It has been argued that the correct, that is, positive, sign of quantum vacuum energy density, or, more properly, negative sign of quantum vacuum pressure, requires not a very large, and to some extent model-independent, number,
for example, ~100, of additional, undiscovered fundamental bosonic particle species, absent in the standard model. Interpretation of the new particle species in terms of dark matter ones permits to qualitatively, and even quantitatively, connect all the three concepts given in the title.
Dark energy [1–3] and dark matter [4, 5] are two main constituents of our universe. Their contribution amounts to almost 96% of the total energy-mass of the universe. The nature of the both seems to be mysterious but completely different. Another mysterious and elusive constituent of our universe, appearing in theoretical context rather than in a cosmological one, is quantum vacuum [6]. But, recently, mainly due to advances in the Casimir effect, the quantum vacuum is beginning to enter reality [7]. The old idea to identify dark energy and quantum vacuum energy is theoretically very attractive but the main difficulty is to reconcile the values of both energies [8–13]. That is a puzzle. But there is another puzzle, usually not being mentioned. Since, as it is well known, the sign of quantum vacuum energy follows from the statistics of fluctuating fields, the right (positive) sign of vacuum energy corresponds to bosonic modes. But the number of different fermionic particle species prevails in the standard model, and that is the puzzle. Thus, actually, we have the two independent puzzles related to the connection between quantum vacuum energy and dark energy: the puzzle of the huge (absolute) value of quantum vacuum energy density and the puzzle of its sign.
It appears, and this is the main subject of our letter, that it is possible to solve the second puzzle, establishing a link between the issue of dark energy and dark matter. Namely, not a very large, and to some extent model-independent, number of undiscovered bosonic fields should be included in the fundamental set of particle species to obtain the right sign of vacuum energy density. These new species are natural candidates for dark matter particle species.
A typical approach to quantum vacuum energy yields the standard formula [8] ϱvac=12∫0Λuv4π(2πℏ)3c(mc)2+k2k2dk,
where m is the mass of a bosonic mode and k is its momentum. For a large ultraviolet (UV) cutoff Λuv we have approximately ϱvac≈1(4π)2Λuv4ℏ2c.
Setting Λuv=ΛP, where the Planck momentum ΛP=ℏc3G≈6.5kgm/s
and G is the Newton gravitational constant, we obtain the “(in)famous” value (formula) ϱvac≈c5(4π)2ℏG2≈3.4×1094kg/m3≈MPLP3,
where MP and LP are the Planck mass and length, respectively. The fame of this formula rivals its absurdity. Not only is (4) some 10120 times greater than expected but evidently the sign is not as expected. For fermionic modes the sign of (4) will be reversed! Therefore, for presently known contents of fundamental set of fields (with prevalent fermionic modes) the sign will be wrong. Consequently, new bosonic species are urgently being looked for.
One should emphasize that the difficulty with the sign seems to be independent of the approach to the issue of the huge value of quantum vacuum energy. In other words, additional bosonic modes are presumably unavoidable provided quantum vacuum is supposed to have something to do with dark energy or, at least, with reality. Taking for granted that new bosonic particle species should enter the set of fundamental fields any further estimate of their number could already depend on the assumed model of dark energy in the framework of the idea of quantum vacuum.
In [14, 15], we have proposed a phenomenologically promising approach to solve the puzzle of the huge (absolute) value of “the quantum vacuum energy density.” In the framework of our approach the (absolute) value of the “vacuum energy density” of a single mode is of the order ϱ~0.01ϱexp,
where ϱexp is the experimental value of the energy density of dark energy. Thus, (5) gives the result for a single mode. Obviously, the relation (5) is model dependent. In our approach [14, 15] it is just (5).
Strictly speaking, the formula yielding the result (5), that is, the lagrangian density [14, 15] ∓141(4π)2G12(1-q)H2,
where the upper and lower signs correspond to a bosonic and fermionic mode, respectively, q is the present deceleration parameter, and H is the present Hubble expansion rate, corresponds to the pressure rather than to the energy density.
In fact, the diagonal part of the energy-momentum tensor, Tμν=∂L∂∂μϕ∂νϕ-gμνL,
reduces to T00≡ϱ=-g00L,for∂0ϕ=0,
or Tii≡p=-giiL,for∂iϕ=0,
where c=1 and the signature of the metric is (+,-,-,-). Our case corresponds obviously to the second possibility, that is, (9), because our fields are homogeneous (∂iϕ=0) but time dependent (Friedmann-Lemaître-Robertson-Walker cosmological model).
Coming back to our model ∓141(4π)2G12(1-q)H2≈L=-1giip,
and therefore p≈∓141(4π)2G12(1-q)H2,
which still conforms with our description of dark energy in terms of quantum vacuum. For example, assuming temporarily an ad hoc barotropic relation p=wϱ,w=-1,
we simply obtain ϱ≈±1128π2G(1-q)H2.
But (11) (for pressure) is more fundamental than (13) (for energy density) because no equation of state needs to be presumed.
Consequently, as a next step, we should collect contributions, of the type estimated by us, coming from all fundamental physical modes. We can proceed in the spirit of the philosophy of quantum- (vacuum-) induced interactions (see, e.g., [16–18]). Thus, the total pressure, coming from all fundamental modes, is according to (11) of the order p≈-N0128π2G(1-q)H2,
and ϱexp≈N0ϱ, where N0 is the “alternated sum” of the fundamental modes. Namely, we define N0≡nB-nF=∑k=0(-)knk/2,
where nB and nF are the number of fundamental bosonic and fermionic modes, respectively. By virtue of the spin-statistics theorem we can rewrite N0 in terms of spin degrees of freedom, that is, n0, n1/2, n1, and so forth. One should note that the particular case nB=nF corresponds to supersymmetry.
Recapitulating, the puzzle related to quantum vacuum fluctuations consists in getting under control of the huge value of the vacuum energy density, strictly speaking, from our point of view, the (absolute) value of the pressure. Once the value becomes reasonable in its size, the sign puzzle emerges. The sign assumes the expected value, for example, “minus” in (14), only provided the number of bosonic fundamental modes is prevalent.
We would like to stress, once more, that the conclusion concerning bosonic species is not specific to our model of dark energy, because only bosonic modes give contributions huge or moderate but with right signs. Since the standard model contains greater number of fermionic particle species (leptons and quarks) than bosonic ones (mainly, gauge fields), we can conclude that there is a missing number of invisible bosonic modes. The bosonic modes do not enter the standard model but they must interact gravitationally. Therefore, they are appropriate and natural candidates to the role of dark matter particles.
More concretely, for the standard model N0=[4]-2⋅3⋅(3+3⋅4)+2⋅(1+3+8+[1])=-(63±3),
where in the first bracket we have included, as yet not discovered, Higgs modes, next there are leptons and quarks (2 spins × 3 families × (3 leptons of the both helicities + 3 colors × 4 quarks of the both helicities)), and, finally, gauge fields (2 spins × (photon + 3 weak bosons + 8 gluons)) with graviton in the last bracket. From (14) and (16) (see, also (5) for a numeric value) it follows that the lacking number of bosonic modes is of the order nB~100. This number is model dependent but the conclusion is not.
Any possible, alternative, and independent solution of the puzzle of the huge (absolute) value of quantum vacuum energy density also would require additional bosonic species but their number could vary. For example, any potential solution directly yielding the right (absolute) value of the quantum vacuum energy density, meaning that the correct (absolute) value is recovered for a single mode, would require a tuning between the number of bosonic and fermionic species, that is, nB-nF~1.
Certainly, it would be very advantageous to present an alternative and independent estimate of the number of the lacking fundamental bosonic modes nB. To this end we will make use of the proposal given in [18], concerning quantum vacuum-induced gravitational action and quantum vacuum-induced gravitational (black-hole) thermodynamical entropy. Assuming the number and kind of fundamental modes given in (16), we get nB~40 to properly induce the gravitational action (see equation (8) in [18]), and nB~200 to properly induce the gravitational (black-hole) thermodynamical entropy (see equation (2) in [18]). Taking into account an approximate character of our reasoning one should admit that it qualitatively agrees with our present dark energy estimate, that is, nB~100.
In this paper, we have proposed a consistent connection between the following three concepts: quantum vacuum pressure, dark energy, and dark matter. First of all, we have shown that, in the context of lagrangian approach, the quantum pressure naturally replaces the notion of quantum vacuum energy density. Next, we have argued that, independently of an actual model of dark energy, additional, undiscovered fundamental bosonic particle species are necessary. Finally, applying our earlier model of dark energy [14, 15] we have estimated the number of the fundamental bosonic particle species, namely, nB~100. Amazingly, it agrees with the estimates being yielded by induced gravity [18].
Acknowledgments
This work has been supported by the University of Łódź grant and LFPPI network.
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