectroscopy: Vibrational Spectra of the Deionized Form of Bacteriorhodopsin (Blue Membrane)", in Proceedings of the 7th Int. Conf. on Time-Resolved Vibrational Spectroscopy, Los Alamos, LA-13290-C, UC-901 and UC-910, 283-284 (1995/1997). F. Jager, L. Ujj, A. Popp, J. Popp and G. H. Atkinson, "A Picosecond Time-Resolved CARS Investigation on the Isotopically-labeled 13 C14-13C15 Bacteriorhodopsin", in Proceedings of the 7th Int. Conf. on Time-Resolved Vibrational Spectroscopy, Los Alamos, LA-13290-C, UC-901 and UC-910, 285-286 (1995/1997).
Year 1994 L. Ujj, Volodin, A. Popp, J.K. Delany, G.H. Atkinson, "Picosecond Resonance Coherent Anti-Stokes Raman Spectroscopy of Bacteriorhodopsin: Spectra and Quantitative Third -Order Susceptibility Analysis of the Light-Adapted BR-570", Chemical Physics, 182, 291-311 (1994). L.Ujj, A. Popp, G.H. Atkinson, "Picosecond Resonance Coherent Anti-Stokes Raman Spectroscopy of Bacteriorhodopsin: Spectra and Quantitative Third -Order Susceptibility Analysis of the Dark -Adapted Bacteriorhodopsin Mixture", Chemical Physics, 188, 221-234 (1994). G.H. Atkinson, A. Popp, L. Ujj, "Picosecond-Resonance Coherent Anti-Stokes Raman Scattering in Biophysics: Power Dependence in the Bacteriorhodopsin Photocycle", inTime-Resolved Vibrational Spectroscopy VI, Springer Proceedings in Physics, 74, 153-157, (1994).
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A79 A.Popp, L. Ujj, G.H. Atkinson, "Picosecond Time-Resolved Vibrational Spectrum of Batho-Rhodopsin at Room Temperature: Concentration Effect", in Ultrafast Phenomena Proceedings, Series 7,230-232 (1994). A. Popp, L. Ujj and G.H. Atkinson, "Batho-Rhodopsin: Picosecond Time-Resolved CARS Spectrum at Room Temperature," in Proceedings of XIV Intern. Conf. Raman Spect., Hong Kong, John Wiley Publ., 141-142 (1994).
Years 1989-1993 L. Ujj, G.H. Atkinson, "Picosecond Resonance Coherent Anti-Stokes Raman Spectroscopy of Light- and Dark-Adapted Bacteriorhodopsin", Israel Journal of Chemistry, 33, 207-214 (1993) G. H. Atkinson, L. Ujj, "Picosecond Time-resolved Resonance CARS of Bacteriorhodopsin ", Int. Symp. on Ultrafast Processes in Spectroscopy, Bayreuth, Inst. Phys. Conf. Ser. No 126: Section VIII, 599-604 (1991). L. Ujj, A.F.Bunkin, I.Santa, G.Almasi, L.Kozma, " Nonlinear Raman Spectroscopy of Liquids ", Acta Physica Hungarica, 68, 1-2, 71-79 (1990). L. Ujj, J. Erostyak, I. Santa, L. Kozma, " Resonance Coherent Stokes Raman Spectroscopy Study of AllTrans-Diphenylhexatriene in the Ground and Excited Electronic States ", 3rd European Conf. on the Spectroscopy of Biological Molecules, Rimini, Italy, 305-307 (1989).
Years 1985-1988 L. Ujj, I. Santa, G. Almasi, L. Kozma, " CARS Experimental Arrangement to Study Liquid Samples", 1st Symposium on Laser Spectroscopy, JPTE Publishing, Pecs, Hungary, p. 188-193 (1986). L. Ujj, I. Santa, L. Kozma, " Coherent Anti-Stokes Raman Spectroscopy", IX. Hungarian Luminescence and Spectroscopy Conf. (OLSI), JPTE Publishing, Pecs, Hungary,1-16 (1986) I. Santa, L. Ujj, L. Kozma, " The First Steps in the Coherent Raman Spectroscopy in Hungary ", Hungarian Physical Review (Fizikai Szemle) 9, 356-360 (1985).
CONFERENCE LECTURES AND POSTERS PRINTED IN TECHNICAL DIGESTS (1985-2003) I. Santa, L. Ujj, L. Kozma, "CARS Experimental Apparatus for Studies of Liquid Structure", poster, 5th Int. Conference on Lasers and their Applications, Dresden, GDR, p. 139 (1985). L. Ujj, J. Erostyak, I. Santa, L. Kozma, " Polarization Sensitive Resonance Coherent Raman Spectroscopy Study of All-Trans-Diphenylhexatriene in the Excited Electronic States ", lecture, poster, EQEC '88, Hannover, FRG, p. TUBD2 (1988).
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A80 L. Ujj, J. Erostyak, I. Santa, L. Kozma, " Multichannel Detection for Nonlinear Raman Spectroscopy", poster, XIII. KINO, Minsk, USSR, poster, 734 (1988). L. Kozma, L. Ujj, " New Nonlinear Methods to Study the Electronically Excited Molecules ", lecture, Hungarian Chemistry Meeting, Pecs, Hungary, p. 176 (1988). L. Ujj, B. Volodin , A. Popp, G.H. Atkinson, " CARS study of the Bacteriorhodopsin Photocycle and Related Isotopically Substituted Analogies: Polarization Sensitive Picosecond Raman Spectroscopy of Light and Dark adapted BR", poster Dynamics and Function of Biomolecules (IUPAP), Szeged, Hungary, p. 75 (1993). F. Jager, L. Ujj, O. Weidlich, A. Poop and G.H. Atkinson, " Isotopic Effects in the Room Temperature ( 13 C -retinal ) BR-Photocycle: Picosecond Time-Resolved CARS Spectroscopy", poster, 7th International Conference on Retinal Proteins, Zichron Yaacov, Israel, (1996). L. Ujj, F. Jager ,O. Weidlich, A. Poop and G.H. Atkinson, " Vibrational Spectra of the K-590 Intermediate in the BR Photocycle at Room Temperature : Picosecond Time-Resolved CARS", poster, 7th International Conference on Retinal Proteins, Zichron Yaacov, Israel, (1996). Laszlo Ujj, Frank Jager, and George H. Atkinson, A Elucidating the Photo-sequences of Photo-active Proteins@, poster The 11th Int. Conf. On Fourier Transform Spectroscopy, Athens, Georgia, M27 (1997). L. Ujj, Y. Zhou, G. H. Atkinson, "Picosecond Time-Resolved Resonance Coherent Anti-Stokes Raman Spectroscopy of Retinal Proteins@, lecture, poster 9th Int. Conf. on Time-Resolved Vibrational Spectroscopy, Tucson, (1998). Andrew C. Terentis*, George H. Atkinson*, Laszlo J. Ujj**, Yidong Zhou#, M. Sheves+, M. Ottolenghi++, “Time-Resolved Coherent Anti-Stokes Raman Spectroscopy of Artificial Bacteriorhodopsin Pigments”, poster, 10th International Conference on Retinal Proteins, University of Washington, Seattle USA, August 2024, (2002). * Department of Chemistry and Optical Science Center, University of Arizona, Tucson, Arizona 85721 ** Department of Physics, University of West Florida,Pensacola, Florida 32514 # Lightwave Electronics Corp., 2400 Charleston Road,Mountain View, CA 94043 + Department of Organic Chemistry,Weizmann Institute, Rehovot, Israel, ++ Department. of Physical Chemistry, Hebrew University, Jerusalem, Israel International Conference on Raman Spectroscopy: ICORS XIII Time-Resolved Resonance Coherent Anti-Stokes Raman Spectroscopy Investigations: Structural Dynamics of Photo-Active Proteins: Bacteriorhodopsin 6.11, Laszlo J. Ujj, Department of Physics, University of West Florida, Pensacola, Florida 32514, Andrew C. Terentis and George H. Atkinson, Department of Chemistry and Optical Science Center, University of Arizona, Tucson, Arizona 8572, M. Sheves, Department of Organic Chemistry, Weizmann Institute, Rehovot, Israel M. Ottolenghi, Department of Physical Chemistry, Hebrew University, Jerusalem, Israel, Yidong Zhou, Lightwave Electronics Corp., 2400 Charleston Road., Mountain View, CA 94043.
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A81 Andrew C. Terentis*, Halina Abramczyk**, Laszlo Ujj+, and George H. Atkinson*, “Time-Resolved CARS Spectroscopy of Bacteriorhodopsin: Vibrational Spectrum of a Picosecond Intermediate in the Photoreaction of the 13-cis-Locked Artificial Bacteriorhodopsin Pigment BR5.13, poster 11th International Conference on Time-Resolved Vibrational Spectroscopy, Castiglione della Pescaia, Italy May 24-29, (2003). * Department of Chemistry and Optical Science Center, University of Arizona, Tucson, Arizona 85721 ** Technical University of Lodz, Poland + Department of Physics, University of West Florida,Pensacola, Florida 32514
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Guoqing Wu
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12.8 Syllabi of all Courses Affiliated to the Physics Department
EGM 2500 ENGINEERING MECHANICSSTATICS
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EGM 3401 ENGINEERING MECHANICSDYNAMICS
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A101 PHY 1020 INTRODUCTION TO CONCEPTS IN PHYSICS
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COURSE POLICY STATEMENT – DEPARTMENT OF PHYSICS PHY 1020L INTRODUCTION TO CONCEPTS IN PHYSICS LAB
COURSE:
PHY1020L Concepts in Physics Laboratory
TEXT:
How Everything Works by Bloomfield ISBN : 047174817X Your text book will also be very helpful.
WITHDRAWLS: UWF policy requires that students submit to the Office of Records and Registration a completed withdraw from courses, which is a different policy from that used by some other institutions, notably PJC. Withdrawals from this course that are processed by Friday, March 20, 2009 will result in a “W” grade being recorded. Withdrawals after this date can be done only by withdrawing from the University; the grade assigned will be W or WF. No withdrawals can be made after the close of classes. GRADING: There will be 10 labs each worth 10 points and 1 final exam worth 20 points. LABORATORY PROCEDURES: You will work in groups of two unless there are not enough setups available. Each of you will independently collect and record the data, and write a lab report. ATTENDANCE: Please attend another lab section or otherwise make it up by arrangement with Bill Caplinger (the lab manager) while the lab set up is still available if you miss a lab session; you responsible for checking with your primary instructor for special instructions and extra problems which other instructors may not assign. Missing reports will receive a grade of 0 at the end of the semester.
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CONCEPTS IN PHYSICS LABORATORY SCHEDULE Spring 2008 LAB #
1
DATE
TITLE
1/5-1/9
Introduction & Syllabus Handout
1/12-1/16
Pendulums
1/19-1/23
No Lab 1/20 MLK Birthday
2
1/26-1/30
Acceleration
3
2/2-2/6
Spring Energy
4
2/9-2/13
Collisions
5
2/16-2/20
Static Forces
6
2/23-2/27
Buoyancy
7
3/2-3/6
Circular Motion
3/9-3/13
No Lab Spring Break
8
3/16-3/20
Heat Transfer
9
3/23-3/27
Light Rays
10
3/30-4/3
Waves
4/6-4/10
Lab Final
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A106 Expectations for Academic Conduct/Plagiarism Policy: As members of the University of West Florida, we commit ourselves to honesty. As we strive for excellence in performance, integrity—personal and institutional—is our most precious asset. Honesty in our academic work is vital, and we will not knowingly act in ways that erode that integrity. Accordingly, we pledge not to cheat, nor to tolerate cheating, nor to plagiarize the work of others. We pledge to share community resources in ways that are responsible and that comply with established policies of fairness. Cooperation and competition are means to high achievement and are encouraged. Indeed, cooperation is expected unless our directive is to individual performance. We will compete constructively and professionally for the purpose of stimulating high performance standards. Finally, we accept adherence to this set of expectations for academic conduct as a condition of membership in the UWF academic community. Please, read also Approved Academic Misconduct Policy and Student Code of Conduct at http://uwf.edu/judicialaffairs/documents/BOTApprovedAcademicMisconductPolicy-2007edition.pdf http://uwf.edu/judicialaffairs/documents/BOTApprovedStudentCodeofConduct-2007edition.pdf
ASSISTANCE: Students with special needs who require specific examination-related or other course-related accommodations should contact Barbara Fitzpatrick, Director of Disabled Student Services (DSS),
[email protected], (850) 474-2387. DSS will provide the student with a letter for the instructor that will specify any recommended accommodations.
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COURSE SYLLABUS PHY 2048 UNIVERSITY PHYSICS I
Course Prefix/Number: PHY 2048 Course Title: University
Physics I
Course Credit Hours: 3 Hours Course Description: University Physics I is the first of a two-semester sequence of physics topics chosen as an introduction to this science. This is a calculus based physics course. The principal topics covered in this course are mechanics-the science of motion- (kinematics and dynamics) of particles and rigid bodies including the laws of motion, conservation laws and principles, gravity and oscillations. Mechanics is the basis for much of engineering and applied science, and many of the ideas introduced here will be needed later to understand things like the motion of waves and the motion of electrons through circuits or the contemporary concepts of science including modern physics. We will cover at minimum chapters 1-14 of the text book, than select topics by demand e.g. fluids and elasticity. Remember that this is a problem-oriented course. You will be responsible only for the material covered in class and assigned for special reading. Student Learning Outcomes: • In accordance with the general educational mission, you are here to learn new analytical tools that will serve you well in a broad range of professions. • The course will generate interest for a deeper understanding of nature. • Along the way of mastering the subject you will learn how to use physics to analyze and solve many practical problems. • Specifically, a student who masters this subject will have the following skills: • The ability to model reality in terms of abstract objects and physical laws. • The ability to express these models verbally. • The ability to express these models graphically. • The ability to express these models mathematically. • The ability to manage complexity in terms of distinct and simpler concepts.
Requirements: • Text Book:
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Physics for Scientists and Engineers Second Edition (with Modern Physics), A Strategic Approach, by Randall D. Knight, Addison Wesley, ISBN-13: 978-08053-2736-6 Web access for online assignments and the campus eLearning system. • Software: Mastering Physics – Student Access Kit (Comes with the Text book) • Supplement: Student Workbook (Comes with the Text Book) • Use of Active Physics OnLine (accessed via www.masteringphysics.com) •
Optional: •
Physics for Scientists and Engineers: Student Solutions Manual, Chapters 1-19
Prerequisites or Co-Requisites: MAC 2311 or equivalent. This is strictly enforced. Topics Covered:
1 2 3 4 5 6 7 8 9 10 11 12 13 14
Topic Concepts of Motion Kinematics in one Dimension Vectors and Coordinate Systems Kinematics in Two Dimension Midterm Exam 1 Force and Motion Dynamics I: Motion along a Line Newton’s Third Law Dynamics II: Motion in a Plane Midterm Exam 2 Impulse and Momentum Energy Work Midterm Exam 3 Rotation of a Rigid Body Newton’s Law of Gravity Oscillations Final Exam
Week 1 2 3 4 4-5 5 6 7 8 8-9 9 10 11 11-12 12 13 14
WITHDRAWALS: UWF policy requires that students submit to Records and Registration a completed withdrawal form to withdraw from courses, which is a different policy than that used by some other institutions (see the 2008-2009 Catalog of UWF). Grading / Evaluation:
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A109 There will be 3 midterm tests and a final exam. Both will be closed book but open notes exams. It is a good idea to use and create a handwritten notebook during the lecture classes and summarize all the important concepts from the text book. You will ACTIVELY participate in the class by working out the STUDENT WORKBOOK in the class. Problems and questions will be assigned as homework. Only a few of these will be worked out in class. It is important that you work out homework problems before looking at solutions. The tests will be very similar to these. You can submit as many problems as you are able to do in the time given to you. Submission of homework must be before the set deadline. No excuses will be entertained. Homework must be done neatly and the sheets must be stapled together.
Grades are assigned according to the following scale: 100 points for each midterm tests, 100 for the homework, 100 for the workbook, and 100 for the final. Total points for the semester are 600. 90 -100% A; 85 – 89.9% A- ; 80 – 84.9% B+ ; 75 – 79.9% B;70 – 74.9% B- ; 65 – 69.9% C+ ; 60-64.9 C; 55-59.9 C-, 50-54.9 D; < 50 F. Expectations for Academic Conduct/Plagiarism Policy: As members of the University of West Florida, we commit ourselves to honesty. As we strive for excellence in performance, integrity—personal and institutional—is our most precious asset. Honesty in our academic work is vital, and we will not knowingly act in ways that erode that integrity. Accordingly, we pledge not to cheat, nor to tolerate cheating, nor to plagiarize the work of others. We pledge to share community resources in ways that are responsible and that comply with established policies of fairness. Cooperation and competition are means to high achievement and are encouraged. Indeed, cooperation is expected unless our directive is to individual performance. We will compete constructively and professionally for the purpose of stimulating high performance standards. Finally, we accept adherence to this set of expectations for academic conduct as a condition of membership in the UWF academic community. Please, read also Approved Academic Misconduct Policy and Student Code of Conduct at http://uwf.edu/judicialaffairs/documents/BOTApprovedAcademicMisconductPolicy-2007edition.pdf http://uwf.edu/judicialaffairs/documents/BOTApprovedStudentCodeofConduct-2007edition.pdf
ASSISTANCE: Students with special needs who require specific examination-related or other course-related accommodations should contact Barbara Fitzpatrick, Director of Disabled Student Services (DSS),
[email protected], (850) 474-2387. DSS will provide the student with a letter for the instructor that will specify any recommended accommodations.
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A110 PHY 2048L UNIVERSITY PHYSICS I LAB
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COURSE POLICY STATEMENT – DEPARTMENT OF PHYSICS PHY 3106L MODERN PHYSICS LAB
COURSE:
PHY3106L Modern Physics Laboratory
TEXT:
No specific books are required. You will reference your text and any other material that are deemed useful.
WITHDRAWLS: UWF policy requires that students submit to the Office of Records and Registration a completed withdraw from courses, which is a different policy from that used by some other institutions, notably PJC. Withdrawals from this course that are processed by Friday, October 31, 2008 will result in a “W” grade being recorded. Withdrawals after this date can be done only by withdrawing from the University; No withdrawals can be made after the close of classes. GRADING: There will be 6 labs, each worth 25 points, and a seminar (presentation) on one of your experiments worth 50 points. For each lab, the points are distributed equally between the experiment itself, and the lab report. A further 50 points are allotted for discussions with each of the physics faculty (Drs Prayaga, Ujj and Wu) on each experiment. This works like this. For each experiment, it will be your responsibility to seek an appointment with each faculty member, and discuss the experiment with him, and he will grade you based on that discussion. Your total grade will be calculated as a straight percentage of the total number of points.
90 -100% A ;
85 - 89% A- ;
80 - 84% B+ ;
75 - 79% B
70 - 74% B- ;
60 - 69% C ;
50 - 59% D;
< 50% F
LABORATORY PROCEDURES: You will work in groups of two unless there are not enough students available to make an even group. Each of you will independently collect and record the data that you and your lab partner observe. ALL observations and data should be recorded in your lab notebook Instructions for how your lab notebook, formal report and presentation are attached. ATTENDANCE: You are expected to spend 6 hours a week as scheduled in the lab or library working on you experiment or the associated research for the experiment. This will most likely not be a sufficient amount of time to complete all that is necessary. Hence you should plan to spend an equal amount of time outside of the scheduled lab time to work on each experiment. You are also expected to attend all of the presentations given during the
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A137 semester. Missing one or more presentation will count against the grade you receive on your own presentation. General Notes and Hints: This is a discovery type of lab. Therefore the instructor will not tell you exactly what to do or which button to turn to find the desired result. More than likely it will also take you more than the assigned 6 hours a week to complete the experiment. It is recommended that you and your lab partner make arrangements to meet and work on your experiment outside of lab time. Sources of information are everywhere. You may use anything you like as a source as long as you report what it was in your lab book. Some good sources are the physics library, the John C Pace library, the internet, Dr. Chandra and Dr.Marsh. Seminar Presentation Guidelines 1. Presentations should be 30-40 minutes in length. 2. Slides of some sort are highly recommended. (PowerPoint, transparencies, etc.) 3. You and your lab partner may work on the presentation together but each of you will present it separately. 4. You may use any diagrams, models, etc that you like to help illustrate your point. Journal Submission This link http://www.jurp.org/articles/aboutjurp.htm will take you to the Journal of Undergraduate Research in Physics’ submission. You should use this format when preparing your formal write-up.
How to Keep a Lab Notebook A lab notebook is the way real scientists keep track of their work. It may seem tedious or even unnecessary to you, but it is an important part of any lab experience. The notebook should be complete enough that you could refer back to it in a few years and repeat the experiments. General Guidelines: 1. The Notebook must be permanently bound: no loose-leaf or spiral notebooks. 2. Handwriting must be legible. Your TA will not grade materials that he or she cannot easily read. All notes should be taken in pen with the exception of colored drawings that may be done with pencils. Errors should be crossed through with a single line, not erased or obliterated. 3. All information in the notebook must be handwritten or represent actual results, such as photographs. Do not place any photocopied material into your notebook unless specifically directed to do so. 4. Everything you do in the laboratory should be recorded in your lab notebooks, including notes, drawings, data, speculations, etc. Everything from your initial strategy through planning, execution and interpretation should be in your notebook. 5. Keep all of your lab-related notes, including lab lecture notes, in one notebook. Keep a separate binder for the lab manual and lab handouts. 6. Keep in mind that reports and presentations will be prepared from the notebook. -137-
A138 You should have much more information recorded in your notebook than you can or should put on a poster or into a presentation.
The notebook should include: 1. 2. 3. 4.
The first two pages reserved for a table of contents. Notes from lab lectures, discussions and your own research. Answers to assigned questions. Prelab Section for experiments: • Title of experiment and date. • The Objective(s) of the lab: what you are trying to do and why you are trying to do it. • The Procedure in flow chart or outline form. This should not be an exact copy of the lab manual instructions, but reworked in a manner easy for you to fallow 5. Any deviations from your written procedure. This includes changes both intentional and accidental. 6. Observations: everything that happens during your experiment that may have a bearing on the outcome or interpretation of the experiment (this includes color, precipitate, time, temperature, etc). 7. Data: raw and calculated. Use complete sentences, tables and graphs where appropriate. Show sample calculations with steps and units. 8. Discussion: Interpret your results. Refer back to your predictions. Draw conclusions about experiment. Make suggestions for further experiments or refinements to the procedure. Student Learning Outcomes: 1. Follow experimental procedures including lab safety, maintaining a lab notebook, proper data recording, statistical analysis of data, and reporting results 2. Measure and explain the significance of the measurement of some of the fundamental constants in nature, such the charge of the electron, the mass of the electron, and the speed of light. 3. Measure the characteristic behavior of alternating electrical circuits, in terms of currents, voltages, and impedances 4. Measure the spacing between atoms in a solid 5. Measure the gamma decay of some elements. 6. Measure the wavelength of light List of experiments: 1. 2. 3. 4. 5. 6. 7.
Gamma Ray Spectroscopy Milliken Oil Drop X-Ray Diffraction Michelson Interferometer e/m of an electron Speed of light AC circuits
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A139
COURSE SYLLABUS Course Prefix/Number: PHY 3107 PHY 3107 MODERN PHYSICS II
Course Title: Modern Physics II Required texts: 1. Physics for Scientists and Engineers, A Strategic Approach, By Randall D Knight, Addison Wesley, 2nd Ed. 2. Introduction to Quantum Mechanics, David J Griffiths, Pearson PrenticeHall (2005) Prerequisites or Co-Requisites: PHY3106 WITHDRAWALS: UWF policy requires that students submit to the Office of Records and Registration a completed withdrawal form to withdraw from courses, which is a different policy from that used by some other institutions, notably PJC. Withdrawals from this course that are processed by Friday, March 20, 2009 will result in a "W" grade being recorded. Withdrawals after this date can be done only by withdrawing from the University; the grade assigned will be W or WF. No withdrawals can be made after the close of classes. Course Description: Modern Physics II is the second of a two-semester sequence of topics in Modern Physics. The principal topics covered in this course are Atomic and Nuclear Physics, Quantum Mechanics. Student Learning Outcomes: Upon successful completion of the course, the student must be able to analyze the structure and spectra of atoms using the principles of quantum mechanics; describe the structure and stability of nuclei and discuss the different forms of radioactive decay. Topics Covered: Topic 1 Hydrogen atom 2 Energy levels and quantum numbers, wave functions 3 Electron spin, multielectron atoms, exclusion principle,
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Week 1 1, 2 3
A140
10
periodic table Excited states, spectra, lasers Nuclear structure, stability, shell model, radioactivity Decay mechanisms, α−, β−, γ−decay, weak interactions Principles of quantum mechanics, wave function, probability, uncertainty principle 1-d quantum mechanics Mid-semester Exam Formalism, Hilbert space, observables, vectors inner products, matrices Change of basis, eigenvectors and eigenvalues, hermitian operators
11 12 13 14
Statistical interpretation, uncertainty principle Angular momentum Hydrogen atom Final Exam
4 5 6 7 8
9
4 4, 5 5, 6 7 8, 9 10, 11 12 12, 13 14 15
Grading / Evaluation: Your evaluation will be continuous, throughout the semester. It will consist of the following parts: (1) Classwork, (2) Homework, (3) Mid-semester Exam, and (4) Final Exam. These are explained below: Classwork (120 points, 30% of total grade): You will ACTIVELY participate in the class. Note that classwork carries the maximum points in the grading system. Your DAILY classwork will consist of the following parts: a. There will be short quizzes (5 min) throughout the course on: 1) on material from previous classes, 2) and on the concepts being taught in each class. b. Answering questions in written form (including multicolor diagrams) and solving problems, during class At the end of each class, you will submit all the work in (a) and (b) which will be graded.
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Homework (120 points, 30% of total grade): Homework will consist of problems assigned from your textbooks. Submission of homework must be before the set deadline. No excuses will be entertained. Mid-semester Exam (80 points: 20% of total grade): The mid-semester exam will take place sometime around mid semester (obviously), and will consist of problems similar to the problems assigned during the classes, and conceptual or descriptive questions. Final Exam: (80 points: 20% of total grade) The final exam will be cumulative over the entire semester’s material and will be similar in content to the class test. Grading system: As explained above, grades are assigned according to the following scale: 120 points for the homework (problems, preparatory notes and Concept Maps), 120 for the classwork, 80 for the class test, and 80 for the final. Total points for the semester: 400. 90 -100% A ;
85 - 89% A- ;
80 - 84% B+ ;
75 - 79% B
70 - 74% B- ;
60 - 69% C ;
50 - 59% D;
< 50% F
ASSISTANCE: Students with special needs who require specific examination-related or other course-related accommodations should contact Barbara Fitzpatrick, Director of Disabled Student Services (DSS),
[email protected], (850) 474-2387. DSS will provide the student with a letter for the instructor that will specify any recommended accommodations.
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A142 PHY 3220 INTERMEDIATE MECHANICS
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A143
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A144
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A145 PHY 3424 OPTICS
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A146
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A147 PHY 4250 FLUID MECHANICS
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A150 PHY 4323 ELECTRICITY AND MAGNETISM I
COURSE SYLLABUS Course Prefix/Number: PHY4323 Course Title: Electricity & Magnetism I Course Credit Hours: 3 Hours Required text: Introduction to Electrodynamics, David J Griffiths, Prentice Hall Prerequisites or Co-Requisites: PHZ4113 WITHDRAWALS: UWF policy requires that students submit to the Office of Records and Registration a completed withdrawal form to withdraw from courses, which is a different policy from that used by some other institutions, notably PJC. Withdrawals from this course that are processed by Friday, March 20, 2009 will result in a "W" grade being recorded. Withdrawals after this date can be done only by withdrawing from the University; the grade assigned will be W or WF. No withdrawals can be made after the close of classes. Course Description: Electricity & Magnetism I is the first of a two-semester sequence of courses on Classical Electricity & Magnetism. The principal topics covered in this course are electrostatics, magnetostatics, electromagnetic induction, Maxwell equations and electromagnetic waves. Student Learning Outcomes: Upon successful completion of the course, the student must be able to analyze electrical forces between charges, calculate electric fields and potentials for various charge configurations, solve problems of electrical energy, analyze magnetic fields for various current distributions, calculate currents and potentials in electrical circuits, apply the concept of electromagnetic induction to generators and timedependent fields, apply Maxwell equations to problems involving electromagnetic waves. Topics Covered: Topic Electric charges and 1 Forces
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A151
2 3 4 5 6 7 8 9 10 11 13 14
Electric field Electric field, cont’d. Current Potential Calculating Potentials Electric fields in matter Magnetostatics Mid-semester Exam Magnetic fields in matter Electrodynamics, induction Maxwell equations EM Fields & Waves Final Exam
1, 2 3 4 4, 5 5, 6 7 8, 9 10 12, 13 13, 14 14, 15
Grading / Evaluation: Your evaluation will be continuous, throughout the semester. It will consist of the following parts: (1) Classwork, (2) Homework, (3) Mid-semester Exam, and (4) Final Exam. These are explained below: Classwork (120 points, 30% of total grade): You will ACTIVELY participate in the class. Note that classwork carries the maximum points in the grading system. Your DAILY classwork will consist of the following parts: c. There will be short quizzes (5 min) throughout the course on: 1) on material from previous classes, 2) and on the concepts being taught in each class. d. Answering questions in written form (including multicolor diagrams) and solving problems, during class At the end of each class, you will submit all the work in (a) and (b) which will be graded. Homework (120 points, 30% of total grade): Homework will consist of problems assigned regularly.
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Submission of homework must be before the set deadline. No excuses will be entertained. Mid-semester Exam (80 points: 20% of total grade): The mid-semester exam will take place sometime around mid semester (obviously), and will consist of problems similar to the problems assigned during the classes, and conceptual or descriptive questions. Final Exam: (80 points: 20% of total grade) The final exam will be cumulative over the entire semester’s material and will be similar in content to the class test. EXTRA NOTE: YOU CANNOT MISS ANY OF THE CLASSWORK OR HOMEWORK FOR ANY REASON, AND YOU CANNOT “MAKE UP” FOR ANY OF IT. THEY HAVE TO BE DONE ACCORDING TO SCHEDULE. YOU MAY MISS AND MAKE UP FOR THE MIDSEMESTER EXAM ONLY FOR PERSONAL MEDICAL (DOCUMENTED) REASONS. Grading system: As explained above, grades are assigned according to the following scale: 120 points for the homework, 120 for the classwork, 80 for the class test, and 80 for the final. Total points for the semester: 400. 90 -100% A ;
85 - 89% A- ;
80 - 84% B+ ;
75 - 79% B
70 - 74% B- ;
60 - 69% C ;
50 - 59% D;
< 50% F
ASSISTANCE: Students with special needs who require specific examination-related or other course-related accommodations should contact Barbara Fitzpatrick, Director of Disabled Student Services (DSS),
[email protected], (850) 474-2387. DSS will provide the student with a letter for the instructor that will specify any recommended accommodations.
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A153
Instructions for Mastering Physics software NOTE: YOUR COURSE ID FOR UNIVERSITY PHYSICS II IS:
YOU WILL NEED THIS WHEN YOU ENROLL FOR THE “MASTERING PHYSICS” SOFTWARE How do students get a Student Access Code for Mastering? Students receive a Student Access Kit with their purchase of a new textbook. The kit contains instructions and a unique access code for registering for use of the site. If you used Mastering Physics in UPI, your UPI access code should work here, and you should be able to login as you did last semester. Students without a Student Access Kit can purchase access online from Pearson Education by clicking Buy Now from the site's login page: MasteringPhysics www.masteringphysics.com During registration, students create a login name and password for accessing the site. How do students enroll in a Mastering course? Prerequisites for the educator: You will need to have opened your Mastering course for student enrollment and given your students its Course ID. – This has been done Students establish a user account, including their login name and password, for logging into the site. They do this by starting from the site's login page. • •
Students WITH an access code click Register and follow the on-screen instructions. Students WITHOUT an access code click Buy Now and follow the on-screen instructions.
When students log in to the site for the first time, they are asked to provide a Course ID. Once a student enters the Course ID and clicks Save, that student is enrolled in your course. The student's name will appear in your online gradebook. Notes: •
For sites that offer self-study resources: Students can access study area resources before enrolling in your course. Instead of providing a Course ID upon their first login, they click Proceed to Study Area. These students can enroll in your online course later by clicking Join Course.
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A154 PHY 4325 ELECTRICITY AND MAGNETISM II
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A158 PHY 4445 LASERS AND APPLICATIONS
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A160
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A161 PHY 4513 THERMODYNAMICS AND KINETIC THEORY
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A163 PHY 4604 QUANTUM THEORY
COURSE SYLLABUS Course Prefix/Number: PHY4604 Course Title: Quantum Theory Required text: Introduction to Quantum Mechanics by D. J. Griffiths, Prentice Hall Prerequisites or Co-Requisites: PHY4323 Electricity & Magnetism I, and PHZ4113 Mathematical Physics I WITHDRAWALS: UWF policy requires that students submit to the Office of Records and Registration a completed withdrawal form to withdraw from courses, which is a different policy from that used by some other institutions, notably PJC. Withdrawals from this course that are processed by Friday, October 31, 2008 will result in a "W" grade being recorded. Withdrawals after this date can be done only by withdrawing from the University; the grade assigned will be W or WF. No withdrawals can be made after the close of classes Course Description: Postulates of quantum theory, Schrödinger equation, particle in a box, harmonic oscillator; hydrogen atom, and perturbation theory Student Learning Outcomes: Upon successful completion of the course, the student must be able to analyze and solve problems involving: simple potentials in one, two, and three dimensions, angular momentum, identical particles, time independent and time dependent perturbation theory, variational methods, the WKB approximation, the adiabatic approximation, and scattering. Topics Covered:
1 2 3 4 5 6 7
8 9 10 11 12 13
Topic The Schrödinger equation Formalism 3-dimensional problems Angular Momentum Angular Momentum Identical Particles Identical Particles Class Test Time-independent Perturbations Variational Principle WKB approximation Time dependent perturbation Time dependent perturbation Adiabatic approximation
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A164 14 Scattering 15 Scattering Final Exam
14 15
Grading / Evaluation: There will be one (1) class test and a final exam. Both will be closed book, no cheat-sheets. Classwork: You will ACTIVELY participate in the class. Note that classwork carries the maximum points in the grading system. Your DAILY classwork will consist of the following parts: a. Quiz at the beginning of class (5 minutes) on material from previous classes b. Answering questions in written form and solving problems, during class At the end of each class, you will submit all the work in (a) and (b), which will be graded. Homework: Problems and questions will be assigned as homework. Only a few of these will be worked out in class. It is important that you work out homework problems before looking at solutions. The tests will be very similar to these. You can submit as many problems as you are able to do in the time given to you. Submission of homework must be before the set deadline. No excuses will be entertained. If you cannot submit your homework on time, don’t submit it. Homework must be done neatly and the sheets must be stapled together. Homework on white sheets please. No torn sheets from notebooks. Grading system: Grades are assigned according to the following scale; 100 points for the class test, 50 for the homework, 150 for the classwork, and 100 for the final. Total points for the semester, 400. 90 -100% A ; 85 - 89% A- ; 80 - 84% B+ ; 75 - 79% B 70 - 74% B- ; 60 - 69% C ; 50 - 59% D;
< 50% F
ASSISTANCE: Students with special needs who require specific examination-related or other course-related accommodations should contact Barbara Fitzpatrick, Director of Disabled Student Services (DSS),
[email protected], (850) 474-2387. DSS will provide the student with a letter for the instructor that will specify any recommended accommodations.
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A165
PHY 4910 INDEPENDENT RESEARCH
COURSE SYLLABUS Course Prefix/Number: PHY4095 Course Title: Independent Research Course Credit Hours: 3 Hours Required text: None Requires Readings: Assigned from reference texts and journal publications Prerequisites: PHY3106 WITHDRAWALS: UWF policy requires that students submit to the Office of Records and Registration a completed withdrawal form to withdraw from courses, which is a different policy from that used by some other institutions, notably PJC. Withdrawals from this course that are processed by Friday, March 20, 2009 will result in a "W" grade being recorded. Withdrawals after this date can be done only by withdrawing from the University; the grade assigned will be W or WF. No withdrawals can be made after the close of classes. Course Description: This is a research course designed to acquaint the student with a modern research topic, research methods, experimental and/or theoretical methods of research, literature survey, laboratory safety and report generation. The specific techniques to be learnt will depend on the specific research topic chosen by the student in consultation with the supervisor. Student Learning Outcomes: Upon successful completion of the course, the student must be able to conduct a literature survey in a field of research, formulate a research problem, design an experiment, set up the experiment, conduct the experiment following rules of safety and methods of research, gather data, analyze data using graphical and numerical methods, arrive at valid conclusions based on the research, prepare a research report including a complete analysis of the errors, and present the results in a seminar or a discussion group meeting.
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Topics Covered: Will depend upon the specific research topic chosen. Grading / Evaluation: Your evaluation will be continuous, throughout the semester. It will consist of the following parts: (1) Literature survey – 10 points (2) Formulation of problem – 10 points (3) Design of experiment – 10 points (4) Experimental procedures followed – 10 points (5) Data analysis – 10 points (6) Report – 25 points (7) Seminar – 25 points. Total 100 points Grading system: Grades are assigned according to the following scale: 90 -100% A ;
85 - 89% A- ;
80 - 84% B+ ;
75 - 79% B
70 - 74% B- ;
60 - 69% C ;
50 - 59% D;
< 50% F
ASSISTANCE: Students with special needs who require specific examination-related or other course-related accommodations should contact Barbara Fitzpatrick, Director of Disabled Student Services (DSS),
[email protected], (850) 474-2387. DSS will provide the student with a letter for the instructor that will specify any recommended accommodations.
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PHZ 3106 INTERMEDIATELEVEL PHYSICS PROBLEMS
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A169
COURSE POLICY STATEMENT - DEPARTMENT OF PHYSICS COURSE: PHZ 4113-1577: Mathematical Physics I TERM: Fall 2008
PHZ 4113 MATHEMATICAL PHYSICS I
PREREQUISITE: MAC 2313 or equivalent course REQUIRED TEXT: Mathematical Methods in the Physical Sciences, 3rd Ed. by Mary L. Boas, John Wiley & Sons, Inc. (2006) OPTIONAL TEXT: Mathematical Methods for Physicists, 4th Ed. by G. F. Arfken & H. J. Weber
WITHDRAWALS: UWF policy requires that students submit to the Office of Records and Registration a completed withdrawal form to withdraw from courses, which is a different policy from that used by some other institutions. Withdrawals from this course that are processed by October 31th, 2008 will result in a "W" grade being recorded. Withdrawals after this date can be done only by withdrawing from the University; the grade assigned will be W or WF. No withdrawals can be made after the close of classes. HOMEWORK: There will be homework assignments given out every week. They will be due at the posted dates of the class. You will have the opportunity to present the solutions of the problems and we will discuss them. COURSE GRADE SCALE: 90 -100% A ; 85 - 89% A- ; 80 - 84% B+ ; 75 - 79%; B70 - 74% B- ; 60 - 69% C ; 50 - 59% D; < 50% F STUDENT LEARNING OUTCOMES: On completion of the course, students will be able to apply advanced mathematical methods and solve mathematical problems in their applications to physics and engineering. The student will be able to apply mathematical concepts in Infinite Series, Complex Variables, Linear Vector Spaces, Partial Differentiation, Vector Analysis, Fourier Series and Transformations.
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A170 Positive class activity during the problem solving classes may raise your grade by 5-10 %. COURSE SCHEDULE
Week
DATE
TOPIC
TEXT REFERENCE
HOMEWORK
1.
8/25 8/27 8/29
Infinite Series, Power Series: overview of basic concepts, convergence and divergence Problem Solving
Chapter 1, 1.1 - 1.10
2.
9/1 9/3 9/5
Chapter 1, 1.10-1.16
3.
9/8 9/10 9/12
Labor Day Infinite Series, Power Series: theorems about series and power series, techniques for obtaining power series expansions Techniques for obtaining power series expansions Problem Solving Complex Numbers Complex Numbers
A/ Pg.3: 4,6,12; Pg.5: 1,6,9, Pg.8: 2,3,6, Pg.9: 3; Pg.11; 5; Pg.13: 10 Pg.15: 25; Pg.16: 33; Pg.17: 4; Pg.19: 5,10 Homework A is due. B/ Pg. 22: 7,8,9; Pg. 29: 1,4 Pg. 32: 8,16, 20, 39 40 Pg. 44: 1
Chapter 2
Homework B is due. C/ Pg.
4.
9/15 9/17 9/19
Problem Solving Complex Functions and Some Applications of the theory Complex
Chapter 2
Homework C is due D/ Pg.
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A171
Applications of the theory 5.
9/22 9/24 9/26
Problem Solving Problem Solving Midterm Exam I.
Chapter 2
9/29 10/1 10/3
Linear Algebra Linear Algebra Problem Solving
Chapter 3
7.
10/ 6 10/8 10/10
Chapter 3
F/pg... Homework F is due.
8.
10/13 10/15 10/17
Linear Algebra: Eigenvalues and Eigenvectors Linear Algebra: Introduction to Groups, General Vector Spaces Problem Solving Partial Differentiation Partial Differentiation Problem Solving
Chapter 4
G/pg.....
10/20 10/22 10/24
Partial Differentiation Partial Differentiation Problem Solving
Chapter 4
10.
10/27 10/29 10/31
Midterm Exam II. Vector Analysis Vector Analysis
Chapters 3,4 Chapter 6
J/pg.....
11.
11/03 11/05 11/7
Problem Solving Vector Analysis Veteran's Day
Chapter 6
Homework J is due. K/pg.....
12.
11/10
Vector Analysis
Chapter 6
Homework K is due.
6.
9.
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Chapters 1,2
Homework D is due Homework D is due E/ pg..... Homework E is due.
Homework G is due. H/pg..... Homework H is due.
A172
11/12 11/14
Problem Solving Midterm Exam III.
13.
11/17 11/19 11/21
Fourier Series and Transforms Fourier Series and Transforms Problem Solving
14.
11/24 11/26 11/28
15.
12/1 12/3 12/5
Fourier Series and Transforms Fourier Series and Transforms NO CLASSThanksgiving Problem Solving Overview and Problem Solving Overview and Problem Solving
16.
12/8-12/12
FINAL EXAM
Chapter 7
L/pg....
Chapter 7
Homework L is due. M/pg.......
Chapter 7 Chapters 1,2,3,4,6,7
Homework M is due.
Chapters 1,2,3,4,6,7
ASSISTANCE: Students with special needs who require specific examination-related or other course-related accommodations should contact Barbara Fitzpatrick, Director of Disabled Student Services (DSS),
[email protected], (850) 474-2387. DSS will provide the student with a letter for the instructor that will specify any recommended accommodations. Please, read about MISCONDUCT policy of UWF at http://uwf.edu/judicialaffairs/documents/BOTApprovedAcademicMisconductPolicy-2007edition.pdf http://uwf.edu/judicialaffairs/documents/BOTApprovedStudentCodeofConduct-2007edition.pdf
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PHZ 4114 MATHEMATICAL PHYSICS II
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AST 3033 MODERN ASTRONOMY
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A178 PHZ 3601 SPECIAL RELATIVITY
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