Ground-state properties of spin-1/2 Heisenberg antiferromagnets with frustration on the diamond-like-decorated square and triangular lattices

We study the ground-state phase diagrams and properties of spin-1/2 Heisenberg models on the diamond-like-decorated square and triangular lattices. The diamond-like-decorated square (triangular) lattice is a lattice in which the bonds of a square (triangular) lattice are replaced with diamond units....

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Published inAIP advances Vol. 8; no. 10; pp. 101427 - 101427-7
Main Authors Hirose, Yuhei, Miura, Shoma, Yasuda, Chitoshi, Fukumoto, Yoshiyuki
Format Journal Article
LanguageEnglish
Published Melville American Institute of Physics 01.10.2018
AIP Publishing LLC
Subjects
Antiferromagnetism
Computer simulation
Decoration
Diamonds
Dimers
Ferrimagnetism
Heisenberg antiferromagnets
Heisenberg theory
Lattices (mathematics)
Long range order
Magnons
Order parameters
Phase diagrams
Properties (attributes)
Scaling
Statistical models
Subgroups
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Summary:We study the ground-state phase diagrams and properties of spin-1/2 Heisenberg models on the diamond-like-decorated square and triangular lattices. The diamond-like-decorated square (triangular) lattice is a lattice in which the bonds of a square (triangular) lattice are replaced with diamond units. The diamond unit has two types of antiferromagnetic exchange interactions, and the ratio λ of the strength of the diagonal bond to that of the other four edges determines the ground-state properties. In particular, the macroscopically degenerated tetramer-dimer states, which are equivalent to the dimer covering states of the original lattices, are stabilized for λc < λ < 2, where the value of λc depends on the lattices. To determine the phase diagrams and boundaries λc, we employ the modified spin wave (MSW) method and the quantum Monte Carlo (QMC) method to estimate the ground-state energies of the ferrimagnetic states for λ < λc, where we can consider the mixed spin-1 and spin-1/2 Lieb-lattice and triangular Lieb-lattice Heisenberg antiferromagnets instead, and obtain λc(square)=0.974 and λc(triangular)=0.988. We also calculate the long-range order (LRO) parameters using the MSW and QMC methods and find the scaling relations where the spin reductions of each sublattice are inversely proportional to the number of sublattice sites. We prove these scaling relations by applying an infinitesimal uniform magnetic field. Furthermore, by examining the calculation process in the MSW, we clarify the mathematical structure behind the scaling relations for the sublattice LROs.
ISSN:2158-3226
2158-3226
DOI:10.1063/1.5042792