English

Kitaev quantum spin liquid - concept and materialization

Strongly Correlated Electrons 2022-01-21 v1

Abstract

A decade ago, Alexei Kitaev proposed an exactly solvable SS = 1/2 model on a two-dimensional honeycomb lattice, where the spins fractionalize into Majorana fermions and form a topological quantum spin liquid (QSL) in the ground state. It was soon recognized that a family of complex iridium oxides, as well as ruthenium chloride, with honeycomb structure are magnetic insulators and accommodate essential ingredients of the Kitaev model, due to the interplay of electron correlation and spin-orbit coupling. This initiated a race to materialize the Kitaev QSL and to capture the signature of Majorana fermions. In this review, we provide a wide perspective of this rapidly growing field, including theory, materials and experiment. We first summarize the theoretical background of the Kitaev QSL ground state and its materialization using spin-orbital-entangled JeffJ_{\rm eff} = 1/2 moments. This is followed by an overview of candidate materials and their magnetic properties, including Na2_2IrO3_3, α\alpha, β\beta, γ\gamma-Li2_2IrO3_3,α\alpha-RuCl3_3 and H3_3LiIr2_2O6_6. Finally, we review the latest exciting progress in the search for the Kitaev QSL. In particular, H3_3LiIr2_2O6_6 and α\alpha-RuCl3_3 in applied magnetic field show signatures of the QSL state, and α\alpha-RuCl3_3 has unusual magnetic excitations and thermal transport properties that are consistent with spin fractionalization.

Keywords

Cite

@article{arxiv.1903.08081,
  title  = {Kitaev quantum spin liquid - concept and materialization},
  author = {Hidenori Takagi and Tomohiro Takayama and George Jackeli and Giniyat Khaliullin and Stephen E. Nagler},
  journal= {arXiv preprint arXiv:1903.08081},
  year   = {2022}
}

Comments

Accepted for publication in Nature Reviews Physics

R2 v1 2026-06-23T08:12:59.878Z