We study the behavior of the vacuum condensates characterizing many physical phenomena. We show that condensates due to thermal states, to fields in curved space, and to neutrino mixing, may represent new components of the dark matter, whereas the condensate due to axion-photon mixing can contribute to the dark energy. Moreover, by considering a supersymmetric framework, we show that the nonzero energy of vacuum condensates may induce a spontaneous supersymmetry breaking.
Ministero dell’Istruzione, dell’Università e della RicercaINFN1. Introduction
In recent years, many efforts have been made to understand the nature and the origin of the dark energy and of the dark matter [1–29], which represent almost the 68% and the 27%, respectively, of the matter and energy content of the universe [30–34].
Another important field of study is the supersymmetry (SUSY) [35–40]. Such a symmetry associates any boson to a fermion (called superpartner) with the same mass and internal quantum numbers and vice versa. However, up to now, no superpartner has been detected. Therefore, SUSY must be a broken symmetry, which permits the existence of superpartners heavier than the corresponding particles, or it must be ruled out as a fundamental symmetry. In particular, intensive study has been devoted to the analysis of the possibility of SUSY breaking.
Here we report on recent results [41–47] obtained by studying the condensate structure of the vacuum of many phenomena such as Hawking effect and fields in curved space [48–61]. In the framework of the standard model of particles, we show that the thermal vacuum of the hot plasma present at the center of a galaxy cluster, the vacuum fluctuations of fields in curved space [62], and the flavor neutrino vacuum give nontrivial contributions to the energy of the universe and have a pressure equal to zero. Thus, such condensates, in the presence of ordinary matter, can aggregate structures and to represent a component of the dark matter. A behavior completely different is the one of the vacuum condensate induced by the axion-photon mixing. Indeed, in this case the condensate has a state equation which coincides with one of the cosmological constants and can contribute to the dark energy of the universe [41, 42]. Then, the condensates can provide both the effects of the dark part of the universe, that is, the dynamical and the gravitational ones.
It is worth stressing that the condensate contributions are different from the usual zero-point energy contribution of fields. Indeed they are not originated from radiative corrections, but they derive from the property of QFT of being characterized by infinitely many representations of the canonical (anti)commutation relations in the infinite volume limit. Values compatible with the estimated ones for dark matter and dark energy are obtained by using reasonable values of the cut-offs on the momenta. This result is due to the drastic decrease in the degree of divergency, for high momenta, of integrals describing the energy-momentum tensor of the condensates, in comparison with the case of the zero-point energy of a free field. Indeed, the usual zero-point energy contribution goes like K4 for high momenta. Such divergence and K2 one are removed in the vacuum condensates [63–67].
We also consider the framework of the supersymmetry and, by using the free Wess–Zumino model, we show that the presence of nonvanishing vacuum energy at the Lagrangian level implies that SUSY is spontaneously broken by the condensates [43–47].
The structure of the paper is the following: in Section 2, we introduce the Bogoliubov transformations in quantum field theory (QFT) and we study the energy-momentum tensor density for vacuum condensates of boson and fermion fields. In Sections 3 and 4, we present the contribution given to the energy of the universe by thermal states, with reference to the Hawking and Unruh effects, by fields in curved space and by particle mixing phenomena. SUSY breaking induced by vacuum condensate is presented in Section 5 and Section 6 is devoted to the conclusions.
2. Bogoliubov Transformation and Energy-Momentum Tensor of Vacuum Condensate
Many phenomena, ranging from the BCS theory of superconductivity [51] to the Casimir and the Schwinger effects [50], are represented, in the context of QFT, by a Bogoliubov transformation [55]. Such a transformation for bosons is expressed as ak(ξ,t)=UkBak(t)-V-kBa-k†(t), with ξ parameter depending on the phenomenon analyzed, ak annihilators of the vacuum 0, and UkB, VkB, coefficients satisfying the conditions UkB=U-kB, VkB=V-kB, and UkB2-VkB2=1 (similar discussion holds for fermions).
Introducing the generator J(ξ,t) of the Bogoliubov transformation, one can write ak(ξ,t)=J-1(ξ,t)ak(t)J(ξ,t). Here J(ξ,t) is a unitary operator, J-1(ξ)=J(-ξ), which allows relating the original vacua 0 to the vacua 0ξ,t annihilated by ak(ξ,t); 0ξ,t=J-1ξ,t0. Such a relation is a unitary operation in quantum mechanics, where k assumes a discrete range of values, but it is not a unitary transformation in QFT, where k assumes a continuous infinity of values. In this case, 0ξ,t and 0 are unitarily inequivalent and the proper physical vacua are 0ξ,t [54, 55]. Such vacua have a condensate structure which is responsible for an expectation value of the number operator Nk=ak†ak on 0ξ,t different from zero; 0ξ,tak†ak0ξ,t=Vk2. This fact implies a nontrivial result of the expectation value of the energy-momentum tensor density Tμν(x) for free fields on 0ξ,t; Ξμνλx=λ0ξ,t:Tμνλ(x):0ξ,tλ. Here, :⋯: denotes the normal ordering with respect to the original vacuum 0λ. Notice that the off-diagonal components of Ξμνλ(x) are zero, Ξi,jλ(x)=0, for i≠j, then the condensates act as a perfect fluid, and one can define their energy density and pressure, by means of the (0,0) and the (j,j) components of Ξμνλ(x), as ρλ=Ξ00λ(x) and pλ=Ξjjλ(x) [41, 42].
For bosons, in the particular case of the isotropy of the momenta, k1=k2=k3, the energy density, the pressure, and the state equation, wB=pB/ρB, are given by [41, 42](1)ρB=12π2∫0∞dkk2ωkVkB2,(2)pB=16π2∫0∞dkk2k2ωkVkB2-k2ωk+3m22ωkUkBVkBcosωkt,(3)wB=13∫d3kk2/ωkVkB2∫d3kωkVkB2-13∫d3kk2/ωk+3m2/2ωkUkBVkBcosωkt∫d3kωkVkB2,respectively. For Majorana fermions, one has [41, 42](4)ρF=1π2∫0∞dkk2ωkVkF2,(5)pF=13π2∫0∞dkk4ωkVkF2,(6)wF=13∫d3kk2/ωkVkF2∫d3kωkVkF2.The equations presented above hold for all the systems described by Bogoliubov transformations in QFT. By using such equations and the explicit form of the Bogoliubov coefficients, we analyze the cases of thermal states and of fields in curved spaces. Then, we study the particle mixing phenomenon which, at the level of the annihilators, is described by a Bogoliubov transformation and a rotation. This fact implies that, for particle mixing, (1)–(6) must be modified, as shown in Section 4.
3. Dark Matter Components from Thermal States, Hawking and Unruh Effects, and Fields in Curved Background
We show that thermal vacuum states and vacuum condensate of fields in curved space can be interpreted as components of the dark matter.
We start by considering the thermal vacuum state 0ξβλ introduced in the framework of Thermofield Dynamics (TFD) (where β≡1/(kBT), and kB is the Boltzmann constant and λ=B,F) [53–55]. In such a context, every degree of freedom is doubled and the thermal Bogoliubov transformation allows defining, at nonzero temperature, the state 0ξβλ such that the thermal statistical average is given by 0ξβλNχk0ξβλ, where Nχk=χk†χk, (χ=a for bosons and α for fermions) is the number operator [54]. The Bogoliubov coefficients are UkT=eβωk/(eβωk±1) and VkT=1/(eβωk±1), with − for bosons and + for fermions, and ωk=k2+m2. The energy density and pressure of 0ξβλ, obtained by (1)–(6) with Uk=UkT and Vk=VkT, permit studying many thermal systems.
We obtain that, for temperatures of order of the cosmic microwave radiation (i.e., T=2.72K), only photons and very light particles contribute to the energy radiation with ρ~10-51GeV4 and state equations, w=1/3, whereas nonrelativistic particles give negligible contributions [68]. On the other hand, the thermal vacuum of the hot plasma filling the center of galaxy clusters with temperatures (10÷100)×106K can contribute to the dark matter. Indeed, such a vacuum has an energy density of (10-48–10-47)GeV4 and a pressure p~0. Moreover, since the temperatures related to Unruh and Hawking effects are very low, their contributions to the energy of the universe are negligible [68].
Let us now consider fields in curved background. In such a case, the Bogoliubov coefficients depend on the metric analyzed [58]. Here, we study boson fields in spatially flat Friedmann Robertson-Walker metric, ds2=dt2-a2(t)dx2=a2(η)(dη2-dx2), where t is the comoving time, a is the scale factor, and η(t)=∫t0t(dt/a(t)) is the conformal time, with t0 arbitrary constant.
The energy density and pressure are [69, 70](7)ρcurv=2πa2∫0Kdkk2ϕk′2+k2ϕk2+m2ϕk2,pcurv=2πa2∫0Kdkk2ϕk′2-k23ϕk2-m2ϕk2,where K is the cut-off on the momenta, ϕk are mode functions, and ϕk′ are the derivative of ϕk with respect to the conformal time η. The numerical value of ρcurv, of pcurv, and of the state equation wcurv are depending on the choice of K. However, it has been shown in [62] that, in infrared regime, by using a cut-off on the momenta much smaller than the comoving mass of the field, K≪ma, and setting m≫H, one obtains the state equation of the dark matter, wcurv≃0. The energy density, in this case, is ρcurv=mK3/12π2a3, which is much smaller than m4/12π2. Therefore, the contributions of light particles are compatible with the value estimated for the dark matter.
4. Dark Matter Component from Neutrino Mixing and Dark Energy Contribution from Mixed Bosons
We now compute the contributions to the energy given by the vacuum of mixed fields. The particle mixing concerns fermions as neutrinos and quarks and bosons as axions, kaons, B0, D0, and η-η′ systems. The mixing of two fields is expressed as(8)φ1θ,x=φ1xcosθ+φ2xsinθ,φ2θ,x=-φ1xsinθ+φ2xcosθ,where θ is the mixing angle, φi(x) are free fields, and φi(θ,x) are mixed fields, with i=1,2.
The generator of the mixing, J(θ,t), allows writing (8) as φi(θ,x)≡J-1(θ,t)φi(x)J(θ,t) and the mixed annihilation operators as χk,ir(θ,t)≡J-1(θ,t)χk,ir(t)J(θ,t). Here we denote with χk,ir the annihilators of bosons ak,i and the ones of fermions αk,ir [59, 60]. One can see that the mixing transformation, at the level of annihilators, is a rotation plus a Bogoliubov transformation [59, 60]. Then the physical vacuum, 0θ,t≡J-1(θ,t)01,2 (where 01,2 is the vacuum annihilated by χk,ir), generates a condensation density given by(9)0θ,tχk,ir†χk,ir0θ,t=sin2θΥkλ2,where λ=B,F. The Bogoliubov coefficient, Υkλ, appearing in the condensates, assumes the following form for bosons and fermions:(10)ΥkB=12Ωk,1Ωk,2-Ωk,2Ωk,1,(11)ΥkF=Ωk,1+m1-Ωk,2+m22Ωk,1Ωk,2Ωk,1+m1Ωk,2+m2k,respectively, where Ωk,i are the energies of the free fields, i=1,2. The other coefficients of the transformations are ΣkB=1+ΥkB2 and ΣkF=1-ΥkF2.
In the following, we use the relation J-1(θ,t)=J†(θ,t)=J(-θ,t) to write(12)0θ,tλ:Tμνλx:0θ,tλ==λ0Jλ-1-θ,t:Tμνλx:Jλ-θ,t0λ.Then, we denote with Θ(-θ,x)=J-1(-θ,t)Θ(x)J(-θ,t) the operators transformed by J(-θ,t). Let us now analyze the contributions induced by the mixing of bosons and of fermions.
(i) Boson Mixing. The energy density and pressure of the vacuum condensate induced by mixed bosons are(13)ρmixB=120:∑iπi2-θ,x+∇→ϕi-θ,x2+mi2ϕi2-θ,x:0;(14)pmixB=0:∑i∂jϕi-θ,x2+12πi2-θ,x-∇→ϕi-θ,x2-mi2ϕi2-θ,x:0,respectively. One can see that the kinetic and gradient terms of the mixed vacuum are equal to zero [41, 42]:(15)0:∑iπi2-θ,x:0=0:∑i∇→ϕi-θ,x2:0=0:∑i∂jϕi-θ,x2:0=0.Therefore, (13) and (14) reduce to(16)ρmixB=-pmixB=0:∑imi2ϕi2-θ,x:0,and the state equation is the ones of the cosmological constant, wmixB=-1. Denoting by K the cut-off on the momenta and by setting Δm2=m22-m12, one has(17)ρmixB=Δm2sin2θ8π2∫0Kdkk21ωk,1-1ωk,2.Such an integral, solved analytically, gives the following results.
(i) For axion-photon mixing, considering magnetic field strength B∈[106–1017]G, axion mass ma≃2×10-2eV, sina2θ~10-2, and a Planck scale cut-off, K~1019GeV, one obtains a value of the energy density ρmixaxion=2.3×10-47GeV4, which is of the same order of the estimated upper bound on the dark energy.
(ii) For the mixing of neutrino superpartners, assuming m1=10-3eV, m2=9×10-3eV, and sin2θ=0.3, one has ρmixB=7×10-47GeV4 for K=10eV. For smaller values of sin2θ, one obtains ρmixB~10-47GeV4 also in the case in which K=1019GeV [41, 42].
(ii) Fermion Mixing. The energy density and pressure of the condensate induced by mixed fermions are (18)ρmixF=-0:∑iψi†-θ,xγ0γj∂jψi-θ,x+mψi†-θ,xγ0ψi-θ,x:0;pmixF=i0:∑iψi†-θ,xγ0γj∂jψi-θ,x:0,where ψi(-θ,x) denote the mixed fields. With the kinetic terms equal to zero, that is,(19)0:∑iψ¯i-θ,xγj∂jψi-θ,x:0=0:∑iψi†-θ,xγ0γj∂jψi-θ,x:0=0,then (18) reduces to(20)ρmixF=-0:∑imiψi†-θ,xγ0ψi-θ,x:0,pmixF=0.Then, the vacuum condensate of fermion mixing behaves as a dark matter component, being wmixF=0. Explicitly, one has(21)ρmixF=Δmsin2θ2π2∫0Kdkk2m2ωk,2-m1ωk,1.By considering mi~10-3eV and K=m1+m2, one has ρmixF=4×10-47GeV4. For Plank scale cut-off, one has ρmixF~×10-46GeV4.
We also note that the condensates of quarks, kaons, and other mesons should not contribute to the dark matter and to the dark energy, since the quarks confinement inhibits other interactions.
5. SUSY Breaking and Vacuum Condensate
Up to now we have analyzed condensed systems in the context of the standard model. Let us now extend our formalism to a supersymmetric framework. We show that the vacuum condensate provides a new mechanism of spontaneous SUSY breaking. To do that, we consider a system in which SUSY is preserved at the Lagrangian level. Then, in order not to break SUSY explicitly, we consider a Bogoliubov transformation which acts simultaneously and with the same parameters on boson and on fermion operators. Such a transformation leads to a vacuum condensate with nonzero energy. In general, a nonzero vacuum energy implies the spontaneous SUSY breaking in any field theory which has manifest supersymmetry at the Lagrangian level [37]. Hence, the nontrivial energy of vacuum condensate breaks SUSY spontaneously.
We consider the Wess–Zumino Lagrangian which is invariant under supersymmetry transformations [71]:(22)L=i2ψ¯γμ∂μψ+12∂μS∂μS+12∂μP∂μP-m2ψ¯ψ-m22S2+P2.Here ψ is a Majorana spinor field, S is a scalar field, and P is a pseudoscalar field. Denoting by αkr, bk, and ck the annihilators for ψ, S, and P, respectively, the vacuum annihilated by such operators is defined as 0=0ψ⊗0S⊗0P. Let us now carry out simultaneous Bogoliubov transformations on fermion and boson annihilators:(23)αkrξ,t=Ukψαkrt+V-kψα-kr†t,(24)bkη,t=UkSbkt-V-kSb-k†t,(25)ckη,t=UkPckt-V-kPc-k†t,where the coefficients for scalar and pseudoscalar fields are equal to each other, UkS=UkP and VkS=VkP. We denote such quantities as UkB and VkB, respectively. The annihilators in (23)–(25) can be expressed as χkrξ,t=J-1ξ,η,tχkrtJξ,η,t, with χk=αk,bk,ck and J(ξ,η,t)=Jψ(ξ,t)JS(η,t)JP(η,t), where Jψ, JS and JP are the generators of transformations (23), (24), and (25), respectively.
The supersymmetric transformed vacuum, which is the physical one, is given by 0ξ,η,t=0ξ,tψ⊗0η,tS⊗0η,tP. Here 0ξ,tψ=Jψ-1(ξ,t)0ψ, 0η,tS=JS-1(η,t)0S, and 0η,tP=JP-1(η,t)0P are the transformed vacua of fermion and boson fields. Then one has 0ξ,η,t=J-1ξ,η,t0. As shown above, the vacua 0ξ,tψ, 0η,tS, and 0η,tP have nontrivial value of their energy density. This fact implies a nonzero energy densities for 0ξ,η,t. Indeed, denoting by H=Hψ+HB (where HB=HS+HP) the free Hamiltonian corresponding to the Lagrangian (22), one has(26)0ξ,η,tHψ0ξ,η,t=-∫d3kωk1-2Vkψ2,0ξ,η,tHB0ξ,η,t=∫d3kωk1+2VkB2.Then the total energy density is(27)0ξ,η,tH0ξ,η,t=2∫d3kωkVkψ2+VkB2,which is different from zero and positive. Such a result holds for all the phenomena characterized by vacuum condensate. Recent experiments on cold atoms-molecules trapped in two-dimensional optical lattices [72] could permit testing the SUSY breaking mechanism here presented [44, 45].
6. Conclusions
We have shown that, in the framework of the standard model of the particles, the vacuum condensates of many systems can contribute to the energy of the universe. In particular, dark matter components can derive by thermal vacuum of intercluster medium, by the vacuum of fields in curved space, and by the neutrino flavor vacuum. On the other hand, the condensate induced by axion-photon mixing can contribute to the dark energy. We have also studied a supersymmetric field theory. In this framework, considering the Wess–Zumino model, we have shown that vacuum condensates may lead to spontaneous SUSY breaking.
Conflicts of Interest
The authors declare that there are no conflicts of interest regarding the publication of this paper.
Acknowledgments
Partial financial support from MIUR and INFN is acknowledged.
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