Bose-Einstein condensation and/or modulation of "displacements" in the two-state Bose-Hubbard model

Bose-Einstein condensation and/or modulation of "displacements" in the two-state Bose-Hubbard model

Instabilities resulting in Bose-Einstein condensation and/or modulation of “displacements” in a system of quantum particles described by a two-state Bose-Hubbard model (with an allowance for the interaction between particle displacements on different lattice sites) are investigated. A possibility o...

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Date:2018
Main Authors: Stasyuk, I.V., Velychko, O.V.
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Language:English
Published: Інститут фізики конденсованих систем НАН України 2018
Series:Condensed Matter Physics
Online Access:https://nasplib.isofts.kiev.ua/handle/123456789/157050
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Cite this:Bose-Einstein condensation and/or modulation of "displacements" in the two-state Bose-Hubbard model / I.V. Stasyuk, O.V. Velychko // Condensed Matter Physics. — 2018. — Т. 21, № 2. — С. 23002: 1–17. — Бібліогр.: 24 назв. — англ.

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spelling nasplib_isofts_kiev_ua-123456789-1570502025-02-09T14:42:05Z Bose-Einstein condensation and/or modulation of "displacements" in the two-state Bose-Hubbard model Бозе-ейнштейнiвська конденсацiя та/або модуляцiя “змiщень” у двостановiй моделi Бозе-Хаббарда Stasyuk, I.V. Velychko, O.V. Instabilities resulting in Bose-Einstein condensation and/or modulation of “displacements” in a system of quantum particles described by a two-state Bose-Hubbard model (with an allowance for the interaction between particle displacements on different lattice sites) are investigated. A possibility of modulation, which doubles the lattice constant, as well as the uniform displacement of particles from equilibrium positions are studied. Conditions for realization of the mentioned instabilities and phase transitions into the SF phase and into the “ordered” phase with frozen displacements are analyzed. The behaviour of order parameters is investigated and phase diagrams of the system are calculated both analytically (ground state) and numerically (at non-zero temperatures). It is revealed that the SF phase can appear as an intermediate one between the normal and “ordered” phases, while a supersolid phase is thermodynamically unstable and does not appear. The relation of the obtained results to the lattices with the double-well local potentials is discussed. Дослiджено нестiйкостi, результатом яких є бозе-конденсацiя та/або модуляцiя “змiщень” у системi квантових частинок, якi описуються двостановою моделлю Бозе-Хаббарда з врахуванням взаємодiї мiж змiщеннями частинок у рiзних вузлах ґратки. Вивчено можливiсть модуляцiї з подвоєнням перiоду ґратки, а також однорiдного змiщення частинок з рiвноважних позицiй. Проаналiзовано умови реалiзацiї згаданих нестiйкостей та фазових переходiв до SF фази та “впорядкованої” фази (зi замороженими змiщеннями), вивчено поведiнку параметрiв порядку та побудовано фазовi дiаграми — як аналiтично (для основного стану), так i числовим способом (при ненульовiй температурi). Показано, що SF фаза може з’явитися як промiжна мiж нормальною та “впорядкованою” фазами, в той час як фаза “суперсолiд” є термодинамiчно нестiйкою i не реалiзується. Обговорено застосовнiсть отриманих результатiв до ґраток з локальними потенцiалами типу подвiйних ям. 2018 Article Bose-Einstein condensation and/or modulation of "displacements" in the two-state Bose-Hubbard model / I.V. Stasyuk, O.V. Velychko // Condensed Matter Physics. — 2018. — Т. 21, № 2. — С. 23002: 1–17. — Бібліогр.: 24 назв. — англ. 1607-324X PACS: 03.75.Hh, 03.75.Lm, 64.70.Tg, 71.35.Lk, 37.10.Jk, 67.85.-d DOI:10.5488/CMP.21.23002 arXiv:1806.09927 https://nasplib.isofts.kiev.ua/handle/123456789/157050 en Condensed Matter Physics application/pdf Інститут фізики конденсованих систем НАН України
institution Digital Library of Periodicals of National Academy of Sciences of Ukraine
collection DSpace DC
language English
description Instabilities resulting in Bose-Einstein condensation and/or modulation of “displacements” in a system of quantum particles described by a two-state Bose-Hubbard model (with an allowance for the interaction between particle displacements on different lattice sites) are investigated. A possibility of modulation, which doubles the lattice constant, as well as the uniform displacement of particles from equilibrium positions are studied. Conditions for realization of the mentioned instabilities and phase transitions into the SF phase and into the “ordered” phase with frozen displacements are analyzed. The behaviour of order parameters is investigated and phase diagrams of the system are calculated both analytically (ground state) and numerically (at non-zero temperatures). It is revealed that the SF phase can appear as an intermediate one between the normal and “ordered” phases, while a supersolid phase is thermodynamically unstable and does not appear. The relation of the obtained results to the lattices with the double-well local potentials is discussed.
format Article
author Stasyuk, I.V.
Velychko, O.V.
spellingShingle Stasyuk, I.V.
Velychko, O.V.
Bose-Einstein condensation and/or modulation of "displacements" in the two-state Bose-Hubbard model
Condensed Matter Physics
author_facet Stasyuk, I.V.
Velychko, O.V.
author_sort Stasyuk, I.V.
title Bose-Einstein condensation and/or modulation of "displacements" in the two-state Bose-Hubbard model
title_short Bose-Einstein condensation and/or modulation of "displacements" in the two-state Bose-Hubbard model
title_full Bose-Einstein condensation and/or modulation of "displacements" in the two-state Bose-Hubbard model
title_fullStr Bose-Einstein condensation and/or modulation of "displacements" in the two-state Bose-Hubbard model
title_full_unstemmed Bose-Einstein condensation and/or modulation of "displacements" in the two-state Bose-Hubbard model
title_sort bose-einstein condensation and/or modulation of "displacements" in the two-state bose-hubbard model
publisher Інститут фізики конденсованих систем НАН України
publishDate 2018
url https://nasplib.isofts.kiev.ua/handle/123456789/157050
citation_txt Bose-Einstein condensation and/or modulation of "displacements" in the two-state Bose-Hubbard model / I.V. Stasyuk, O.V. Velychko // Condensed Matter Physics. — 2018. — Т. 21, № 2. — С. 23002: 1–17. — Бібліогр.: 24 назв. — англ.
series Condensed Matter Physics
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AT velychkoov bozeejnštejnivsʹkakondensaciâtaabomodulâciâzmiŝenʹudvostanovijmodelibozehabbarda
first_indexed 2025-11-26T23:49:30Z
last_indexed 2025-11-26T23:49:30Z
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fulltext Condensed Matter Physics, 2018, Vol. 21, No 2, 23002: 1–17 DOI: 10.5488/CMP.21.23002 http://www.icmp.lviv.ua/journal Bose-Einstein condensation and/or modulation of “displacements” in the two-state Bose-Hubbard model I.V. Stasyuk, O.V. Velychko Institute for Condensed Matter Physics of the National Academy of Sciences of Ukraine, 1 Svientsitskii St., 79011 Lviv, Ukraine Received May 8, 2018 Instabilities resulting in Bose-Einstein condensation and/or modulation of “displacements” in a system of quan- tum particles described by a two-state Bose-Hubbard model (with an allowance for the interaction between particle displacements on different lattice sites) are investigated. A possibility of modulation, which doubles the lattice constant, as well as the uniform displacement of particles from equilibrium positions are studied. Conditions for realization of the mentioned instabilities and phase transitions into the SF phase and into the “ordered” phase with frozen displacements are analyzed. The behaviour of order parameters is investigated and phase diagrams of the system are calculated both analytically (ground state) and numerically (at non-zero temperatures). It is revealed that the SF phase can appear as an intermediate one between the normal and “ordered” phases, while a supersolid phase is thermodynamically unstable and does not appear. The relation of the obtained results to the lattices with the double-well local potentials is discussed. Key words: Bose-Hubbard model, hard-core bosons, Bose-Einstein condensates, phase transition, particle displacements, uniform and modulated ordering PACS: 03.75.Hh, 03.75.Lm, 64.70.Tg, 71.35.Lk, 37.10.Jk, 67.85.-d 1. Introduction Physical properties of the system of ultracold bosonic atoms in optical lattices are intensively studied during the last two decades. Beside a study of thermodynamics and the phase transition to the superfluid (SF) phase for such lattices of different structure and dimensionality, collective phenomena caused by interactions of various type are another matter of interest. Theoretical description is based on the Bose-Hubbard model (BHM) proposed in works [1, 2] and extended by consideration of direct intersite interactions between particles (resulting in the appearance of modulated and separated phases) [3] as well as by taking into account the excited single-site states [4]. The extension of a single-site basis that also takes place in the case of bosons with nonzero spin (e.g., S = 1, [5, 6]) leads to more complex phase diagrams where the phase transition to the superfluid phase can change its order from the second to the first one. However, this transition is dominated by the on-site correlation U of bosons of Hubbard type responsible for a characteristic multilobe shape of phase diagrams (t, µ) [2–7], where t is an energy of the boson hopping between the neighbouring sites, and µ is the boson chemical potential. In the limitU →∞ (corresponding to the case of the so-called hard-core bosons (HCB), i.e., no more than one boson per site, ni 6 1), this theory is applicable to the region where the two above-mentioned lobes connect at T = 0 [8]. Being rather some kind of approximation, the HCB model is still widely exploited for a description of the Bose-Einstein condensate (BEC) in optical lattices (see [9]). Beside ultracold systems, the model is used in the theory of ionic conductors [10], the systems of particles intercalated or adsorbed on the crystal surfaces [11–13], as well as in describing the local electron pairing in the theory of high-temperature superconductors [14]. This work is licensed under a Creative Commons Attribution 4.0 International License . Further distribution of this work must maintain attribution to the author(s) and the published article’s title, journal citation, and DOI. 23002-1 https://doi.org/10.5488/CMP.21.23002 http://www.icmp.lviv.ua/journal http://creativecommons.org/licenses/by/4.0/ I.V. Stasyuk, O.V. Velychko Within the framework of theHCBmodel extended by an allowance for the first excited local vibrational state, we studied a phase transition to the superfluid phase for the case of a particle transfer over the excited states [4]. It was established that this phase transition can be of the first or of the second order; the system can also separate into normal (NO) and superfluid (SF) phases. The study was continued by consideration of non-ergodic effects and their contribution to the momentum distribution of bosonic particles [15]. The above-mentioned two-state HCBmodel was extended by taking into account the displacements of bosonic particles from their equilibrium positions in the optical lattice as well as their intersite interaction leading to the excitations of a phonon type [16]. These excitations are related to transitions between the ground and excited states of bosonic atoms on lattice sites. Calculations of the displacement correlator (the Green’s function 〈〈x̂ | x̂〉〉) determining a static susceptibility of “dipole” type revealed a tendency to the appearance of soft phonon modes and related instabilities with respect to the lowering of an initial symmetry and the transition to the state with “frozen” displacements. The present work is aimed at a detailed study of this problem.Wewill consider the coexistence and the mutual influence of the BEC and the modulation (or the uniform ordering) of the particle displacements. Our description is based on the two-state HCBmodel where the particle transfer occurs between the local ground states (unlike the excited-state transfer considered in [4, 16]). This approach takes into account the peculiarities of boson transfer in the optical lattice with local double-well potentials [17, 18]. Such a lattice is a valuable test bench allowing for an easy tuning of characteristic parameters of the model (e.g., the energy of tunnel splitting in double wells). We will study the thermodynamics of the described system calculating the phase diagrams and establishing the conditions for the phase coexistence. Possible applications of the obtained results beyond the optical lattices will be discussed as well. 2. Model The Hamiltonian of the HCB system on a lattice, in which the two lowest local levels separated by an energy gap δ (δ > 0) are considered only, can be written as Ĥ = Ĥ0 + Ĥ ′ + Ĥ ′′, (2.1) where Ĥ0 = ∑ i j ti jb+i bj + ∑ i j t ′i jc + i cj − µ ∑ i b+i bi + (δ − µ) ∑ i c+i ci is the Hamiltonian of noninteracting bosons consisting of the terms that describe the intersite boson transfer over the ground (ti j) and excited (t ′i j) states, Ĥ ′ = 1 2 ∑ i j Φi j x̂i x̂j (2.2) corresponds to the interaction between particle displacements (relative to their equilibrium positions in the respective lattice sites), Ĥ ′′ = −h ∑ i x̂i (2.3) describes the influence of the external field conjugated to the displacements. Here, x̂i = d(c+i bi + b+i ci), (2.4) where d is a matrix element of the coordinate operator between the ground and excited states, bi (b+i ) and ci (c+i ) are the bosonic destruction (creation) operators in the respective states. The following considerations will be performed in the limit t ′i j → 0, i.e., the particles will transfer over the ground states only. Such an approach corresponds to the case of bosonic particles moving in the lattice formed by double-well potentials (see appendix A). 23002-2 BEC and modulation in the two-state Bose-Hubbard model Due to the chosen HCB limit, the basis of local states |nbi , n c i 〉 is reduced to the three (|0〉 = |00〉, |1〉 = |10〉, |2〉 = |01〉) ones [4]. Thus, in the Hubbard projection operator (X-operator) representation bi = X01 i , ci = X02 i , x̂i = d ( X21 i + X12 i ) ; b+i bi = X11 i , c+i ci = X22 i . (2.5) This results in Ĥ = ∑ i j t ′i jX 10 i X01 j − µ ∑ i X11 i + (δ − µ) ∑ i X22 i + 1 2 ∑ i j Φi jd2 ( X21 i + X12 i ) ( X21 j + X12 j ) − hd ∑ i ( X21 i + X12 i ) . (2.6) Our aim is to study the thermodynamics and equilibrium states of the considered model as well to investigate the phase transitions related to the BEC appearance and the particle displacements from equilibrium positions. The boson transfer and the interaction Φi j are considered in the mean field approximation (MFA): ∑ i j ti jX10 i X01 j → t(0)ξ ∑ i ( X10 i + X01 i ) − Nt(0)ξ2, (2.7) where t(0) = ∑ j ti j , ξ = 〈 X01 i 〉 = 〈 X10 i 〉 (see [4]), and 1 2 ∑ i j Φi j X̂i X̂j → ρΦ(0)d ∑ i ( X12 i + X21 i ) − N 2 Φ(0)ρ2, (2.8) while Φ(0) = ∑ j Φi j , ρ = 〈x̂i〉 = 2d〈X12 i 〉 (here 〈X 12 i 〉 = 〈X 21 i 〉). In this approximation ĤMF = ∑ i Ĥi − Nt(0)ξ2 − N 2 Φ(0)ρ2, (2.9) where Ĥi = t(0)ξ ( X10 i + X01 i ) − µX11 i + (δ − µ)X 22 i + ρΦ(0)d ( X12 i + X21 i ) − hd ( X12 i + X21 i ) . (2.10) Now energies of local bosonic states are determined by the eigenvalues of λα of the matrix | |Ĥi | | = ©­« 0 t(0)ξ 0 t(0)ξ −µ [ρΦ(0) − h]d 0 [ρΦ(0) − h]d δ − µ ª®¬ . (2.11) Correspondingly, the grand canonical potential of the model looks like Ω/N = −t(0)ξ2 − 1 2 Φ(0)ρ2 − Θ ln ( e−βλ1 + e−βλ2 + e−βλ3 ) . (2.12) Order parameters ξ and ρ are established from the self-consistency equations ∂Ω/N ∂ξ = 0, ∂Ω/N ∂ρ = 0. (2.13) They correspond to the absolute minimum of the grand potential at certain values of the chemical potential µ and the field h. In principle, there are phases with ρ = 0 and ξ , 0, ρ , 0 and ξ = 0 as well as ρ , 0 and ξ , 0 (apart from the normal one with ρ = 0 and ξ = 0). At first, we will consider the transitions to the phases with ρ , 0 and ξ , 0 as independent ones. 23002-3 I.V. Stasyuk, O.V. Velychko 3. Phase with ρ , 0 The solution of the equation system (2.13) with ρ , 0 and ξ = 0 describes a phase with uniform spontaneous displacements of particles. In the case of the lattice with local potentials as the double wells, such a solution corresponds to an asymmetric occupation of minima of the well (like a uniform dipole ordering). At ξ = 0, the eigenvalues of the matrix (2.11) are λ1 = 0, λ2,3 = δ 2 − µ ± √ δ2/4 + B2, (3.1) where B = d[ρΦ(0) − h]. The grand canonical potential is Ω/N = 1 2 Φ(0)ρ2 − Θ ln [ 1 + 2 cosh β √ δ2/4 + B2e−β(δ/2−µ) ] , (3.2) the ρ parameter is determined by the second equation from the set (2.13) ρ = − 2 sinh βR · e−β(δ/2−µ) 1 + 2 cosh βR · e−β(δ/2−µ) · Bd R , (3.3) where the notation R = √ δ2/4 + B2 is introduced. At the non-zero field h, there is no a trivial solution ρ = 0 of equation (3.3). Such a solution exists only at h = 0, when other solutions are determined by the equation 1 = − 2 sinh βR0 · e−β(δ/2−µ) 1 + 2 cosh βR0 · e−β(δ/2−µ) · d2Φ(0) R0 , (3.4) where R0 = √ δ2/4 + d2Φ2(0)ρ2. As one can see, this equation can have solutions for ρ atΦ(0) < 0 only. If a conditionΦ(0) > 0 holds, the uniform ordering of displacements 〈x̂0〉 changes into a modulated one. At the interaction limited to the nearest neighbours and to the modulation doubling, a lattice constant (when 〈x̂i〉 is equal to +ρ or −ρ for the first or second sublattices, respectively) an equation analogous to (3.4) has a different sign of the right-hand side (see appendix B). Thus, we can consider a single equation 1 = 2 sinh βR0 · e−β(δ/2−µ) 1 + 2 cosh βR0 · e−β(δ/2−µ) · d2 |Φ(0)| R0 , (3.5) which is valid for the both cases. Solutions of equation (3.5) are calculated numerically, choosing the ones corresponding to the absolute minimum of function (3.2). In the limit of the zero temperature, this task greatly simplifies and is carried out analytically. 3.1. CaseT = 0 At the absolute zero temperature, only the ground state of the system contributes to thermodynamic potential. Depending on the relations between the model parameters, only the single-site states with energies λ1 and λ3 can be the ground ones. In the first case Ω/N = − 1 2 Φ(0)ρ2 + λ1 = − 1 2 Φ(0)ρ2 (3.6) and the equality ρ = 0 follows from conditions (2.13). In this phase, the particles (and, of course, their displacements) are absent. 23002-4 BEC and modulation in the two-state Bose-Hubbard model When the ground state corresponds to the level λ3, Ω/N = − 1 2 Φ(0)ρ2 + δ/2 − µ − √ δ2/4 + B2. (3.7) Based on conditions (2.13), we obtain the following equation for the parameter ρ ρ = − Bd√ δ2/4 + B2 . (3.8) After replacement Φ(0) = −|Φ(0)| [for Φ(0) < 0], this equation can be rewritten as ρ = B̄d√ δ2/4 + B̄2 , (3.9) where B̄ = d[ρ|Φ(0)| + h]. As stated above, the equation also holds in the case Φ(0) > 0. At certain conditions, the ground state can be changed. Based on the equality λ1 = λ3, one can conclude that it takes place at ρ = √ µ(µ − δ) |Φ(0)|d − h |Φ(0)| . (3.10) It follows from formula (3.9) that ρ → ±d at h → ±∞, respectively. On the other hand, the solution of equation (3.9) with respect to h is as follows: h = δ 2d · ρ√ d2 − ρ2 − ρ|Φ(0)|. (3.11) Obviously, at ρ � d h ≈ [ δ 2d2 − |Φ(0)| ] ρ. (3.12) It follows from the above expression that the curve of ρ as a function of h is S-shaped at δ/2 < d2 |Φ(0)| ≡ W, (3.13) defining a condition for the appearance of a spontaneous displacement at h = 0 ρs0 = d √ 1 − δ2 4W2 , (3.14) which can be obtained from (3.9). It describes a state with a uniform or modulated displacement [determined by the sign of Φ(0)] of bosonic particles residing in the lattice sites. It is important that ρs0 is independent of the chemical potential of bosons. Thus, there are two possible phases of the system at T = 0: (1) the phase with ρ = 0 (the ground level is λ1) and (2) the phase with ρ = ρs0 (the ground level is λ3). The transition between them can be investigated by calculation of the grand canonical potential Ω at variation of µ with the constraint λ1 = λ3. Substituting ρ [formula (3.10)] into the expression Ω/N = + 1 2 |Φ(0)|ρ2 + λ1 = − 1 2 |Φ(0)|ρ2 + λ3 , (3.15) we obtain Ω/N = 1 2|Φ(0)| [√ µ(µ − δ) d + h ]2 . (3.16) In particular, at h = 0 Ω/N = µ(µ − δ) 2W . (3.17) 23002-5 I.V. Stasyuk, O.V. Velychko Plots of functions Ω/N �� λ1, h=0 = 0, (3.18a) Ω/N �� λ3, h=0 = − (W − δ/2)2 2W − µ, (3.18b) Ω/N �� λ1=λ3, h=0 = µ(µ − δ) 2W (3.18c) are presented in figure 1. The fishtail shape of the dependence Ω(µ) indicates the first order phase transition between phases ρ = 0 [branch (3.18a)] and ρ , 0 [branch (3.18b)]. The respective points of absolute instability are at µ = δ/2 −W and µ = 0. Branch (3.18c) describes an unstable state. The phase transition occurs at µ = µ1 ≡ − 1 2W ( W − δ 2 )2 . (3.19) The dependence of the order parameter ρ ≡ ρ̃d on the chemical potential of bosons is described at ( c ) ( b ) ( a ) ( W 2− δ2/4) /2W − ( W − δ/2) 2/2W δ/2 − W µ 1 0 µ Ω / N Figure 1. (Colour online) Dependence of the grand canonical potential Ω/N on the chemical potential of bosons µ at T = 0 and t(0) = 0 in the vicinity of a transition to the phase ρ , 0. A phase transition of the first order occurs at µ = µ1. Hereinafter, solid and dashed lines designate stable and metastable states, respectively. ∼ρ ( c ) ( b ) ( a ) ( 1 − δ2/ 4W 2 ) 1/2 δ/2 − W µ 1 0 µ Figure 2. (Colour online) Dependence of the order parameter ρ on the chemical potential of bosons µ at T = 0 and t(0) = 0 in the vicinity of the transition to the phase ρ , 0. 23002-6 BEC and modulation in the two-state Bose-Hubbard model h = 0 by formulae ρ̃ = 0, (3.20a) ρ̃ = √ 1 − δ2 4W2 , (3.20b) ρ̃ = √ µ(µ − δ) W (3.20c) and is presented in figure 2. There is a jump between the values ρ̃ = 0 and ρ̃ = ρs0/d at µ = µ1. This phase transition is accomplished by a jump of the boson concentration n̄B = −∂(Ω/N)/∂µwhen n̄B changes from n̄B = 0 to n̄B = 1 at the rise of µ [as it follows from formulae (3.6) and (3.7)]. 3.2. CaseT , 0 The above considerations are limited to the zero temperature. At T , 0, one should start from the equations (3.3) or (3.5) as well as from the general expression (3.2) for the grand canonical potential Ω and perform numerical calculations. As usual, a spontaneous (i.e., at h = 0) value of the order parameter ρ decreases at the rise of temperature. The phase transition to the NO phase is of the second order. It occurs at the temperature defined by the equation 1 = 2 sinh βδ 2 e−β(δ/2−µ) 1 + 2 cosh βδ 2 e−β(δ/2−µ) · 2W δ , (3.21) which follows from (3.5) in the limit ρ→ 0. The dependences ofΩ and ρ on µ at various temperatures are depicted in figure 3. The corresponding phase diagram (T, µ) shown in figure 4 defines the region of the ρ , 0 phase at a certain relationship between the parameter W (describing the interaction of bosonic displacements) and the energy δ of the excited bosonic state on a lattice site. Figure 4 also demonstrates the spinodal curve where the NO phase reaches an absolute instability [the spinodal is defined by the equality (∂ρ/∂µ)|ρ=0 = ∞]. 4. Phase ξ , 0 Here, we consider the phase transition between the NO and SF (with ξ , 0) phases for the model (2.1) (where bosons transfer through the ground state) assuming its independence of the phase transition with the order parameter ρ. Obviously, it happens in the absence of the interaction of displacementsΦi j . Later on, we will formulate the criterion for such a transition at non-zero values of Φi j . One can separate the part of theHamiltonianwhich is related to theBEC.According to equations (2.10) and (2.11), in the MFA and under conditions ρ = 0 and h = 0, the single-site spectrum of bosons in the SF phase looks as follows: z1,2 = − µ 2 ± √ µ2/4 + t2(0)ξ2, z3 = δ − µ. (4.1) In this case, the grand canonical potential Ω is expressed as Ω/N = −t(0)ξ2 − Θ ln [ e−β(δ−µ) + e βµ 2 · cosh β √ µ2 4 + t2(0)ξ2 ] . (4.2) Thus, taking into account the equilibrium condition (2.13), one can derive the following equation for the BEC order parameter ξ = − sinh β √ µ2/4 + t2(0)ξ2 e−βδeβµ/2 + 2 cosh β √ µ2/4 + t2(0)ξ2 · t(0)ξ√ µ2/4 + t2(0)ξ2 . (4.3) 23002-7 I.V. Stasyuk, O.V. Velychko −1.0 −0.5 0.5 1.0 −0.6 −0.3 0.3 0.6 Θ = 0.05 µ 1 0 µ Ω / N −1.0 −0.5 0.5 1.0 −0.2 0.5 1.2 Θ = 0.05 ∼ρ µ 1 0 µ −1.0 −0.5 0.5 1.0 −0.6 −0.3 0.3 0.6 Θ = 0.2 0 µ Ω / N −1.0 −0.5 0.5 1.0 −0.2 0.5 1.2 Θ = 0.2 ∼ρ 0 µ −1.0 −0.5 0.5 1.0 −0.6 −0.3 0.3 0.6 Θ = 0.4 0 µ Ω / N −1.0 −0.5 0.5 1.0 −0.2 0.5 1.2 Θ = 0.4 ∼ρ 0 µ Figure 3. (Colour online) Dependences of the grand canonical potential Ω/N and the order parameter ρ on the chemical potential of bosons µ at T , 0 (|t(0)| = 0, δ = 0.5 and W = 1). Quantities having a dimension of energy are given in units of W . The above equation is known from the two-state model. It was obtained in a similar form in [4] for the case of the boson transfer through excited states, which corresponds to a different sign of the parameter δ. Equation (4.3) has non-zero solutions at t(0) < 0. At δ > 0, the phase transition to the SF phase is of the second order in the limit T → 0, as demonstrated in [4]. This can be proved by analyzing the ground state of a bosonic system: level z2 is the lowest one for any value of µ. For potential Ω, we have Ω/N = |t(0)|ξ2 − µ/2 − √ µ2/4 + t2(0)ξ2, (4.4) while an equation for a non-zero ξ is reduced to 1 = |t(0)| 2 √ µ2/4 + t2(0)ξ2 . (4.5) 23002-8 BEC and modulation in the two-state Bose-Hubbard model −0.8 −0.6 −0.4 0.0 0.3 0.6 ρ ≠ 0 ρ ≠ 0 N O 1 s t o r d e r P T 2 n d o r d e r P T s p i n o d a l c u r v e Te mp era tur e Θ C h e m i c a l p o t e n t i a l µ Figure 4. (Colour online) The phase diagram (T, µ) in the vicinity of the transition to the phase ρ , 0 at |t(0)| = 0, δ = 0.5 and W = 1. Solid and dashed lines designate phase transition of the first and second order, respectively, while a dotted line corresponds to spinodal. Thus, ξ = 1 2 √ 1 − µ2 t2(0) . (4.6) The above expression demonstrates that the SF phase (ξ , 0) exists in the region −|t(0)| < µ < |t(0)|. Substituting (4.6) into the expression for the grand canonical potential, one can obtain Ω/N =  0, µ < −|t(0)|; −µ, µ > |t(0)|; − 1 4 |t0 | [µ + |t(0)|] 2, −|t(0)| < µ < |t(0)|. (4.7) The derivative ∂ ∂µ (Ω/N) = −n̄B (thus, defining the concentration of bosons) is continuous at points µ = ±|t(0)|. This is an evidence that the transition to the SF phase (ξ , 0) is of the second order (at T = 0). Dependences Ω/N and n̄B on µ are presented in figures 5 and 6, respectively. It should be mentioned that at T , 0, due to a partial occupation of the excited state, the phase transition to the SF phase can change its order from the second to the first one. It takes place at low energies of excitation δ and at intermediate temperatures (this issue is discussed more in detail in [4]). 5. Complete phase diagrams All aforementioned conditions for the appearance of phases with ξ , 0 or ρ , 0 at T = 0 are obtained assuming the phases as mutually exclusive. Such a conjecture is true at Φi j = 0 for the former phase and at ti j = 0 for the latter one. At non-zero parameters Φi j and ti j , the domains of the above-mentioned phases intersect. Only the analysis of the grand potential Ω can detect the thermodynamically stable phases in this case. We have performed numerical calculations based on expression (2.12) with the use of eigenvalues of matrix (2.11) and self-consistency equation (2.13). It is shown that only phases with ξ , 0 or ρ , 0 can be thermodynamically stable while the phase with the both non-zero order parameters (ξ , 0 and ρ , 0) is unstable at any conditions in the considered model. Thus, complete phase diagrams can be built by comparison of the grand canonical potentials for respective phases. 23002-9 I.V. Stasyuk, O.V. Velychko − | t ( 0 ) | − | t ( 0 ) | ( c ) ( b ) ( a ) | t ( 0 ) |0 µ Ω / N Figure 5. (Colour online) Dependence of the grand canonical potential Ω/N on the chemical potential of bosons µ in the vicinity of the transition to the SF phase (ξ , 0) at T = 0 (Φi j = 0). −n B1 | t ( 0 ) |− | t ( 0 ) | ( c ) ( b ) ( a ) 0 µ Figure 6. (Colour online) Dependence of the bosonic occupation number n̄B on the chemical potential of bosons µ in the vicinity of the transition to the SF phase (ξ , 0) at T = 0 (Φi j = 0). At T = 0, the consideration can be performed in an analytical form using formulae (3.18) and (4.7). Plots of appropriate functions are combined in figure 7, where two cases are separated. The first one [figure 7 (a)] realizes at W 2 ( 1 − δ 2W )2 > |t(0)|. (5.1) The phase transition to the ρ phase at an increase of µ takes place prior to the possible appearance of the BEC. The branch Ωξ (corresponding to the state with ξ , 0) has greater values of Ω than the branch Ωρ (corresponding to the state with ρ , 0); hence, the SF phase is unstable. Thus, there are sequentially two phases here: (1) the NO phase (ρ = 0 and ξ = 0) at µ < µ1 and (2) the phase with ρ , 0 at µ > µ1 [µ1 = −W(1 − δ/2W)2/2]. The second case [when condition (5.1) does not hold] corresponds to large values of bosonic transfer |t(0)|. As one can see in figure 7 (b), minimum values of potential Ω are reached on three branches in respective intervals: (1) the branch Ω0 = 0 at µ < −|t(0)| (the NO phase), (2) the branch Ωξ at −|t(0)| < µ < µ∗ (the SF phase with ξ , 0) and (3) the branch Ωρ at µ > µ∗ (the phase with ρ , 0). The intersection of branchesΩξ andΩρ occurs at the chemical potential µ∗ satisfying the following equation − 1 4|t(0)| [µ + |t(0)|]2 = − (W − δ/2)2 2W − µ, (5.2) 23002-10 BEC and modulation in the two-state Bose-Hubbard model Ω / N = −µ Ω ρ Ω ξ Ω 0 | t ( 0 ) | − | t ( 0 ) | ( W 2− δ2/4) /2 W δ/2 − W µ 1 0 µ Ω / N Ω / N = −µ Ω ρ Ω ξ Ω ξ Ω 0 | t ( 0 ) |− | t ( 0 ) | ( W 2− δ2/4) /2 W δ/2 − W µ∗ 0 µ Ω / N Figure 7. (Colour online) Grand canonical potentials Ωρ [formula (3.18)] and Ωξ [formula (4.7)] as functions of the chemical potential of bosons µ at T = 0. On the left: a direct transition between the NO phase and the phase ρ , 0 providing inequality (5.1) is satisfied; on the right: the appearance of the intermediate SF phase (ξ , 0) when this condition is broken. −n B1 | t ( 0 ) |− | t ( 0 ) | µ 1 0 µ µ∗ −n B1 | t ( 0 ) |− | t ( 0 ) | 0 µ Figure 8. (Colour online) The bosonic occupation number n̄B as function of the chemical potential of bosons µ at T = 0. Left-hand and right-hand graphs correspond to the respective plots in figure 7. which gives µ∗ = −|t(0)| − √ 2|t(0)| W (W − δ/2) . (5.3) In this case, the SF phase exists at the rise of µ as an intermediate one prior to the phase with ρ , 0. The phase transition to the SF phase at µ = −|t(0)| is of the second order while the phase transition at µ = µ∗ between the phases with non-zero ξ and ρ is of the first order. In a similar way, if condition (5.1) is fulfilled and the SF phase is absent, then the transition to the ρ phase is of the first order. The behaviour of the boson concentration n̄B in the region of these phase transitions is presented in figures 8 (a) and 8 (b). The phase transition of the first order to the ρ phase is accompanied by a steplike change of n̄B, while n̄B(µ) is a linear function in the SF phase. Such a dependence on µ at T = 0 is characteristic of the SF phase of the BHM [19, 20]. The above considerations are valid at the absolute zero temperature. Numerical calculations prove that at T , 0, the SF phase remains intermediate as in the above discussed case. Phase diagrams (T, µ) at various values of parameter |t(0)| (presented in figure 9) demonstrate a narrowing of the SF region at a decrease of |t(0)|. The achievable maximum temperature of the SF phase also decreases. At |t0 | < |t0 |cr, the SF phase is absent (|t0 |cr ≈ 0.2 at T = 0.1, δ = −0.9, W = 0.8; see the phase diagram (|t0 |, µ) in figure 10). At T , 0, the phase transition between the ξ and ρ phases is also of the first order. At small values of |t(0)|, the phase transition between NO and ρ phases changes its order from the first to the second one at the rise of temperature (figure 9). At large enough values of |t(0)|, this transition is of the second order starting from the triple point where all three phases are in equilibrium. 23002-11 I.V. Stasyuk, O.V. Velychko −2 −1 0 0.0 0.3 0.6 ρ ≠ 0S F N O 1 s t o r d e r P T 2 n d o r d e r P T Te mp era tur e Θ C h e m i c a l p o t e n t i a l µ | t ( 0 ) | = 1 . 0 −2 −1 0 0.0 0.3 0.6 ρ ≠ 0 S F N O 1 s t o r d e r P T 2 n d o r d e r P T Te mp era tur e Θ C h e m i c a l p o t e n t i a l µ | t ( 0 ) | = 0 . 5 −2 −1 0 0.0 0.3 0.6 ρ ≠ 0 S F N O 1 s t o r d e r P T 2 n d o r d e r P T Te mp era tur e Θ C h e m i c a l p o t e n t i a l µ | t ( 0 ) | = 0 . 3 −2 −1 0 0.0 0.3 0.6 ρ ≠ 0 N O 1 s t o r d e r P T 2 n d o r d e r P T Te mp era tur e Θ C h e m i c a l p o t e n t i a l µ | t ( 0 ) | = 0 −2 −1 0 0.0 0.3 0.6 S F N O ρ ≠ 0 1 s t o r d e r P T 2 n d o r d e r P T Te mp era tur e Θ C h e m i c a l p o t e n t i a l µ | t ( 0 ) | = 0 . 1 −1.00 −0.98 −0.96 0.00 0.02 0.04 (∗) ρ ≠ 0 N O S F 1 s t o r d e r P T 2 n d o r d e r P T Te mp era tur e Θ C h e m i c a l p o t e n t i a l µ | t ( 0 ) | = 0 . 1 Figure 9. (Colour online) Phase diagrams (T, µ): regions of the NO phase and phases with ξ , 0 and ρ , 0 at various values of |t(0)| (δ = 0.9, W = 0.8). Designations of phase transition lines are identical to the ones in figure 4. The possibility of the SF phase existence as an intermediate one at the rise of temperature [the vertical line marked (*)] is shown on the last graph. 6. Conclusions Thermodynamics of the lattice bosonic system, studied within the framework of the two-state HCB model, is affected by an intersite interaction, caused by displacements of particles from their equilibrium positions on lattice sites, which can lead to spontaneous symmetry breaking and to the appearance of a phase with uniform or space-modulated displacements. Matrix elements of displacements are related to bosonic transitions between the ground and excited states. Thus, thementioned orderings of displacements are analogous to dipole orderings in ferroelectrics. An intersite particle transfer leads to the instability 23002-12 BEC and modulation in the two-state Bose-Hubbard model −2 −1 0.0 0.5 1.0 N O S F ρ ≠ 0 1 s t o r d e r P T 2 n d o r d e r P T Ho ppi ng ene rgy |t( 0)| C h e m i c a l p o t e n t i a l µ Figure 10. (Colour online) Phase diagram (|t(0)|, µ) at T = 0.1, δ = 0.9 and W = 0.8. Designations of phase transition lines are identical to the ones in figure 4. with respect to the BE condensation that exists in such intervals of the chemical potential of bosons where their concentration is non-integer and varies. Competition between this effect and the tendency to freezing of the displacements affects the shape of phase diagrams defining the regions of the NO phase, the SF phase (ξ , 0) and the phase with spontaneous displacements (ρ , 0). The phase with non-zero values of both order parameters ρ and ξ is unstable, as proved by a numerical analysis of the Ω(µ) dependence. Such a state could be a supersolid phase which is well known from the theory of phase transitions in optical lattices derived within the framework of an extended Bose-Hubbard model with frustration (see, for example, [21]). In particular, our model approach is aimed at optical lattices formed by the system of local double wells. In this case, a decisive contribution is made by the intersite hopping of particles residing in the ground vibrational state. Hence, a “frozen” displacement (when ρ , 0) corresponds to localization in certain minima of the double wells. Such a phenomenon is similar to the ordering of protons in hydrogen bonds in hydrogen-bonded ferroelectric crystals. However, there is a difference: the number of protons in these crystals is constant (one proton per bond). The exception is a crystal with a superprotonic (superionic) phase where the number of virtual H-bonds exceeds the number of protons, so the average bond occupation is fractional (n̄i < 1). The crystals of the M3H(XO4)2 family (where M = Rb, Cs, NH4; X = S, Se), in which in the superprotonic phase n̄i = 1/3, are an example, see [22]. Thus, our model can also be applied to a description of phases with a superprotonic conductivity existing at temperatures higher than the ones characteristic of the ordered phases with an integer occupation per hydrogen bond. A possibility of the above-mentioned scenario is illustrated in figure 9, where at some relations between the model parameters and certain values of the boson chemical potential, the SF phase can appear at intermediate temperatures. It should be mentioned that the model of the (2.1) type, describing the proton ordering as well as superionic transition as a disordering process, was proposed for the mentioned class of crystals and was used for the calculation of proton conductivity [22, 23]. Anyway, this issue calls for a separate and more detailed study. A. Optical lattice with double-well potentials As an example, let us consider an optical lattice with local double-well potentials. For simplicity, the further consideration will be limited to the case of a simple cubic lattice with the lattice constant R0 where double wells are oriented along a certain axis (figure 11). As usual, we assume that bosons residing in 23002-13 I.V. Stasyuk, O.V. Velychko a b a ba b a b a ba b a b a ba b R0 ij ϕ R0 2δ ψ ij' Figure 11. (Colour online) Interaction of bosons in a lattice with local double-well potentials. the lattice potential wells are localized in vibrational states with the lowest energy. For the lattice site i, these states |i, a〉 and |i, b〉 are localized in minima a and b, respectively. We take into account the hopping of bosons between the nearest positions in the lattice: (1) hopping between the minima a and b in a single double well and (2) hopping between neighbour double wells [24]. In the first case, the Hamiltonian for the well on the lattice site i looks as follows: Ĥ0 = Ω(c+iacib + c+ibcia) − µ(c+iacia + c+ibcib), (A.1) where cia(c+ia) and cib(c+ib) are operators of destruction (creation) of bosons in potential minima |i, a〉 and |i, b〉, Ω is the parameter describing the hopping (tunnelling) between them, µ is the chemical potential of bosons. By means of transformation cia = 1 √ 2 (di1 + di2), cib = 1 √ 2 (di1 − di2), (A.2) which is equivalent to the transition from localized states |i, a〉 and |i, b〉 to their symmetric 1 √ 2 (|i, a〉 + |i, b〉) ≡ |i, 1〉 and asymmetric 1 √ 2 (|i, a〉 − |i, b〉) ≡ |i, 2〉 combinations, Hamiltonian (A.1) becomes diagonal: Ĥi = E1d+i1di1 + E2d+i2di2 , (A.3) where E1,2 = ±Ω− µ. At Ω < 0, the ground state is a symmetric one |i, 1〉. Due to tunnelling, the excited state is separated from the ground one by a gap of the width 2|Ω|. 23002-14 BEC and modulation in the two-state Bose-Hubbard model Hopping between adjacent double wells (the second case) is described by the operator Ĥ = ∑( ‖) i j ∑ αβ ϕ αβ i j c+iαcjβ + ∑(⊥) i j ∑ αβ Ψ αβ i j c+iαcjβ , (A.4) where the first and the second terms correspond to a bosonic transfer in the longitudinal (parallel to the orientation of double wells) and transverse directions, respectively (α, β = a, b). When the distance rab between positions (a) and (b) in a potential well is much smaller compared to the distance R0 between the neighbour wells [24], one can perform expansions in terms of the ratio rab/R0. In this way, the hopping parameters are expressed as follows: ϕaaij = ϕ bb ij = ϕ(R0), ϕabij = ϕ ba ij = ϕ(R0) ± ϕ ′(R0) · 2rab; ψaa ij = ψ bb ij = ψ(R0), ψab ij = ψ ba ij = ψ(R0) + ψ ′(R0) · 2r2 ab R0 . (A.5) In terms of operators di1 and di2, the Hamiltonian (A.4) written down as Ĥ = Ĥ‖ + Ĥ⊥, looks as follows: Ĥ‖ = ∑( ‖) i< j [ 2ϕ(R0)d+i1dj1 − ϕ ′(R0)2rab · d+i1dj2 + ϕ ′(R0)2rab · d+i2dj1 ] + h.c. , (A.6) Ĥ⊥ = ∑(⊥) i j {[ 2ψ(R0) + ψ ′(R0) · 2r2 ab R0 ] d+i1dj1 − ψ ′(R0) · 2r2 ab R0 d+i2dj2 } + h.c. . (A.7) At a small ratio rab/R0, the major contribution is made by hopping between symmetric states. The corrections start in the MFA from the second order (linear corrections mutually compensate). Neglecting the terms of the second (and higher) order, the bosonic transfer is described by the Hamiltonian Ĥ‖ + Ĥ⊥ = ∑( ‖) i j t ‖i jd + i1dj1 + ∑(⊥) i j t+i jd + i1dj1. (A.8) Let us take t ‖i j = t⊥i j ≡ ti j , having in mind that the effects of local anisotropy are negligibly small [ϕ(R0) ≈ ψ(R0)]. As a result, we obtain the Hamiltonian of a two-state model Ĥ = Ω ∑ i ( d+i1di1 − d+i2di2 ) − µ ∑ i ( d+i1di1 + d+i2di2 ) + ∑ i j ti jd+i1dj1 , (A.9) where the transfer occurs over the ground states, and a − 2|Ω| = δ corresponds to the excitation energy (the energy difference between the excited and ground states of a site). After the substitution µ→ µ−δ/2, operator (A.8) transforms to Hamiltonian (2.1). B. State with modulation of displacements To describe the modulation with a doubled lattice constant, it is convenient to divide the initial lattice into two sublattices. Let us put 〈x̂i1〉 = ρ1 , 〈x̂i2〉 = ρ2 (B.1) for the first and second of them, respectively. If the intersite interaction between displacements Φi j is considered in the MFA, an external field is absent and ti j → 0, then the Hamiltonian can be written down as follows: Ĥ = ∑ i1 Ĥi1 + ∑ i2 Ĥi2 − N 2 φ(0)ρ1ρ2 , (B.2) where Ĥi1 = −µX11 i1 + (δ − µ)X22 i1 + ρ2Φ(0)d ( X12 i1 + X21 i1 ) , Ĥi2 = −µX11 i2 + (δ − µ)X22 i2 + ρ1Φ(0)d ( X12 i2 + X21 i2 ) . (B.3) 23002-15 I.V. Stasyuk, O.V. Velychko Eigenvalues of operators (B.3) acting on the basis of states |0〉, |1〉 and |2〉 look as follows: λ (1,2) 1 = 0, λ (1,2) 2 = δ 2 − µ + √ δ2/4 + B2 (2,1) , λ (1,2) 3 = δ 2 − µ − √ δ2/4 + B2 (2,1) , (B.4) with B1 = ρ1Φ(0)d, B2 = ρ2Φ(0)d. (B.5) In this case, the grand canonical potential is given by the expression Ω/N = − 1 2 Φ(0)ρ1ρ2 − Θ 2 [ 1 + 2 cosh β √ δ2/4 + B2 1 · e −β( δ2 −µ) ] − Θ 2 ln [ 1 + 2 cosh β √ δ2/4 + B2 2 · e −β( δ2 −µ) ] (B.6) (it is taken into account that the number of sites in the sublattice is equal to N/2). 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Phys., 2001, 114, No. 10, 4607–4617, doi:10.1063/1.1348030. 24. Trotzky S., Cheinet P., Fölling S., Feld M., Schnorrberger U., Rey A.M., Polkovnikov A., Demler E.A., Lukin M.D., Bloch I., Science, 2008, 319, 295–299, doi:10.1126/science.1150841. Бозе-ейнштейнiвська конденсацiя та/або модуляцiя “змiщень” у двостановiй моделi Бозе-Хаббарда I.В. Стасюк, О.В. Величко Iнститут фiзики конденсованих систем НАН України, вул. Свєнцiцького, 1, 79011 Львiв, Україна Дослiджено нестiйкостi, результатом яких є бозе-конденсацiя та/або модуляцiя “змiщень” у системi кван- тових частинок, якi описуються двостановою моделлю Бозе-Хаббарда з врахуванням взаємодiї мiж змi- щеннями частинок у рiзних вузлах ґратки. Вивчено можливiсть модуляцiї з подвоєнням перiоду ґратки, а також однорiдного змiщення частинок з рiвноважних позицiй. Проаналiзовано умови реалiзацiї згаданих нестiйкостей та фазових переходiв до SF фази та “впорядкованої” фази (зi замороженими змiщеннями), вивчено поведiнку параметрiв порядку та побудовано фазовi дiаграми — як аналiтично (для основного стану), так i числовим способом (при ненульовiй температурi). Показано, що SF фаза може з’явитися як промiжна мiж нормальною та “впорядкованою” фазами, в той час як фаза “суперсолiд” є термодинамiчно нестiйкою i не реалiзується. Обговорено застосовнiсть отриманих результатiв до ґраток з локальними потенцiалами типу подвiйних ям. Ключовi слова: модель Бозе-Хаббарда, жорсткi бозони, бозе-конденсат, фазовий перехiд, змiщення частинок, однорiдне та модульоване впорядкування 23002-17 https://doi.org/10.1103/RevModPhys.62.113 https://doi.org/10.5488/CMP.15.33002 https://doi.org/10.5488/CMP.18.43004 https://doi.org/10.1103/PhysRevLett.95.010402 https://doi.org/10.1103/PhysRevA.76.043606 https://doi.org/10.1209/0295-5075/22/4/004 https://doi.org/10.1103/PhysRevB.77.014503 https://doi.org/10.1103/PhysRevB.88.174515 https://doi.org/10.1080/01411599708220065 https://doi.org/10.1063/1.1348030 https://doi.org/10.1126/science.1150841 Introduction Model Phase with 0 Case T=0 Case T0 Phase 0 Complete phase diagrams Conclusions Optical lattice with double-well potentials State with modulation of displacements

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