perpendicular to the earth's magnetic field vector B. (The diffuse resonance. 5 ... The first case (Figures l(a)-l(c)) corresponds to the ad- dition of energetic ...
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' :'....T1 = 3,000°K in the top row, and T versus Tl with T, < T2 = 3,000 °K in the bottom row. The left column corresponds to the condition when 10% of the electrons deviate from the model temperature of 3,000°K, the center column corresponds to a 20% perturbation, and the right column to a 30% perturbation. Note the abscissa scale change between the top and bottom rows. In each column, the bottom figure represents an enlarged extension of the top figureto the temperature range below 3,000°K.
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respond to the plasma conditions given in the caption of Figure Al. Figure Al. Dispersion curves based on the two-temperature dispersion equation (A3) for plasma models with T 2 >T 1 = 3,000 0 K (a), (b), and (c); and for models with T1 < T2 = 3, 000°K (d), (e), and (f). The parameter p represents the fraction of electrons at T 2 .
The solid curves
(p=0 and 1) correspond to the single temperature dispersion curve. The plasma conditions used in these models correspond to a typical observation from the Ottawa data sample of Oya and Benson (1972) (fN=caN/2r=3.475 MHz and fH=l. 178 MHz so that fN/fH=2. 95; the corresponding value for kR when the temperature is taken as 3, 000°K is 0.97).
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