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Smaalen, Sander van; Daniels, Peter J. L.; Palatinus, Lukáš; Kremer, Reinhard K.

doi:10.1103/physrevb.65.060101

Cited by 19 publications

(30 citation statements)

References 26 publications

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“…The model considered in the present work deals with a single plane, leaving aside the question of charge ordering along the third (stacking) direction. The phase transition in NaV 2 O 5 quadruples the unit cell in the stacking direction, and the recent X-ray experiments, carried out deep in the ordered phase [23,33] revealed peculiar stacking ordering patterns of the super-antiferroelectrically charge-ordered planes. In addition, the pressure can change these patterns and even generate a multitude of higherorder commensurate superstructures in the stacking direction (devil's staircase) [29].…”

Section: Summary and Discussionmentioning

confidence: 99%

“…So ifJ < 1 there are regions of T c where condition (32) is satisfied, then the approximation (33) applies. However at sufficiently low temperatures (T c <J/2) we inevitably enter the other regime (38) where the asymptotics (30,31) change (x < 1 → x > 1), and the function g(T c ) crosses over from (33) to (39). If, on the contrary,J is large, then condition (32) never applies, and the approximation (39) describes the whole region T c < 1/2.…”

Section: Re-entrancementioning

confidence: 99%

“…(33,39) in the both regimes (32,38), the the re-entrant behavior on the phase diagram occurs at any λ = 0.…”

Section: Re-entrancementioning

confidence: 99%

“…Let us point out that the conditions (32,38) determine two different regimes (x < 1 or x > 1) of the asymptotics (30,31) we apply in order to obtain g(T c ) as (33) or (39). So ifJ < 1 there are regions of T c where condition (32) is satisfied, then the approximation (33) applies.…”

Section: Re-entrancementioning

confidence: 99%

“…is defined from the minimum of the function g(T c ) (33). This point corresponds to the critical temperature…”

Section: Re-entrancementioning

confidence: 99%

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Ordering in two-dimensional Ising models with competing interactions

Chitov

Gros

2005

Low Temperature Physics

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We study the 2D Ising model on a square lattice with additional non-equal diagonal next-nearest neighbor interactions. The cases of classical and quantum (transverse) models are considered. Possible phases and their locations in the space of three Ising couplings are analyzed. In particular, incommensurate phases occurring only at non-equal diagonal couplings, are predicted. We also analyze a spin-pseudospin model comprised of the quantum Ising model coupled to XY spin chains in a particular region of interactions, corresponding to the Ising sector's super-antiferromagnetic (SAF) ground state. The spin-SAF transition in the coupled Ising-XY model into a phase with co-existent SAF Ising (pseudospin) long-range order and a spin gap is considered. Along with destruction of the quantum critical point of the Ising sector, the phase digram of the Ising-XY model can also demonstrate a re-entrance of the spin-SAF phase. A detailed study of the latter is presented. The mechanism of the re-entrance, due to interplay of interactions in the coupled model, and the conditions of its appearance are established. Applications of the spin-SAF theory for the transition in the quarter-filled ladder compound NaV2O5 are discussed.

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Section: Summary and Discussionmentioning

confidence: 99%

Section: Re-entrancementioning

confidence: 99%

“…(33,39) in the both regimes (32,38), the the re-entrant behavior on the phase diagram occurs at any λ = 0.…”

Section: Re-entrancementioning

confidence: 99%

Section: Re-entrancementioning

confidence: 99%

“…is defined from the minimum of the function g(T c ) (33). This point corresponds to the critical temperature…”

Section: Re-entrancementioning

confidence: 99%

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Ordering in two-dimensional Ising models with competing interactions

Chitov

Gros

2005

Low Temperature Physics

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Electronic Properties of α-NaV2O2

Gozar

Blumberg²

Frontiers in Magnetic Materials

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1 General properties of α ′ −NaV 2 O 5 and motivation for a spectroscopic study Introduction -α ′ −NaV 2 O 5 is one of the several phases in the class of Na x V 2 O 5 systems [1] and until now it is by far the most studied of them. Since 1996 this compound (denoted in the following simply by NaV 2 O 5 ) has received considerable attention because it was thought to be the second realization, after CuGeO 3 , of a quasi-one dimensional (1D) inorganic material displaying a spin-Peierls (SP) transition. The interest was justified given the scarcity of inorganic materials having this property, which is quite interesting especially for the scientific community working in the field of low dimensional quantum spin systems. However, it turned out that the physics of NaV 2 O 5 is more complicated and intriguing than that and the degrees of freedom involved are not only the ones describing the spins and the lattice.What is a SP transition? We discussed in Chapter [2] the general properties of a Peierls distortion which is a transition to charge density wave state. This means that below some temperature T P the crystal gets distorted and the electronic density acquires a periodic spatial modulation, a process during which the loss in elastic energy is compensated by the gain in the kinetic energy of the electrons. A crucial role is played by the nesting properties of the Fermi surface (i.e. the property that enables one to connect points of the Fermi surface by wavevector characteristic of other excitations, in this case phonons) which makes low dimensional systems especially susceptible to such an instability. A pure SP transition is one in which the lattice distortion is caused by the magneto-elastic coupling, the gain in energy in this case being related to the spin degrees of freedom [3]. In other words, it is a lattice instability driven by the magnetic interactions. This phenomenon leads to the formation of a spin-singlet (S = 0) ground state and the opening of a spin-gap in the magnetic excitation spectrum, i.e. a finite energy is required to excite the system from its ground state to lowest triplet (S = 1) state. A signature of a SP state is thus an isotropic activated temperature dependence in the uniform magnetic susceptibility below the transition at T SP . In addition, as opposed to an usual Peierls transition, the direct participation of the spins leads to specific predictions for the dependence of T SP on external magnetic field H [4]. This has to do with the fact that in the spin case the filling factor of the electronic band and accordingly the magnitude of the nesting wavevectors can be varied continuously by a magnetic field. This statement should not be taken ad litteram, but in the sense that the magnetic problem can be mapped onto a fermion like system by using a transformation of the spin operators, the magnetic field playing the role of the chemical potential, see Refs. [3,4] for more details.So what is the difference between CuGeO 3 and NaV 2 O 5 ? In the former, the SP nature of the transition observe...

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