Gravitons are described by the propagator in teleparallel gravity in nearly flat space-time. Finite temperature is introduced by using Thermofield Dynamics formalism. The gravitational Casimir effect and Stefan-Boltzmann law are calculated as a function of temperature. Then an equation of state for gravitons is determined.
Conselho Nacional de Desenvolvimento Científico e Tecnológico308611/2017-9430194/2018-81. Introduction
The teleparallel theory of gravity is similar to the general theory of gravity due to Einstein [1–4] except that it has a well-defined expression of energy-momentum tensor [5]. In addition the teleparallel gravity has a successful quantum approach using Weyl prescription [6]. Using a path integral approach a different propagator in teleparallel gravity is obtained [7]. Furthermore it is possible to introduce finite temperature effects in this formalism.
There are several approaches to introduce finite temperature formulation in a theory that can be quantized. Such a method involves doubling the physical space, Thermofield Dynamics (TFD) [8–16]. This thermal theory is obtained by using Bogoliubov transformation and it is a real-time formulation. The thermal state is obtained by doubling of Hilbert space, i.e., real space and a tilde space. The tilde space introduces temperature in the problem.
The objective of the paper is to use teleparallel theory of gravity and formulation of TFD to calculate the gravitational Casimir effect and Stefan-Boltzmann law. Originally the Casimir effect was observed by H. Casimir for parallel plates [17] which are attracted due to vacuum fluctuations of the electromagnetic field. Subsequent experiments have established this effect to a high degree of accuracy [18–20]. Experiments have observed both Casimir effect and Stefan-Boltzmann law experimentally for standard field theories. Gravitational field effects have been considered in gravitational field [21–24], violation of Lorentz theory [25–27], and in Kalb-Ramond field [28], among others.
This paper is organized as follows. In Section 2, details of the teleparallel gravity are described. In Section 3, details of the TFD formalism are defined in detail. In Section 4, the Green function is defined using the graviton propagator for the teleparallel gravity. In Section 5, the Casimir effect and the Stefan-Boltzmann law are obtained using finite temperature procedure. Then the first law of thermodynamics for gravitons is obtained. Finally in Section 6, some concluding remarks are given.
2. Teleparallel Gravity
Teleparallel gravity has unique features such as a well-defined expression for the gravitational energy-momentum tensor. This alternative theory is constructed in the framework of Weitzenböck geometry that is described by torsion and a vanishing curvature. Thus a Weitzenböckian manifold is endowed with a Cartan connection [29], defined by(1)Γμλν=eaμ∂λeaν,where eaμ is the tetrad field. Such a variable assures two fundamental symmetries in teleparallel gravity, Lorentz symmetry denoted by latin indices and diffeomorphism represented by greek ones.
It is important to note that the Cartan connection is curvature free, but it has the torsion tensor(2)Taλν=∂λeaν-∂νeaλ.On the other hand, Weitzenböck geometry is intrinsically related to Riemann geometry by the following mathematical identity(3)Γμλν=0Γμλν+Kμλν,where 0Γμλν are the Christoffel symbols and Kμλν is the contortion tensor given by(4)Kμλν=12Tλμν+Tνλμ+Tμλν,with Tμλν=eaμTaλν. Such an identity leads to the following relation:(5)eRe≡-e14TabcTabc+12TabcTbac-TaTa+2∂μeTμ,where e is the determinant of the tetrad field and R is the scalar mode of Christoffel symbols. Then a gravitational theory, dynamically equivalent to general relativity, is established by the following Lagrangian density:(6)Leaμ=-κeΣabcTabc-LM,where κ=1/(16π), LM is the Lagrangian density of matter fields and Σabc is given by(7)Σabc=14Tabc+Tbac-Tcab+12ηacTb-ηabTc,with Ta=eaμTμ. It is worth pointing out that in the Weitzenböch geometry it is possible to obtain a large number of invariants compared to the Riemannian case.
If a derivative of the Lagrangian density with respect to the tetrad field is performed, it yields(8)∂νeΣaλν=14κeeaμtλμ+Tλμ,with eeaμTλμ=∂LM/∂eaλ and(9)tλμ=κ4ΣbcλTbcμ-gλμΣabcTabc.This is the gravitational energy-momentum tensor [30, 31]. It should be noted that the quantity Σaλν is skew-symmetric in the last two indices, i.e., ∂λ∂νeΣaλν≡0 which implies a conservation law that leads to the energy-momentum vector(10)Pa=∫Vd3xeeaμt0μ+T0μ,that is a well-defined expression for energy and momentum. It is a vector under Lorentz transformations.
3. Thermofield Dynamics (TFD)
This section includes brief details of Thermofield Dynamics (TFD) [8–16]. TFD is a real-time formalism of quantum field theory at finite temperature. The thermal average of an observable is given in an extended Hilbert space. There are two necessary ingredients of TFD: the doubling of the degrees of freedom in Hilbert space and the Bogoliubov transformations. The doubling is defined by the tilde ~ conjugation. Each operator in the Hilbert space S has a fictitious Hilbert space S~. The Bogoliubov transformation combines the two spaces.
The creation (a†) and annihilation operators (a) in the standard Hilbert space and tilde operators, a~† and a~, are combined in the extended space using Bogoliubov transformations. For bosons these are(11)ak,α=uαak-vαa~†k,(12)a~†k,α=uαa~†k-vαak,and the algebraic rules for the operators are(13)ak,α,a†p,α=δ3k-p,a~k,α,a~†p,α=δ3k-p,and other commutation relations are null. The algebraic rules for these thermal operators are the same as obtained in the quantum field theory at zero temperature. The quantities u(α) and v(α) are related to the Bose distribution given as(14)v2α=1eαω-1,u2α=1+v2α.Here ω=ω(k) and α=1/β with β=1/(kBT) and kB is the Boltzmann constant and T is the temperature. There is a similar Bogoliubov transformation for fermions.
A doublet notation is introduced by(15)ak,αa~†k,α=Bαaka~†k,where B(α) is the Bogoliubov transformation given as(16)Bα=uα-vα-vαuα,The α parameter is assumed as the compactification parameter defined by α=(α0,α1,…,αD-1). The effect of temperature is described by the choice α0≡β and α1,,…,αD-1=0, where D are the space-time dimensions. Any propagator in the TFD formalism may be written in terms of the α-parameter. For the scalar field propagator, as an example, the Green function is(17)G0ABx-x′;α=i0,0~τϕAx;αϕBx′;α0,0~,where A,B=1,2 are the indices that define the double space and(18)ϕx;α=BαϕxB-1α.In the thermal vacuum 0α=Bα0,0~, the propagator becomes(19)G0ABx-x′;α=i0ατϕAxϕBx′0α,=i∫d4k2π4e-ikx-x′G0ABk;α,where(20)G0ABk;α=B-1αG0ABkBα,with(21)G0ABk=G0k00ξG0∗k,and G0(k)=1/k2. Here ξ=-1 for bosons and ξ=+1 for fermions. The nontilde variables describe the physical quantities. Then(22)G011k;α=G0k+ξu2k;αG0∗k-G0k,where u2(k;α), the generalized Bogoliubov transformation [32], is(23)u2k;α=∑s=1d∑σs2s-1∑lσ1,…,lσs=1∞-ηs+∑r=1slσrexp-∑j=1sασjlσjkσj,with d being the number of compactified dimensions and η=1(-1) for fermions (bosons), σs denotes the set of all combinations with s elements, and k is the 4-momentum.
4. Gravitational Casimir Effect and Stefan-Boltzmann Law
In this section the Stefan-Boltzmann law and the Casimir effect at zero and finite temperature are calculated in the teleparallel gravity framework. The free Lagrangian of the teleparallel gravity is(24)Lg=-keΣabcTabc,and using the weak field approximation, i.e.,(25)gμν=ημν+hμν,the graviton propagator is obtained as(26)ebλ,edγ=Δbdλγ=iηbdκqλqγ.Some details are given in [7]. This leads to the Green function(27)G0x,x′=-iΔbdλγgλγηbd,which explicitly is(28)G0x,x′=-i64πq2,with q=x-x′. It is worth comparing the graviton propagator in TEGR and general relativity. There is remarkable difference between the graviton propagator in general relativity that has the form(29)Δμνλγ=i2ημληνγ+ημγηνλ-ημνηλγG0q,where G0(q) is the Green function of a massless scalar field. Such a difference would be expected since the symmetry in the two theories are not the same.
Now it is necessary to calculate the mean value of tλμ (the gravitational energy-momentum tensor). In the weak field approximation, expanding expression (9) leads to(30)TbcλTbcμ=gμα∂γebλ-∂λebγ∂γebα-∂αebγ,TbcλTbcμgμλ=2∂γebα∂γebα-∂αebγ,TbcλTbcμgμλ=2∂γebα∂γebα-∂αebγ.These quantities are second order in the tetrad field while the terms(31)TcbλTbcμ=ebγecα∂γecλ-∂λecγ∂αebμ-∂μebα,TλbcTbcμ=eaλebα∂αeaγ-∂γeaα∂γebμ-∂μebγ,ebλTcTbcμ=ebλeaα∂αeaγ-∂γeaα∂γebμ-∂μebγ,ηbcTγTbcμ=ηbceaαecγ∂αeaλ-∂λeaα∂γebμ-∂μebγ,are of higher order in the field. These are dropped in the weak field approximation. Then the gravitational energy-momentum tensor is(32)tλμ=κgμα∂γebλ∂γebα-gμλ∂αebλ∂γebα-gμα∂λebγ∂γebα-∂λebγ∂αebγ-2gλμ∂γebα∂γebα-∂αebγ.To avoid a product of field operators at the same space-time point, the expectation value of energy-momentum tensor is(33)tλμx=0tλμx0,=limxμ→x′μ4iκ-5gλμ∂′γ∂γ+2gμα∂′λ∂αG0x-x′,where 〈ecλ(x),ebα(x′)〉=iηcbδαλG0(x-x′), with G0(x-x′) being the Green function.
In the TFD formalism, using the tilde conjugation rules, the vacuum average of the gravitational energy-momentum tensor is(34)tλμABx;α=limx→x′4iκ-5gλμ∂′γ∂γ+2gμα∂′λ∂αG0ABx-x′;α.It is impossible to get an analogues expression for general relativity since there is no energy-momentum tensor. However there is a propagator for the graviton. It is shared by other gravitational theories where the concept of gravitational energy is well established. Gravitoelectromagnetism (GEM) is certainly one theory where this is possible.
Following the Casimir prescription, the physical energy-momentum tensor is given by(35)TλμABx;α=tλμABx;α-tλμABx.Explicitly(36)TλμABx;α=limx→x′4iκ-5gλμ∂′γ∂γ+2gμα∂′λ∂αG¯0ABx-x′;α,where(37)G¯0ABx-x′;α=G0ABx-x′;α-G0ABx-x′.In the Fourier representation(38)G¯0ABx-x′;α=∫d4k2π4e-ikx-x′G¯0ABk;α,such that its physical component is(39)G¯011k;α=u2αG0k-G0∗k,where u2(α) is the generalized Bogoliubov transformation given in (23).
Now some applications are considered for different choices of the α-parameter.
4.1. Gravitational Stefan-Boltzmann Law
A first application is the case α=(β,0,0,0), such that the Bogoliubov transformation is given as(40)u2β=∑j0=1∞e-βk0j0.Then the physical component of the Green function is(41)G¯011x-x′;β=∫d4k2π4e-ikx-x′∑j0=1∞e-βk0j0G0k-G0∗k,=2∑j0=1∞G011x-x′-iβj0n0,where n0μ=(1,0,0,0). The vacuum expectation value of the gravitational energy-momentum tensor at finite temperature is(42)Tλμ11x;β=limx→x′∑j0=1∞8iκ-5gλμ∂′γ∂γ+2gμα∂′λ∂αG011x-x′-iβj0n0,At this point a nearly flat space-time, which represents gravitons precisely, may be analyzed. With λ=μ=0 and using the Riemann Zeta function [33, 34](43)ζ4=∑j0=1∞1j04=π490,and the gravitational Stefan-Boltzmann law is given by(44)ET=6415π4T4,where E(T)≡T00(11)(x;α). The first law of Thermodynamics is formulated as(45)E+P=T∂P∂TV,then(46)σT4+P=T∂P∂TVwhere σ=64π4/15. As a consequence, P=σT4/3 which leads to the equation of state(47)P=E3.The equation of state for both gravitons and photons is the same.
4.2. Gravitational Casimir Effect at Zero Temperature
In the framework of TFD formalism the Casimir effect at zero temperature is determined when α=(0,0,0,i2d). Then the Bogoliubov transformation becomes(48)u2d=∑l3=1∞e-i2dk3l3and the Green function is given as(49)G¯011x-x′;d=2∑l3=1∞G011x-x′-2dl3z.Then the energy-momentum tensor is(50)Tλμ11x;d=limx→x′∑l3=1∞8iκ-5gλμ∂′γ∂γ+2gμα∂′λ∂αG011x-x′-2dl3n3,where n3=(0,0,0,1). Then for λ=μ=0 the gravitational Casimir energy (at zero temperature) associated with the gravitons is(51)Ecd=-4π445d4,where the Riemann Zeta function has been used and Ec(d)≡T00(11)(x;d). Under such conditions and with λ=μ=3 the gravitational Casimir pressure is calculated as well; it reads(52)Pcd=-4π415d4,where Pc(d)≡T33(11)(x;d). Here the Casimir force between the plates is negative; then, it is an attractive force, similar to the case of the electromagnetic field.
4.3. Gravitational Casimir Effect at Finite Temperature
The effect of temperature in the Casimir effect is introduced by taking α=(β,0,0,i2d). Then(53)v2k0,k3;β,d=v2k0;β+v2k3;d+2v2k0;βv2k3;d,=∑j0=1∞e-βk0j0+∑l3=1∞e-i2dk3l3+2∑j0,l3=1∞e-βk0j0-i2dk3l3,(54)G¯011x-x′;β,d=4∑j0,l3=1∞G011x-x′-iβj0n-2dl3zare the Bogoliubov transformation and the Green function, respectively. The first term in (53) leads to the Stefan-Boltzmann law, the second term to the Casimir effect at zero temperature, and the third term to the Casimir effect at finite temperature. Considering only the third term, the energy-momentum tensor becomes(55)Tλμ11β;d=limx→x′∑j0,l3=1∞16iκ-5gλμ∂′γ∂γ+2gμα∂′λ∂α×G011x-x′-iβj0n-2dl3z.The Casimir energy at finite temperature for gravitons is(56)Ecβ,d=T0011β;d=-256∑j0,l32dl32-3βj022dl32+βj023,and the Casimir pressure at finite temperature is(57)Pcβ,d=T3311β;d=-256∑j0,l332dl32-βj022dl32+βj023,It is to be noted that these results were obtained using a metric tensor of an approximate Minkowski space-time. In addition Ec(β,d) recovers the dependency of T4 for d→0; similarly it tends to be proportional to d-4 when T→0. The same behavior is observed for Pc(β,d).
5. Conclusion
The graviton propagator is calculated using teleparallel gravity and this leads to a Green function. Details of TFD formalism are given to introduce temperature. Stefan-Boltzmann law and Casimir effect are calculated at finite temperature. This leads to finding pressure as a function of temperature. These results are obtained for a nearly flat space-time. These results play an important role in comparison with experimental results obtained for systems in outer space. An extension of this program for different space-time points will be carried out later. In addition the first law of thermodynamics is used to establish the dependency of the gravitational pressure on the temperature. The equation of state is found identical to that obtained for photons.
Data Availability
No data were used to support this study. Our study is completely theoretical.
Disclosure
F. C. Khanna is Professor Emeritus, Physics Department, Theoretical Physics Institute, University of Alberta, Edmonton, Alberta, Canada.
Conflicts of Interest
The authors declare that they have no conflicts of interest.
Acknowledgments
This work by A. F. Santos is supported by CNPq projects 308611/2017-9 and 430194/2018-8.
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