Abstract
The paper deals with the scale discrepancy between the observed vacuum energy in cosmology and the theoretical quantum vacuum energy (cosmological constant problem). Here, we demonstrate that Einstein’s equation and an analogy to particle physics leads to the first physical justification of the so-called fine-tuning problem. This fine-tuning could be automatically satisfied with the variable cosmological term \(\varLambda (a)=\varLambda _0+\varLambda _1 a^{-(4-\epsilon )}\), \(0 < \epsilon \ll 1,\) where a is the scale factor. As a side effect of our solution of the cosmological constant problem, the dynamical part of the cosmological term generates an attractive force and solves the missing mass problem of dark matter.
1 Introduction
Direct cosmological experiments could only observe 5% of the total matter-energy content of the universe. The remaining unknown components dark matter and dark energy are classified by their gravitational effects. The first component behaves attractively and constitutes 26% of the matter-energy density, whereas the dark energy has a fraction of 69% and is responsible for an accelerated expansion of the universe [1]. Since the 1990s, the cosmological constant \(\varLambda \) in Einstein’s field equation
has been used as a simple explanation for an expansion of the universe (see [2,3,4,5] for further details and [6] for notational conventions). Due to the unknown form of the underlying energy, this anti-gravitational mechanism is called dark energy. From the source point of view the cosmological constant can be written as an energy-momentum tensor
where \(p_\varLambda =-\varLambda /\kappa , \rho _\varLambda =-p_{\varLambda }/c^2\) and \(u_\mu \) is the fluid four-velocity. Hence, in the absence of matter the cosmological constant could be interpreted as the energy density of the vacuum. In contrast to the notion of an empty space, the quantum field theory defines the vacuum as the state of lowest energy density. A comparison of both concepts by cosmological observations of \(\varLambda \) and theoretical calculations of the quantum energy density uncovers a large discrepancy
which is “the most striking problem in the contemporary fundamental physics” [7].
Changing the point of view and defining the cosmological constant by \(\varLambda =\kappa c^2 \rho ,\) where \(\rho \) is a density field which contributes to the vacuum energy density, it is natural to assume \(\varLambda \) as a dynamical quantity. Furthermore, there are no a priori reasons why \(\varLambda \) should not vary - as long as the energy conservation
is satisfied (see [8, p. 2]).
The remainder of the paper is organised as follows. In Sect. 2 we review the pressure-free Friedmann equations where the cosmological term \(\varLambda \) is a function of the scale factor a. Section 3 is devoted to a Klein-Gordon equation for the scale factor. In order to identify the arrived equation as an Euler-Lagrange equation, the Klein-Gordon equation is transformed to a scale factor independent space-time metric. Then, the Lagrangian density could be determined and the related energy-momentum tensor of an empty Friedmann universe is studied in Sect. 4. This enabled us to establish a canonical decomposition of the total energy into a cosmological and a remainder term. Consequently, the fine-tuning of the energy densities is justified. Moreover, we demonstrate with an application of the model \(\varLambda (a)=\varLambda _0+\varLambda _1 a^{-(4-\epsilon )}\), \(0 < \epsilon \ll 1\) that the total energy density of an empty Friedmann universe equals the quantum zero-point energy. Finally, we show that our solution of the cosmological constant problem explains cosmological observations without the missing mass of dark matter.
2 A time-dependent cosmological term
Let M be a 4-dimensional manifold equipped with a metric \(\bar{g}_{\mu \nu },\) which determines the space-time interval as follows:
where \(d \varOmega ^2=d\theta ^2 + \sin ^2 \theta d \phi ^2\) and k denotes the curvature parameter of unit \(\text {length}^{-2}.\) Inserting the metric \(\bar{g}_{\mu \nu }\) in Einstein’s field equation, we get Friedmann’s equations for the scaling factor a(t)
Until now, several decay laws in which \(\varLambda \) is a function of time, the scale factor, the Hubble Parameter and the deceleration parameter have been discussed in the literature (see [8] for an overview). Here, we consider a cosmological term of the form
It is convenient to include the \(\varLambda \)-term in the energy-momentum tensor of the right-hand side. Therefore, we define an effective density and pressure field
where \(\rho _b=\varLambda (a)/\kappa c^2\) and \(p_b=-\varLambda (a)/\kappa \) denote the background fields. Now, Einstein’s field equation can be written as
where
is the effective energy-momentum tensor. The theory is well-defined if
is satisfied. Moreover, a straightforward calculation gives
or equivalent
Equation (5) is solved in the case of a matter dominated universe by \(p=0\) and
Therefore, it follows
3 Conformally-related trace equation
In this section we provide the ground for a total energy discussion of an empty Friedmann universe which is compatible with quantum field theory. To do so, we have to establish the notion of total energy on a Lagrangian density such that the Euler–Lagrange equation is consistent with Friedmann’s equations. Therefore, we have to find a space-time metric which is independent of the scale factor. In order to do so, we start from the field equation for the Robertson–Walker metric \(\bar{g}_{\mu \nu }\) and consider the transformed equation for the conformally-related metric \(g_{\mu \nu }.\)
Let u be a strictly positive \(C^\infty (M)-\)function. The metric \(g_{\mu \nu }=u^{-2} \bar{g}_{\mu \nu }\) is said to be conformally-related to \(\bar{g}_{\mu \nu }.\) Introducing the notation \(\nabla _{\mu }\) for the covariant derivative, \(\varDelta =g^{\mu \nu } \nabla _{\mu } \nabla _{\nu }\) and \(|\nabla u|^2=g^{\mu \nu } \nabla _{\mu } u\nabla _{\nu }u,\) we note down the relation for the Ricci scalar (see [6, p. 446])
Inserting the relation for the Ricci scalar into the trace of Eq. (4), we see that
which leads to
Up to now the above considerations are valid for every strictly positive \(u \in C^\infty (M).\) Fixing this function by \(u=a\), we get \(R=6k\) and a Klein-Gordon equation which allows constant coefficients
By using the conformal time \(d\tau =dt/a(t),\) the conformally-related metric \(g_{\mu \nu }\) transforms to a curved Minkowski metric
and the Klein–Gordon equation could be written in the form
Note that, by setting \(\varLambda (a),\) one can realise the usual potentials from scalar field theory.
4 Vacuum energy
In this section we investigate the total energy density of an energy-momentum tensor which is generated by the Lagrangian density of an empty Friedmann universe. According to [5, 9], Lorentz invariance implies that the energy density of the vacuum (zero-point energy) acts like a cosmological constant. Hence, there has to be a decomposition of the form
where the total zero-point energy density is defined as the lowest energy (ground state) and can be expressed by
(cf. [2, 5]). Here, \(k_{\max } =1/l_p\) denotes a cut-off wave-number and \(l_p\) is the Planck length. Using the observed value for \(\rho _{\varLambda }\) (cf. [1]), this requires a fine-tuning of 121 orders of magnitude. Until now, no physical justification for Eq. (11) is known.
Since \(\eta _{\mu \nu }\) is independent of a, Eq. (10) is the Euler–Lagrange equation of the Lagrangian
and
is the related energy-momentum tensor (cf. [10, p. 65]). Interpreting the energy-momentum tensor for a perfect cosmic fluid, we get the total energy density and pressure
Further \(\dot{a}(\tau )\) depends on the coefficients of V(a). Using Eq. (1), we get
Therefore, the total energy density yields
Using the setting \(V_0=0,\) Eq. (15) is the physical justification of Eq. (11) and yields
Hence, the fine-tuning happens automatically if an appropriate \(\varLambda (a)\) can be found that identifies the total energy of the vacuum in quantum field theory and general relativity. Therefore, we identify the zero-point energy of a quantum system with the total energy density of an empty Friedmann universe. In order to do that, we consider the model
which was also investigated in [11]. Using Eqs. (15) and (16), it follows that the total energy density is independent of \(\varLambda _0,\) i.e.
Identifying the total energy densities and using the convention \(a_0=a(t_0)=1\) for today’s scale factor, we get
If one can fit (17) with present cosmological observations (\(\varLambda (a)c^2/3H_0^2\) is of order unity), then \(4 \int ^a \varLambda (\alpha ) \alpha ^3 \, d\alpha / \kappa c^2 a^4\) is identified as the cancellation mechanism which cancels 121 decimal places. As the consequence, there is no scale discrepancy between the total energy densities and the cosmological constant problem is solved.
It remains to consider some observational constraints. The dynamics of the universe are determined by the Eqs. (7) and (8), which depend on the term
Therefore, we get for the matter density and \(r \ne 3\)
which is always positive if \(\varLambda _1/(3-r)>0.\) Moreover, we assume an initial singularity. From Eqs. (8) and (19), we can see that a has an initial singularity if \(\varLambda _1/(3-r)>0\) is satisfied again.
It remains to discuss some choices for the parameter r. First, let \(0<r <3.\) Since (18) leads to \(\varLambda _1/(3-r)<0,\) we neglect this case. Further we have \(3<r<4,\) which gives the compatiblility condition \(\varLambda _1/(3-r)>0.\) In [11, 12], this case was excluded from the considerations because it was assumed without further substantiation that \(\varLambda _1\) is always positive. In order to analyse the acceleration behavior, we have to discuss the term
from Eq. (9). Obviously, it follows from the considered parameter range that the dynamical part of (21) has a different sign than the usual cosmological constant term. Consequently, the solution of the cosmological constant problem yields a cosmological term with the attractive effect of dark matter.
Finally, using the settings
where \(H_0\) denotes the actual Hubble constant, Eq. (8) could be written as
To relate the last equation with observations (cf. [1]), we consider \((\varOmega _k,\varOmega _m,\varOmega _{\varLambda },\varOmega _{dm})=(0,0.05,0.69,0.26)\) and \(H_0=67.74 \frac{km}{s\, Mpc}.\) Using \(r=4-\epsilon ,\) it follows from (18) and (22) that the compatibility condition is fulfilled by
which is satisfied by \(\epsilon =9.151 \cdot 10^{-122}.\) Moreover, for the remaining parameters \(\varLambda _0\) and \(\varLambda _1\) we get
5 Concluding remarks
In this paper, the solution of the cosmological constant problem is demonstrated by an application of a variable cosmological term \(\varLambda (a)=\varLambda _0 + \varLambda _1 a^{-(4-\epsilon )}\). It has been shown that the expansion field a satisfies the Klein-Gordon equation in a non-dynamical space-time and that a variational cosmological term can realise the usual potentials from particle physics. Further it was confirmed that the total energy density of an empty Friedmann universe is related to the cosmological term such that the fine-tuning problem was avoided by the setting \(\varLambda _1=- \epsilon /2 \pi (4-\epsilon ) l_p^2.\) As a consequence of the constraint \(0< \epsilon <1,\) the initial singularity is guaranteed and the dynamical part of the cosmological term generates the attractive force of dark matter. Finally, the setting of \(\epsilon =9.151 \cdot 10^{-122}\) generates the missing mass of dark matter which constitutes 26% of the matter-energy density.
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Henke, C. Quantum vacuum energy in general relativity. Eur. Phys. J. C 78, 126 (2018). https://doi.org/10.1140/epjc/s10052-018-5621-7
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DOI: https://doi.org/10.1140/epjc/s10052-018-5621-7