Exact low-temperature behavior of a kagomé antiferromagnet at high fields

Zhitomirsky, M. E.; Tsunetsugu, Hirokazu

doi:10.1103/physrevb.70.100403

Cited by 166 publications

(347 citation statements)

References 22 publications

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“…A similar jump is known to occur in several cases. 11,[47][48][49] Regarding the existence or the absence of the degeneracy, this behavior is different from the magnetization jump observed in square-kagome-lattice and Cairo-pentagon-lattice antiferromagnets, and so on. [50][51][52][53] Although this behavior occurs irrespective of the value of S, the skip of m at the jump gradually decreases as S is increased.…”

mentioning

confidence: 71%

Magnetization Process of the Spin-S Kagome-Lattice Heisenberg Antiferromagnet

Nakano

Sakai

2015

J. Phys. Soc. Jpn.

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The magnetization process of the spin-S Heisenberg antiferromagnet on the kagome lattice is studied by the numerical-diagonalization method. Our numerical-diagonalization data for small finite-size clusters with S = 1, 3/2, 2, and 5/2 suggest that a magnetization plateau appears at one-third of the height of the saturation in the magnetization process irrespective of S. We discuss the S dependences of the edge fields and the width of the plateau in comparison with recent results obtained by real-space perturbation theory.Frustrated spin systems have attracted much attention from many condensed-matter physicists. One of the fascinating systems among them is the kagome-lattice Heisenberg antiferromagnet. Unfortunately, our understanding of this system is still far from complete in spite of many experimental and theoretical studies. In the S = 1/2 system, in particular, discoveries of several realistic materials such as herbertsmithite, 1, 2 volborthite, 3, 4 and vesignieite 5, 6 have accelerated theoretical studies. 7-29 However, there remain some unresolved issues; one of them is the spin-gap problem of whether the spin excitation above the singlet ground state is gapped or gapless.On the other hand, fewer studies on S > 1/2 cases have been carried out. As candidate S = 1 kagome-lattice systems, m-MPYNM·BF 4 , 30, 31, 33 and KV 3 Ge 2 O 9 34 are known. Theoretical studies 9, 35-39 for the S = 1 case are also limited. Studies on the S > 1 cases have only started recently; candidate kagome-lattice systems of Cs 2 Mn 3 LiF 12 40 for S = 2 and NaBa 2 Mn 3 F 11 41 for S = 5/2 have been reported, together with theoretical studies 42-44 as well as an analysis based on the semiclassical limit. 13 Under these circumstances, then, we are faced with a question: do any systematic behaviors exist in the spin-S kagome-lattice Heisenberg antiferromagnet under magnetic fields? The purpose of this letter is to extract such systematic behavior of the magnetization processes of this model for various S by numerical-diagonalization calculations that are unbiased against approximations. With the same motivation, Zhitomirsky recently investigated the frustrated Heisenberg model under magnetic fields by real-space perturbation theory taking into account fluctuations around a classical configuration. 44 He found that in the magnetization process of the kagome-lattice antiferromagnet, the so-called uud state is stable at one-third of the height of the saturation, at which a magnetization plateau appears irrespective of the value of S. He also derived an expression for the 1/S expansion for both the edge fields of this height. The comparison between the * E-mail: hnakano@sci.u-hyogo.ac.jp † present numerical-diagonalization results and the results from real-space perturbation theory should contribute to our understanding of the frustration effect in the kagome-lattice antiferromagnet.The Hamiltonian that we study in this research is given by H = H 0 + H Zeeman , whereandHere, S i denotes the spin operator at site i, where the sites are th...

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mentioning

confidence: 71%

Magnetization Process of the Spin-S Kagome-Lattice Heisenberg Antiferromagnet

Nakano

Sakai

2015

J. Phys. Soc. Jpn.

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“…[11]) and perform exact-diagonalization calculations [12] to obtain thermodynamic quantities. Then we compare these findings with the results of the exact-diagonalization study of the corresponding effective model (2) of N = 12 sites. For concreteness, we fix the set of parameters as follows: J 2 = 5 and J 1 = 1.1, J X = 0.9.…”

Section: Magnetothermodynamics Exact Diagonalization and Quantum Monmentioning

confidence: 89%

“…We begin with testing the accuracy of the effectivemodel description (2). To this end, we consider the full initial model (1) on a finite bilayer lattice of N = 24 sites (see Fig.…”

Section: Magnetothermodynamics Exact Diagonalization and Quantum Monmentioning

confidence: 99%

“…On the other hand, there are a few theoretical papers considering the ground-state and low-temperature properties of a Heisenberg antiferromagnet on a frustrated bilayer honeycomb lattice [9][10][11], in which classical spin [9] or quantum spin-1 2 [10,11] models in nonzero [9,11] or zero [10] magnetic field were discussed using various complementary approaches. In particular, in our recent work [11] it has been shown that the localized-magnon picture [1][2][3], which emerges for the ideal frustration case, yields a simple effective description of the low-temperature thermodynamics in a moderate and strong magnetic field. Since in this regime only the two states on each vertical bond J 2 , |u = | ↑↑ and |d = 1 √ 2 (| ↑↓ − | ↓↑ ) (localized magnon), dominate thermodynamic properties, it is not astonishing that the effective model is an antiferromagnetic honeycomb-lattice Ising model in a uniform magnetic field with the Hamiltonian operators are defined as follows: T z = 1 2 (|u u| − |d d|), T + = |u d|, and T − = |d u|.…”

Section: Introductionmentioning

confidence: 99%

“…We are interested in the regime when J 2 is the strongest bond and a deviation of J X from J 1 is small, or, more precisely, J 2 > 3J with J = (J 1 + J X )/2 and |J 1 − J X |/J 2 ≪ 1. If J 1 = J X one faces the so-called ideal frustration case characterized by a flat-one magnon band [1][2][3], otherwise the system is slightly away from the ideal frustration region in the parameter space.…”

Section: Introductionmentioning

confidence: 99%

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Frustrated honeycomb-lattice bilayer quantum antiferromagnet in a magnetic field

Krokhmalskii

Baliha

Derzhko

et al. 2018

Physica B: Condensed Matter

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Frustrated bilayer quantum magnets have attracted attention as flat-band spin systems with unconventional thermodynamic properties. We study the low-temperature properties of a frustrated honeycomb-lattice bilayer spin-1 2 isotropic (XXX) Heisenberg antiferromagnet in a magnetic field by means of an effective low-energy theory using exact diagonalizations and quantum Monte Carlo simulations. Our main focus is on the magnetization curve and the temperature dependence of the specific heat indicating a finite-temperature phase transition in high magnetic fields.

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Structural distortions of frustrated quantum spin lattices in high magnetic fields

Derzhko

Richter²,

Schulenburg

2005

Physica Status Solidi (b)

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We study the stability of some strongly frustrated antiferromagnetic spin lattices in high magnetic fields against lattice distortions. In particular, we consider a spin-s anisotropic Heisenberg antiferromagnet on the square-kagomé and kagomé lattices. The independent localized magnons embedded in a ferromagnetic environment, which are the ground state at the saturation field, imply lattice instabilities for appropriate lattice distortions fitting to the structure of the localized magnons. We discuss in detail the scenario of this spin-Peierls instability in high magnetic fields which essentially depends on the values of the exchange interaction anisotropy ∆ and spin s. PACS number(s): 75.10. Jm, 75.45.+j

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Exact low-temperature behavior of a kagomé antiferromagnet at high fields

Cited by 166 publications

References 22 publications

Magnetization Process of the Spin-S Kagome-Lattice Heisenberg Antiferromagnet

Magnetization Process of the Spin-S Kagome-Lattice Heisenberg Antiferromagnet

Frustrated honeycomb-lattice bilayer quantum antiferromagnet in a magnetic field

Structural distortions of frustrated quantum spin lattices in high magnetic fields

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