Physical Review Research (Sep 2024)

Order-by-disorder in the antiferromagnetic J_{1}-J_{2}-J_{3} transverse-field Ising model on the ruby lattice

  • Antonia Duft,
  • Jan A. Koziol,
  • Patrick Adelhardt,
  • Matthias Mühlhauser,
  • Kai P. Schmidt

DOI
https://doi.org/10.1103/PhysRevResearch.6.033339
Journal volume & issue
Vol. 6, no. 3
p. 033339

Abstract

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We investigate the quantum phase diagram of the J_{1}-J_{2}-J_{3} antiferromagnetic transverse-field Ising model on the ruby lattice. In the low-field limit we derive an effective quantum dimer model, analyzing how the extensive ground-state degeneracy at zero field is lifted by an order-by-disorder scenario. We support our analysis by studying the gap closing of the high-field phase using series expansions. For J_{2}>J_{3}, we find a columnar phase at low fields, followed by a clock-ordered phase stabilized by resonating plaquettes at intermediate field values, and an emergent three-dimensional (3D)-XY quantum phase transition to the polarized high-field phase. For J_{3}>J_{2}, an order-by-disorder mechanism stabilizes a distinct k=(0,0) order and a quantum phase transition in the 3D-Ising universality class is observed. Further, we discuss the possible implementation of the columnar- and clock-ordered phase in existing Rydberg atom quantum simulators. When taking into account the full algebraically decaying long-range interactions on the ruby lattice, we find that long-range interactions favor the same ground state as the quantum fluctuations induced by a transverse field, which could make the ruby lattice a promising candidate for the realization of a clock-ordered phase.