Particle Creation in Anisotropically Expanding Universe

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Aug 25, 2003 - arXiv:gr-qc/0308080v1 25 Aug 2003. PARTICLE CREATION IN ANISOTROPICALLY EXPANDING UNIVERSE. P.K.SURESH 1. School of ...
PARTICLE CREATION IN ANISOTROPICALLY EXPANDING UNIVERSE P.K.SURESH

1

School of Physics, University of Hyderabad. Hyderabad 500 046. India.

arXiv:gr-qc/0308080v1 25 Aug 2003

Abstract Using squeezed vacuum states formalism of quantum optics, an approximate solution to the semiclassical Einstein equation is obtained in Bianchi type-I universe. The phenomena of nonclassical particle creation is also examined in the anisotropic background cosmology. Keywords: Bianchi type-I, cosmology, Einstein equation, particle creation, squeezed vacuum. PACS numbers: 42.50.-p, 42.50.Dv, 98.80.k, 98.80.Cq, 98.80.Qc

1. Introduction The present universe in its over all structures seems to be spatially homogeneous and isotropic but there are reasons to believe that it has not been so in all its evolution and that inhomogeneities and anisotropies might have played an important role in the early universe 1,2 . The isotropic model is adequate enough for the description of the later stages of evolution of the universe but this does not mean that the model equally suite for the description of very early stages of the evolution of the universe, especially near the singularity 2 . Also the most general solution of the problem of gravitational collapse turn to be locally anisotropic near the singularity 3−5 . Cosmological solutions of Einstein’s general relativity are also known in which the expansion can be anisotropic at first, near the singularity, and later the expansion became isotropic. Also, to avoid postulating specific initial conditions as well as the existence of particle horizon in isotropic models, attempts have been made through the study of inhomogeneous and anisotropic models of the universe. Among the anisotropic cosmological models, Bianchi type -I universe is the simplest one. In this model the metric considered as spatially homogeneous and possibly anisotropic. In contrast to the Friedmann-Robertson-Walker (FRW) metric, Bianchi type-I metric has three scale factors which evolve differently in their respective direction. Therefor the expansion in this model could be considered as anisotropic expansion. Interests in such models have been received much attention 1,3−7 . Huang has considered the fate of symmetry in Bianchi type - I cosmology using adiabatic approximation for massless field with arbitrary coupling to gravity 8 . Futamase has studied the effective potential in Bianchi type - I cosmology 9 . Berkin has examined the effective potential in Bianchi type -I universe, for scalar field having arbitrary mass and coupling to gravity 10 . These studies show that Bianchi type -I cosmological model may be useful to understand the very early universe. Anisotropic models of the universe which become isotropic have been considered several times 11 . These motivate the study of anisotropic background cosmological models with scalar field possess the advantage of 1

email:[email protected]

1

FRW model, and to analysis the possibility of its approach to the isotropic model with accuracy required by observations 12 . With this aim Bianchi type -I universe has studied and the relevant equation for which extreme close in the form of isotropic case examined. Form anisotropic to isotropic transition a damping mechanism is required. One of the efficient damping mechanisms could be due to the particle creation in anisotropic models. Therefore it would be useful to examine the particle creation in the anisotropic cosmological model with nonclassical inflaton, which could expect to produce sufficient particles to bring isotropy during the evolution process of the universe. In this paper we study a homogeneous massive scalar field (inflaton), minimally coupled to gravity, in a spatially homogeneous and anisotropic background metric. The inflaton under our consideration can be quantized and represent in squeezed vacuum states, hence an approximate solution to the semiclassical Einstein equation and the phenomenon of nonclassical particle creation can be examined in semiclassical theory of gravity. Throughout the paper, we follow the units c = G = h ¯ = 1. 2. Inflaton in Bianchi type -I metric The Bianchi type- I model is an anisotropic generalization of the FRW model with Euclidean spatial geometry. The Bianchi type -I metric can be considered as spatially homogeneous and anisotropic and is given by: ds2 = dt2 − S12 (t)dx1 2 − S22 (t)dx2 2 − S32 (t)dx3 2 ,

(1)

where S1 (t), S2 (t) and S3 (t) are the scale factors in three spatial directions. Which are representing the size of the universe in their respective direction. The three scale factors S1 (t), S2 (t) and S3 (t) are determined via Einstein’s equations. In the background metric (1), consider an inflaton, minimally coupled to gravity, satisfy the equation: 



g µν ∇µ ∇ν − m2 φ(x, t) = 0,

(2)

where ∇µ is the covariant derivative. The Lagrangian density for the inflaton field, φ, is given by:  1 √  αβ L=− (3) −g g ∂α φ∂β φ + m2 φ2 . 2 Since the inflaton is homogeneous,ie.; φ(x, t) = φ(t), its classical equation of motion for the metric (1) can be written as ¨ + φ(t)

3 X i=1

S˙i (t) ˙ φ(t) + m2 φ(t) = 0. Si (t) !

(4)

In the present context (4) is the classical equation of motion for the inflaton for the metric (1).

2

For the metric (1), the purely temporal component of the classical gravity is now the classical Einstein equation and can be written as:

where

8πT00 S˙1 (t) S˙2 (t) S˙2 (t) S˙3 (t) S˙1 (t) S˙3 (t) + + = , S1 (t) S2 (t) S2 (t) S3 (t) S1 (t) S3 (t) S1 (t)S2 (t)S3 (t) T00

φ˙ 2 φ2 (t) = S1 (t)S2 (t)S3 (t) , + m2 2 2 !

(5)

(6)

is the energy density of the inflaton. Incosmological  context, the classical Einstein equation S˙i (t) (5), means that the Hubble constants Hi = Si (t) are determined by the energy density of the dynamically evolving inflaton described by the classical equation of motion. In order to study the full quantum effects in a cosmological model, both metric and matter fields are to be treated quantum mechanically. Since a consistent quantum theory of gravity is not available, in most of the cosmological models the background metric under consideration is taken as classical form and matter field treat as quantum mechanical. Such approximation of the Einstein equation is know as semiclassical approximation. In semiclassical theory Einstein equation takes the following form Gµν = 8πhTˆµν i,

(7)

where Gµν = Rµν − 12 gµν R is the Einstein tensor and hTˆµν i is the expectation value of the energy-momentum tensor for a matter field in a suitable quantum state under consideration. In (7) the quantum field can be represented by a scalar field, φ, and is governed by the time dependent Schrodinger equation i

∂ ˆ m (φ, t)Ψ(φ, t). Ψ(φ, t) = H ∂t

(8)

Using the canonical quantization procedure, the scalar field can be quantized by defining the momentum conjugate to φ, as πφ =

∂L . ∂ φ˙

(9)

Thus the inflaton in the Bianchi type -I cosmological model, can be described by a time dependent harmonic oscillator with the Hamiltonian Hm =

1 m2 S1 (t)S2 (t)S3 (t) 2 πφ2 + φ (t). 2S1 (t)S2 (t)S3 (t) 2

(10)

The eigenstates of the Hamiltonian are the Fock states which can be constructed by annihilation and creation operators in the following manner. ˆ aˆ(t) = φ∗ (t)ˆ πφ − S1 (t)S2 (t)S3 (t)φ˙ ∗ (t)φ, ˙ φ. ˆ aˆ† (t) = φ(t)ˆ πφ − S1 (t)S2 (t)S3 (t)φ(t) 3

(11)

Thus the Fock state of Hamiltonian is : aˆ† a ˆ | n, φ, ti = n | n, φ, ti.

(12)

In the present context the semiclassical Einstein equation takes following form: 8π S˙1 (t) S˙2 (t) S˙2 (t) S˙3 (t) S˙1 (t) S˙3 (t) ˆ + + = hHi, S1 (t) S2 (t) S2 (t) S3 (t) S1 (t) S3 (t) S1 (t)S2 (t)S3 (t)

(13)

where H is given by (10). 3. Particle Creation in the anisotropic universe Most of the cosmological models are based on a classical behaviour of the scalar field. Therefore, it is of interest to study the evolution of the system with the scalar field, which possess the nonclassical features. Recently squeezed states formalism of quantum optics13 is found much useful to deal with many issues in cosmology13−23 . Squeezed states are minimum uncertainty states and are obeying Heisenberg uncertainty principle. A squeezed state is generated by the action of squeezed operator on any coherent state and, in particular, on the vacuum state. Therefore a squeezed vacuum can be defined 13 | Zi = Z(r, ϕ) | 0i,

(14)

where the squeezing operator,  r  −iϕ 2 2 Z(r, ϕ) = exp . e a − eiϕ a† 2 



(15)

In (15) r is the squeezing parameter which determines the strength of squeezing and ϕ is the squeezing angle which determines the distribution between the conjugate variables and they take values 0≤ r < ∞ and −π ≤ ϕ ≤ π. a and a† are respectively known as annihilation and creation operators. When the squeezing operator acts on annihilation and creation operators lead the following results13 : Z † aZ = a cosh r − a† eiϕ sinh r, Z † a† Z = a† cosh r − ae−iϕ sinh r.

(16)

In the case of squeezed states, the variance of the quadrate components are not equal but one component of the noise is always squeezed with respect to another. Next, consider the Hamiltonian of the semiclassical Einstein equation (13), whose expectation value can be computed in squeezed vacuum state by replacing the number state | n, φ, ti with | Zi. Therefor using (14), (15) and (16) in (13), we obtain the semiclassical Einstein equation as:    S˙1 (t) S˙2 (t) S˙2 (t) S˙3 (t) S˙1 (t) S˙3 (t) 1  ˙∗ ˙ 2 + + = 8π sinh r + φ φ + m2 φ∗ φ + (17) S1 (t) S2 (t) S2 (t) S3 (t) S1 (t) S3 (t) 2  oi n Re cosh r sinh re−iϕ φ˙ 2 + m2 φ2

4

In the above equations, φ and φ∗ satisfy the boundary condition ˙ S1 (t)S2 (t)S3 (t) φ˙ ∗ (t)φ(t) − φ∗ (t)φ(t) = i. 



(18)

To solve the semiclassical equations (17), transform the solution in the following form φ(t) = [S1 (t)S2 (t)S3 (t)]−1/2 χ(t)

(19)

Therefor (4) becomes 

3 S˙i 1X χ(t) ¨ + m2 + 4 i=1 Si

!2



3 3 ¨ 1X 1 X Si (t)  S˙i (t) S˙j (t) − χ(t) = 0. − 2 i6=j=1 Si (t) Sj (t) 2 i=1 Si (t)

!

(20)

The inflaton has a solution of the form   Z 1 χ(t) = q exp −i γ(t)dt , 2γ(t)

(21)

where,

3 S˙i (t) 1X γ (t) = m + 4 i=1 Si (t) 2

2

!2

3 3 1 X 1X 3 S˙i (t) S˙j (t) S¨i (t) − − + 2 i6=j=1 Si (t) Sj (t) 2 i=1 Si (t) 4

!

!

γ(t) ˙ γ(t)

!2



3 γ¨ (t) ,(22) 2 γ(t)

with the following condition: 3 1X S˙i m > 4 i=1 Si 2

!2

3 3 ¨ 1X S˙i (t) S˙j (t) Si (t) 1 X − . − 2 i6=j=1 Si (t) Sj (t) 2 i=1 Si (t)

!

(23)

The semiclassical equation (17) can be rewritten as follows: S1 (t)S2 (t)S3 (t) =

8π 2γ



S˙1 (t) S˙2 (t) S1 (t) S2 (t)

+

3 3X S˙i (t) + 4 i=1 Si (t)



S˙2 (t) S˙3 (t) S2 (t) S3 (t)

!

γ˙ 1 + γ 4

+ γ˙ γ

S˙1 (t) S˙3 (t) S1 (t) S3 (t)

!2

    sinh2 r 

!

γ˙ 1 + γ 4

γ˙ γ

!2



+ m2 − γ 2  .

(24)

The above equation can be solved peturbatively. Starting from the approximation ansatz S10 (t) = S10 tn1 , S20 (t) = S20 tn2 , S30 (t) = S30 tn3 , and γ0 (t) = m , we obtain the next order perturbative solution for S1 ,  3 1 i=j=1 ni nj sinh r + 1+ 2 8m2 t2 !# P3 i=j=1 ni nj − 1 t2−n2 −n3 . + cosh r sinh r cos(ϕ + 2mt) 8m2 t2

8πm S11 (t) = S20 S30 (n1 n2 + n2 n3 + n1 n3 )

5

!

+ m2 + γ 2  + (cosh r sinh r cos(ϕ + 2γt))

3 3 3X S˙i (t) S˙j (t) S˙i (t) 1 X + × 4 i,j=1 Si (t) Sj (t) 4 i=1 Si (t)

!



3 S˙i (t) S˙j (t) 1 1 X + 2 4 i,j=1 Si (t) Sj (t)



"

2

P

!

(25)

Similarly, the next order perturbation solution for S2 and S3 are obtained as  3 1 i=j=1 ni nj sinh r + 1+ 2 8m2 t2 !# P3 i=j=1 ni nj + cosh r sinh r cos(ϕ + 2mt) − 1 t2−n1 −n3 , 8m2 t2

!

 3 ni nj 1 sinh r + 1 + i=j=12 2 2 8m t !# P3 i=j=1 ni nj − 1 t2−n1 −n2 . + cosh r sinh r cos(ϕ + 2mt) 8m2 t2

!

8πm S22 (t) = S10 S30 (n1 n2 + n2 n3 + n1 n3 )

"

P

2

(26)

and

8πm S33 (t) = S10 S20 (n1 n2 + n2 n3 + n1 n3 )

"

P

2

(27)

Where S11 means the next order perturbation solution for the scale factor in the x direction and the same hold for S21 and S31 ; respectively in the y and z directions. From (25),(26) and (27) it follow that S11 ∼ t2−n2 −n3 ,

S22 ∼ t2−n1 −n3 ,

S33 ∼ t2−n1 −n2 .

(28)

Next goal is to examine the particle creation the anisotropically evolving universe described through the Bianchi type I metric. For this, consider the Fock space which has a one parameter dependence on the cosmological time t. Then the number of particles at a later time t created from the vacuum at the initial time t0 is given by ˆ N0 (t, t0 ) = h0, φ, t0|N(t)|0, φ, t0 i,

(29)

ˆ where N(t) = a† a. Thus using (11), the vacuum expectation value of the right hand side of (29) becomes ˆ − S1 S2 S3 φφ ˙ ∗ hφˆ ˆπ i. ˆ hN(t)i = (S1 S2 S3 )2 φ˙ φ˙ ∗ hφˆ2 i + φφ∗ hˆ π 2 i − S1 S2 S3 φφ˙ ∗ hˆ πφi

(30)

Therefore 2 ˙ 0 ) − φ(t)φ(t ˙ N0 (t, t0 ) = (S1 S2 S3 )2 |φ(t)φ(t 0 )| .

(31)

The number of particle created in the vacuum states can be obtained by using the peturbative solution in the limit mt0 , mt > 1, in (30), therefore, 

3 1 S˙i S˙j S˙i0 S˙j0 S1 S2 S3  1 X N0 (t, t0 ) = + 4γ(t)γ(t0 ) S10 S20 S30 4 i=j=1 Si Sj Si0 Sj0

6

!

3 1 X S˙i S˙j0 − 2 i=j=1 S˙i S˙j0

3 S˙i 1X + 2 i=1 Si

"

1 + 2 ≃



3 1X γ(t) ˙ γ(t ˙ 0) S˙i0 + + γ(t) γ(t0 ) 2 i=1 Si0

!

γ(t) ˙ γ(t ˙ 0) − γ(t) γ(t0 )

n1 + n2 + n3 4m

2 

!#2

γ(t) ˙ γ(t ˙ 0) − γ(t) γ(t0 )

!



+ γ(t)2 − γ(t0 )2 

t − t0 tt0

2 

t t0

n1 +n2 +n3

(32)

.

By similar procedure, one can compute the particle creation for the quantized inflaton in squeezed vacuum states also. For this, consider the quantized inflaton in the squeezed vacuum state formalism. Then the expectation values of π 2 , φ2 , πφ and φπ can be computed in squeezed vacuum state by using (11),(14) and (16), and are respectively obtained as

hˆ π 2 isqv = (S1 S2 S3 )2 hφˆ2 isqv =



h

˙ 0 ) + sinh r cosh r e−iϕ φ˙ ∗2 (t0 ) + eiϕ φ˙ 2 (t0 ) 2 sinh2 r + 1 φ˙ ∗ (t0 )φ(t 







2 sinh2 r + 1 φ∗ (t0 )φ(t0 ) + sinh r cosh r e−iϕ φ∗2 (t0 ) + eiϕ φ2 (t0 )

ˆ sqv = S1 S2 S3 sinh2 r φ˙ ∗ (t0 )φ(t0 ) + cosh2 r φ(t ˙ 0 )φ∗ (t0 )+ hˆ π φi h

˙ 0 )φ(t0 ) sinh r cosh r e−iϕ φ˙ ∗ (t0 )φ(t0 ) + eiϕ φ(t 



i

i

(33)

ˆπ isqv = S1 S2 S3 sinh2 rφ∗ (t0 )φ(t ˙ 0 ) + cosh2 rφ(t0 )φ˙ ∗ (t0 )+ hφˆ h

˙ 0) sinh r cosh r e−iϕ φ(t0 )φ˙ ∗ (t0 ) + eiϕ φ(t0 )φ(t 

i

.

Applying the above results (33) in (30), the number of particle created in squeezed vacuum in the limit mt0 , mt > 1, is obtained as





3 ˙  1 X 1 ˙ 0) S1 S2 S3  Si (t0 ) γ(t Nsqv (t, t0 ) = 2 sinh2 r + 1  + 4γ(t)γ(t0 ) S10 S20 S30 4 i=1 Si (t0 ) γ(t0 ) 3 ˙ ˙ Si (t) γ(t) 1 X + + 4 i=1 Si (t) γ(t)



!2 

 + sinh r cosh r

3 ˙ Si (t0 ) γ(t ˙ 0) 1 X × + 4 i=1 Si (t0 ) γ(t0 )

!2



e−i(ϕ−2

R

3 ˙ Si (t) γ(t) ˙ 1 X + + 4 i=1 Si (t) γ(t)

γ(t0 )dt0 )

!2

!2

+ γ 2 (t0 ) + γ 2 (t)

− ei(ϕ−2

R

γ(t0 )dt0 )





+ γ 2 (t) − γ 2 (t0 )

3 ˙ 3 ˙ X Si (t) γ(t) Si0 (t) γ(t ˙ ˙ 0) 1 X − 2γ(t)γ(t0 ) (34) + + − sinh2 r 2 i=1 Si (t) γ(t) γ(t0 ) i=1 Si0 (t) ! 3 ! ! 3 ˙ ˙ i0 (t) γ(t X X 1 γ(t) ˙ ˙ ) S (t) S 0 i − cosh2 r + 2γ(t)γ(t0 ) + + 2 i=1 Si (t) γ(t) γ(t0 ) i=1 Si0 (t) ! 3 !# 3 ˙ R  1X  X S˙ i0 (t) γ(t) ˙ γ(t ˙ ) S (t) 0 i − sinh r cosh r e−iϕ + ei(ϕ−2 γ(t0 )dt0 ) . + + 2 i=1 Si (t) γ(t) γ(t0 ) i=1 Si0 (t)

!

7

!

!

Again using the peturbative solution , we get (n1 + n2 + n3 )2 Nsqv (t, t0 ) ≃ 4m2

 t−t t n1 +n2 +n3  0 2 sinh2 r + 1 t0 2t0 t # sinh r cosh r cos ϕ 2 2 +4m sinh r − . 2tt0 "







2

(35)

Therefor the total number of particle created for the whole range of squeezing parameter and squeezing angle can be written as Nsqv−tot = N0 (t, t0 ) +

Z

rmax

0

Nsqv−r dr +

Z

ϕmax

(36)

Nsqv−ϕ dϕ,

0

where Nsqv−r

(n1 + n2 + n3 )2 = 4 sinh r cosh r 4m2 "







t − t0 2t0 t

2

2

+ 2m

!

sinh2 r + cosh2 r cos ϕ  t n1 +n2 +n3  , − 2tt0 t0 

(37)

and Nsqv−ϕ

(n1 + n2 + n3 )2 sinh r cosh r cos ϕ = − 4m2 2tt0 "

#

t t0

n1 +n2 +n3

.

(38)

4. Conclusions In this paper we have examined the behavior a homogeneous and massive scalar (inflaton) field minimally coupled to the gravity in Bianchi type -I model of the universe, in the frame work of semicalssical theory of gravity. The inflaton is represented in squeezed vacuum state formalism of quantum optics and hence the approximate leading solution to the semiclassical Einstein equation is found. The next order solution for each scale factor in their respective direction show that each scale factor in each direction dependent on power law of expansion. Further more the solutions show that evolution of scale factors are mutually correlated. When n1 = n2 = n3 = n, then the corresponding solution reduces to isotropic model and is consistent with the result obtained as in the ref. 23. Form anisotropic to isotropic transition a damping mechanism is required. One of the efficient damping mechanisms could be due to the particle creation in anisotropic models. We have also examined the nonclassical particle creation in Bianchi type -I cosmological model by representing the inflaton in squeezed vacuum state formalism. The present study can account for the nonclassical particle creation and power law of expansion of the scale factors in Bianchi type -I universe, for a homogeneous and massive scalar field minimally coupled to the gravity,in the frame work of semiclassical theory of gravity. 8

Acknowledgements P.K.S. wishes to thank the Director and IUCAA, Pune, for warm hospitality and library facilities made available to him and acknowledges Associateship of IUCAA. References

1.C.W.Misner,Phys.Rev.186,1328(1969) 2.C.W.Misner, K.S.Thorne and J.A.Wheeler,Gravitation (Freeman,San Fransico)(1973) 3.O.Heckman and E.Schucking, Gravitation : An Introduction to Current Research (ed.L.Witten)(Wiley,New York,1962) 4.K.S.Throne, Ap.J. 148,51 (1967) 5.V.A.Belinski, E.M.Lifshitz, and I.M.Khalatnikov, Sov.Phys.Usp. 13,745 (1971) 6.Ya.B.Zel’dovich and A.A.Starobinsky, Zh.Eksp.Teor.Fiz. 61,2161(1971) 7.B.L.Hu and L.Parker, Phys.Rev. D17,933,(1978) 8.W.H.Huang, Phys.Rev. D42, 1287 (1990). 9.F.Futamas, Phys.Rev. D29, 2783 (1984). 10.A.L.Berkin, Phys.Rev. D46, 1551 (1992). 11.V.A.Belinski and I.M.Khalatnikov, Sov.Phys.JETP. 63,1121 (1972) 12.V.N.Folomeev and V.Ts.Gurovich, Gen.Rel.Grav. 32,1255(2000) 13.B.L.Shumaker,Phys.Rep.135317(1986) 14.L.P.Grishchuk and Y. V. Sidorov, Phys.Rev. D42, 3413 (1990). 15.R.Brandenberger, V. Mukhanov and T.Prokopec, Phys.Rev.Lett. 69, 3606 (1992). 16.C.Kuo and L.H.Ford, Phys.Rev. D46, 4510 (1993). 17.A.Albrecht .; et.al. Phys.Rev. D50, 4807 (1994). 18.M.Gasperini and M.Giovananni, Phys.Lett. B301, 334 (1993). 19.B.L.Hu, G.Kang and A.L.Matacz, Int.J.Mod.Phys. A9, 991 (1994). 20.P.K.Suresh, V.C.Kuriakose, and K.Babu Joseph, Int.J.Mod.Phys. D6, 771 (1995). 21.P.K.Suresh and V.C.Kuriakose, Mod.Phys.Lett. A13, 165 (1998). 22.P.K.Suresh, Mod.Phys.Lett. A16, 2431 (2001). 23.S.P.Kim and D.N.Page, J. Korian.Phy.Soc 35, S660 (1999).

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