Abstract
Inflationary scenario in locally rotationally symmetric (LRS) Bianchi Type II space-time with massless scalar field with flat potential is discussed. To get the deterministic solution in terms of cosmic time , we have assumed that the scale factor , that is, and β=βconstant where is effective potential and is Higg's field. We find that spatial volume increases with time and the model isotropizes for large value of under special condition. The Higg's field decreases slowly and tends to a constant value when . The model represents uniform expansion but accelerating universe and leads to de-Sitter type metric.
1. Introduction
Inflationary universes provide a potential solution to the formation of structure problem in Big-Bang cosmology like Horizon problem, Flatness problem, and magnetic monopole problem. Guth [1] introduced the concept of inflation while investigating the problem of why we see no magnetic monopole today. He found that a positive-energy false vacuum generates an exponential expansion of space according to general relativity. In Guth inflationary universe, the scalar field is assumed to start at ; being a local minimum of () where is effective potential and is Higgβs field which breaks the symmetry. In this case, the energy-momentum tensor of particles ( being absolute temperature) almost vanishes in the course of expansion of the universe and the total energy-momentum tensor reduces to vacuum energy, that is, where is effective potential at vanishing temperature (Zelβdovich & Khlokov [1978]). This leads to where is scale factor and is Hubble constant. Rothman and Ellis [2] have pointed out that we can have a solution of isotropic problem if we work with anisotropic metric and these metrics can be isotropized under various general circumstances. Stein-Schabes [3] has shown that inflation will take place if effective potential has flat region while Higgβs field evolves slowly but the universe expands in an exponential way due to vacuum field energy. Burd [4] has discussed inflationary scenario in FRW (Friedmann-Robertson-Walker) model. Anninos et al. [5] discussed the significance of inflation for isotropization of universe. In modern cosmology, inflation is an essential ingredient. During the inflationary epoch, the scale factor of the universe grew exponentially allowing a small causally coherent region to grow enough to be identified with the present observable universe. Linde [6] proposed a chaotic model with an assumption that the present universe is originated from chaotic distribution of initial scalar field when potential energy of the field dominates over that of kinetic energy. Later on, it has been shown by Bunn et al. [7] that chaotic scenario can be realized even when scalar field is kinetic energy dominated. Paul et al. [8] have shown that Lindeβs chaotic scenario is fairly general and can be accommodated even if universe is anisotropic. Bali and Jain [9] has discussed inflationary scenario in LRS Bianchi Type I space-time in the presence of massless scalar field with flat potential. Reddy et al. [10] have investigated inflationary scenario in Kantowski-Sachs space-time. Recently Bali [11] investigated inflationary scenario in anisotropic Bianchi Type I space-time with flat potential considering the scale factor = as introduced by Kirzhnits and Linde [12].
Motivated by the above-mentioned research works, we have investigated inflationary scenario in LRS Bianchi Type II space-time with flat potential, and assuming the condition scale factor , is Hubble constant as introduced by Kirzhnits and Linde [12]. The model represents an anisotropic universe which isotropizes for large value of under special condition as shown by Rothman and Ellis [2]. The model represents uniform expansion but accelerating universe. The model leads to de-Sitter space-time.
2. Metric and Field Equations
We consider Bianchi Type II metric in the form with Therefore, the metric (2) leads to the form where and are functions of -alone.
The Lagrangian is that of gravity minimally coupled to be a scalar field given by (Notations have their usual meaning and in geometrized unit ). Now from the variation of with respect to the dynamical fields, we obtain Einstein field equation for massless scalar field as where with where the flow vector, the Higgβs field, the potential, and the metric tensor. Here The Einsteinβs field equation (6) for the metric (4) leads to Equations (8) for scalar field leads to
3. Solution of Field Equations
To get deterministic solution in terms of cosmic time , we assume that scale factor , that is, as considered by Bali [11]. We also assume that effective potential = constant. Thus (11) leads to Equation (10) leads to where From (12), we have Using (16) in (14), we get where From (17), we have being constant of integration. Equation (19) leads to Equations (19) and (16) lead to Hence the metric (4) reduces to the form
To determine Higgβs field
Using the assumed condition in (11), we have
Equation (23) leads to
where and are constants.
4. Some Physical and Geometrical Aspects
The spatial volume () for the model (22) is given by The expansion () is given by The shear () is given by which leads to The deceleration parameter () is given by where
5. Conclusions
The spatial volume increases with time. Hence inflationary scenario exists in Bianchi Type II space-time. The model (22) in general represents an anisotropic universe. However the model isotropizes for large values of and . The Higgβs field decreases slowly, and it tends to a constant value when . There is uniform expansion and deceleration parameter . Hence the model leads to de-Sitter space-time, and the model represents accelerating universe.