The presence of the Aharonov-Anandan invariant in phenomena in which vacuum condensates are physically relevant can help to reveal the spontaneous supersymmetry breaking induced by condensates. The analysis is presented in the case of the Wess-Zumino model. The manifestation of the Aharonov-Anandan invariant of atoms and their superpartners, generated at nonzero temperature, could reveal the signature of SUSY violation in a recently proposed experimental setup based on an optical lattice in which SUSY is broken at non-zero temperature.
1. Introduction
The idea of supersymmetry (SUSY) had a huge impact on physics in the past years, and much of the research has been geared at the detection of the superpartners, which according to SUSY are associated with the ordinary particles we know. However, no evidence of the existence of superpartners has been obtained till now. The fact that the superpartners are not degenerated with ordinary particles at the scales we can currently probe means that if SUSY exists as a fundamental symmetry, it must be spontaneously broken. As a consequence, a large part of the research activity has been devoted to the study of SUSY breaking.
It has been recently shown [1] that in several phenomena in a supersymmetric context, with particular reference to the free Wess-Zumino model [2], SUSY is broken by the vacuum condensate shifting the vacuum energy density to a nonzero value. Examples include QFT in external fields, like Unruh [3] and Schwinger effects [4], condensed matter physics, such as discussed in connection with BCS theory of superconductivity [5], graphene physics [6] and Thermo Field Dynamics [7–9], particle physics and cosmology, flavor mixing (see, e.g., [10, 11] and refs. therein cited), quantization of dissipative systems [12], and dark energy [13, 14] even though the dark energy problem is far from being settled. In all these cases, vacuum condensates can be effectively described by using Bogoliubov transformations.
On the other hand, the presence of Aharonov-Anandan invariant (AAI) [15] has been revealed to be an interesting feature in the study of phenomena characterized by a vacuum condensate [16].
In this paper, we show that in a supersymmetric context, the AAI could represent a valid instrument to reveal the SUSY violation induced by condensates.
In the following we summarize the main results of [1] and then we show that SUSY breaking could be revealed by means of AAIs.
2. Vacuum Condensate and SUSY Breaking
We consider, for simplicity, the free Wess-Zumino model Lagrangian [2] which is invariant under SUSY. This leads us to the qualitative understanding of the SUSY breaking in more complicated systems.
In order not to break SUSY explicitly, we study the vacuum condensation induced by Bogoliubov transformations acting simultaneously and with the same parameters on the bosonic and the fermionic degrees of freedom. The condensate shifts the vacuum energy density to a nonvanishing value, and, as well known, this is a sufficient condition for the spontaneous breaking of SUSY to occur [17].
The Lagrangian of the free Wess-Zumino model is given by
(1)ℒ=i2ψ-γμ∂μψ+12∂μS∂μS+12∂μP∂μP-m2ψ-ψ-m22(S2+P2),
where ψ is a Majorana spinor field, S is a scalar field, and P is a pseudoscalar field. This Lagrangian is invariant under supersymmetry transformations [2]. Let αkr, bk, and ck denote the annihilation operators of the quantized fields ψ, S, and P, respectively, which annihilate the vacuum |0〉≡|0〉ψ⊗|0〉S⊗|0〉P. Consider then the Bogoliubov transformations of the ladder operators corresponding to all three fields. In full generality, we consider time-dependent Bogoliubov transformations (their specific nature is dictated by the physical phenomena and system under study):
(2)α~kr(ξ,t)=Ukψ(ξ,t)αkr(t)+V-kψ(ξ,t)α-kr†(t),b~k(η,t)=UkS(η,t)bk(t)-V-kS(η,t)b-k†(t),c~k(η,t)=UkP(η,t)ck(t)-V-kP(η,t)c-k†(t),
where the coefficients of scalar and pseudoscalar bosons are the same, UkS=UkP and VkS=VkP. Denote them by UkB and VkB, respectively. We do not specify further the explicit form of these coefficients Uk and Vk except for the fact that Uk=U-k and Vk=±V-k, with ± for bosons and fermions, respectively, and they satisfy the relation |UkB|2-|VkB|2=1 for (boson) S and P, and |Ukψ|2+|Vkψ|2=1 for (fermion) ψ, which guarantees that the transformations are canonical. For notational simplicity, we write Ukψ≡Ukψ(ξ,t), UkB≡UkB(η,t), and so forth.
At any given time t, the transformations (2) can be written as α~kr(ξ,t)=J-1(ξ,t)αkr(t)J(ξ,t), and similar relations for the other operators. We do not report here the explicit form of the generators Js since it does not affect our discussion (it is given, e.g., in [1]). The operators α~kr(ξ,t), b~k(η,t), and c~k(η,t) annihilate the (tensor product) vacuum
(3)|0~(ξ,η,t)〉≡|0~(ξ,t)〉ψ⊗|0~(η,t)〉S⊗|0~(η,t)〉P,
where |0~(ξ,t)〉ψ=Jψ-1(ξ,t)|0〉ψ, |0~(η,t)〉S=JS-1(η,t)|0〉S, and |0~(η,t)〉P=JP-1(η,t)|0〉P, with obvious notation for the Jψ, JS, and JP generators. We write in a compact notation |0~(t)〉≡|0~(ξ,η,t)〉=J-1(ξ,η,t)|0〉.
In a similar way, the Bogoliubov transformed state of the original |ϕk〉≡|ψk〉⊗|Sk〉⊗|Pk〉 is given by
(4)|ϕ~k(ξ,η,t)〉WZ=|ψ~k(ξ,t)〉⊗|S~k(η,t)〉⊗|P~k(η,t)〉,
where the transformed fermion and boson states are |ψ~k(ξ,t)〉=α~kr†(ξ,t)|0~(ξ,t)〉ψ=Jψ-1(ξ,t)|ψk〉, |S~k(η,t)〉=b~k†(ξ,t)|0~(ξ,t)〉S=JS-1(η,t)|Sk〉, and |P~k(η,t)〉=c~k†(η,t)|0~(η,t)〉P=JP-1(η,t)|Pk〉. For notational simplicity, we will use |ϕ~k(t)〉WZ≡|ϕ~k(ξ,η,t)〉WZ=J-1(ξ,η,t)|ϕk〉.
The generators Js are unitary operators if k assumes a discrete range of values; the Fock spaces built on the states |0〉 and |0~(t)〉 are then unitarily equivalent. On the other hand, in the k continuous limit, that is, in QFT, the Js are not unitary operators [7]. This implies that |0~(t)〉 cannot be expressed as a superposition of states belonging to the Fock space built over |0〉. Rather, this last one and the Fock space generated by repeated applications of α~kr†(ξ,t), b~†k(η,t) and c~k†(η,t) over |0~(t)〉 are unitarily inequivalent, and therefore physically different state spaces.
When one considers systems characterized by the presence of condensates, such as those mentioned above [3–5, 7, 12], the state |0~(t)〉 is then the relevant physical vacuum with the nontrivial structure of a condensate [1] responsible of its non-zero energy density and of the appearance of the AAIs [16].
Let H=HB+Hψ and denote the free Hamiltonian corresponding to the Lagrangian (1) by HB=HS+HP. One finds 〈0~(t)|HB|0~(t)〉=∑kωk(1+2|VkB(η,t)|2) for bosons and 〈0~(t)|Hψ|0~(t)〉=-∑kωk(1-2|Vkψ(ξ,t)|2) for fermions, and the expectation value of H on |0~(t)〉 is nonvanishing and positive and represents the background noise [1]
(5)〈0~(t)|H|0~(t)〉=2∑kωk(|VkB(η,t)|2+|Vkψ(ξ,t)|2),
which implies the spontaneous breakdown of SUSY [1]. The physical system under study determines the symmetry breakdown conditions through the Bogoliubov coefficients VkB and Vkψ. Their physical meaning in turn depends on the specific meaning attached to the Bogoliubov transformation parameters. For example, in the case of thermal field theories (e.g., in the Thermo Field Dynamics formalism), the transformation parameters are related to temperature, the physical vacuum is the thermal one, and the result is that SUSY is spontaneously broken at any nonzero temperature, as it is well known [18, 19].
3. SUSY Breaking and Aharonov-Anandan Invariant
The systems in which the vacuum condensate are physically relevant and also have the common characteristic of an AAI [15] in their time evolution [16]. Such an invariant could be used as a tool to reveal the SUSY breakdown. In general, to generate an AAI in the evolution of a state |χk(t)〉, it is necessary and sufficient that its energy uncertainty ΔEk2(t)=〈χk(t)|H2|χk(t)〉-(〈χk(t)|H|χk(t)〉)2 be nonvanishing, which happens, indeed, in the cases considered above [3–12]. The Aharonov-Anandan invariant is then defined as Sk=(2/ħ)∫0tΔEk(t′)dt′.
For each of the neutral scalar and fermion fields we refer to, for example in (4), the energy variances because the Bogoliubov coefficients are ΔEkS(t)=ΔEkP(t)=2ωk|UkB(η,t)||VkB(η,t)| and ΔEkψ(t)=ωk|Ukψ(η,t)||Vkψ(η,t)|, respectively. The corresponding AAIs are then
(6)SkS(t)=SkP(t)=22∫0tωk|UkB(η,t′)||VkB(η,t′)|dt′,
for scalar and pseudoscalar bosons and
(7)Skψ(t)=2∫0tωk|Ukψ(ξ,t′)||Vkψ(ξ,t′)|dt′,
for Majorana fermion field.
In the case of the free Wess-Zumino model, the AAI associated to the Bogoliubov transformed state |ϕ~k(ξ,η,t)〉WZ (see (4)) is then
(8)SkWZ(t)=2∫0tωk×4|UkB(η,t′)|2|VkB(η,t′)|2+|Ukψ(ξ,t′)|2|Vkψ(ξ,t′)|2dt′.
The non-vanishing value of SkWZ(t) is due to the presence of the condensates and controlled by the Bogoliubov coefficients responsible of the SUSY breakdown. We thus see that in the presence of a condensate, the invariant SkWZ(t) signals SUSY breakdown. SkWZ(t) is indeed zero when the condensates disappear (SUSY restoration).
These results apply to any phenomena in which condensates are present. To our knowledge, the only system that deserves a separate discussion is the particle mixing phenomenon. Although spontaneous breakdown of SUSY is present in the field mixing [20, 21], it would be hardly revealed through an AAI measurement. It is so because here the AAI arises as an effect of the mixing of fields with the addition of a small contribution due to the condensate structure [22, 23]. Since this last one is not affecting much the value of the AAI, the SUSY breaking is difficult to be revealed. In the other systems above considered, on the contrary, the AAI is solely due to the condensate contribution. This fact makes the difference between these last cases and the field mixing.
We now analyze the specific case of thermal states and propose a possible experiment to detect SUSY violation with AAI.
4. Aharonov-Anandan Invariant and Thermal State
In the Thermo Field Dynamics formalism [7], one can show that the thermal vacuum is a condensate generated through Bogoliubov transformations whose parameter is related to temperature. We refer for details to the existing literature, see, for example, [7]. Here, we only recall that the Bogoliubov coefficients U and V are real and given by Uk(θ)=eβħωk/(eβħωk±1) and Vk(θ)=1/(eβħωk±1), with − for bosons and + for fermions, and β=1/kBT.
The uncertainties in the energy of the temperature dependent state |ϕ~k(θ)〉≡αk†(θ)|0(θ)〉, with θ≡(θ,t), are given by
(9)ΔEkS(θ)=ΔEkP(θ)=2ħωkUkB(θ)VkB(θ)=2ħωkeβħωk/2(eβħωk-1),
for bosons, and
(10)ΔEkψ(θ)=ħωkUkψ(θ)Vkψ(θ)=ħωkeβħωk/2(eβħωk+1),
for the Majorana fermion field. The corresponding AAIs are
(11)SkS(θ,t)=SkP(θ,t)=22ωkteβħωk/2eβħωk-1,Skψ(θ,t)=2ωkteβħωk/2eβħωk+1.
In the supersymmetric model, at T≠0, SUSY is always broken, and the masses are thermally renormalized [24–26] assuming different values for the fields ψ, S, and P; that is, mψ≠mP≠mS. The dispersion relations for the three particles are different, and then three different AAIs arise for ψ, S, and P fields, Skψ≠SkS≠SkP. On the contrary, at T=0, the AAIs are vanishing, Sk,T=0ψ=Sk,T=0S=Sk,T=0P=0, since the Bogoliubov coefficients are zero and, as well known, SUSY is preserved.
The presence of the AAI for finite temperature systems signals SUSY breakdown. An experiment has been proposed recently in which the Wess-Zumino model in 2+1 dimensions can emerge from a mixture of cold atoms and molecules trapped in two-dimensional optical lattices [27]. In this system the superpartner of the fermion atom is represented by a bosonic diatomic molecule and SUSY is preserved at zero temperature. At non-zero temperature SUSY is broken, and a signature of such a violations can be probed by detecting a thermal Goldstone fermion, the phonino. The detection of such a particle is complicated. However, inspired by the method of [27], in order to partially bypass such difficulties, we propose to construct an experimental setup as follows. Our setting is aimed to detect the AAIs and behaves like an interferometer where the AAI results from the different temperature properties of two similar atom-molecule systems. In other words, the apparatus provides the measure of the difference between the geometric invariants of two mixtures of cold atoms and molecules trapped in two coplanar, two-dimensional optical lattices, one at temperature T≠0 and the other one at T=0. These lattices are moved along the direction perpendicular to the common lattice plane. The part of the apparatus relative to the lattice at T≠0 has non-vanishing invariant
(12)SkWZ(θ,t)=2ωkt[3+5cosh(βħωk)]csch2(βħωk).
The other one, at T=0, has Sk,T=0WZ=0. Use of such an experimental setup could lead to plots similar to the ones theoretically obtained in Figures 1, 2, and 3. These are derived by computing the AAIs versus the excitation energy for different temperatures of the condensate. In particular, we have considered atomic excitation frequencies characteristic of Bose-Einstein condensate of order of 2×104s-1–105s-1 and temperatures of the condensate of the order of (20–200)nK. For simplicity, we considered the case of equal masses of fermion and boson fields, mψ=mP=mS, which happens in the massless version of Wess-Zumino model also presented in [27]. In this case, the AAIs for scalar and pseudoscalar fields are the same, SkP=SkS. The generalization to the massive Wess-Zumino model is straightforward. We find that, in principle, the invariants reported in the previous pictures are all detectable.
Plots of AAI for bosons, SkP as a function of temperature T, for a time interval t=4×2π/ω and for sample values of ω∈[2×104s-1,105s-1], ω=2×104s-1 (gray solid line), ω=4×104s-1 (black dotted line), ω=6×104s-1 (red dot-dashed line), ω=8×104s-1 (blue dashed line), ω=105s-1 (brown solid line). We consider the massless case, and we assume that SkP=SkS. We neglect time dependence of T.
Plots of AAI for fermions, Skψ as a function of temperature T, for the same time interval and sample values of ω as in Figure 1.
Plots of the total AAI induced by SUSY breaking, SkWZ as a function of temperature T, for the same time interval and sample values of ω as in Figures 1 and 2.
From Figure 2, we see that the fermionic AAI shows a plateau at higher values of the temperature parameter. On the other hand, at high temperature (above ≈200nK) also the condensate is expected to disappear (and with it the AAI vanishes).
Finally, we note that also in the supersymmetric context with a condensate, the noise does not affect AAIs, as happens for any system which presents a condensate structure [16]. Let us demonstrate that for the supersymmetric state given in (4).
In the case of free Wess-Zumino model, the background noise is due to the nonzero energy of the physical vacuum as shown in (5). This contribution responsible of the SUSY breaking is, in general, a c-number. For example, in the particular case of the two-dimensional optical lattice of cold atoms and molecules, simulating the massless Wess-Zumino model, the thermal noise is a constant given by 〈0~(t)|H|0~(t)〉=14πζ(3)T3.
As well known, a c-number does not modify the uncertainty ΔEk(t) in the energy of the system; thus, the background noise does not modify the AAI. Indeed, let us denote the noise with Λ=〈0~(t)|H|0~(t)〉 and take into account also Λ in the computation of the uncertainty in the energy. For the Bogoliubov transformed state |ϕ~k(t)〉WZ (4), it is immediate to verify that ΔEk(t) is invariant under the translation H→H+Λ:
(13)ΔEk2(t)=jWZ〈ϕ~k(t)|(H+Λ)2|ϕ~k(t)〉WZ-(yWZ〈ϕ~k(t)|(H+Λ)|ϕ~k(t)〉WZ)2=jWZ〈ϕ~k(t)|H2|ϕ~k(t)〉WZ-(yWZ〈ϕ~k(t)|(H)|ϕ~k(t)〉WZ)2.
This fact leaves unchanged the AAI (up to temperatures above which the AAI does not disappear by itself, as commented above). Note that, on the contrary, the noise affects Berry-like phases since Λ contributes to the value of the Hamiltonian for the system evolution.
5. Conclusion
we have shown that, in a supersymmetric field theory model, the SUSY spontaneous breakdown induced in different phenomena by the vacuum condensates can be revealed by the AAI. The breakdown of SUSY due to the non-zero energy of the vacuum condensate is indeed related to the Bogoliubov coefficients which also appear in the AAI. The analysis is presented in the case of the Wess-Zumino model and might be exploited in a recently proposed experimental setup based on optical lattices in which SUSY is broken at non-zero temperature. Indeed, the difference of the geometric invariants between the AAIs of a system in a thermal bath and one at zero temperature signals SUSY breaking in such a system.
Conflict of Interests
The authors declare that there is no conflict of interests regarding the publication of this paper.
Acknowledgments
Partial financial support from MIUR and INFN is acknowledged.
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