Physical Review X (Oct 2021)

Broken-Symmetry Ground States of the Heisenberg Model on the Pyrochlore Lattice

  • Nikita Astrakhantsev,
  • Tom Westerhout,
  • Apoorv Tiwari,
  • Kenny Choo,
  • Ao Chen,
  • Mark H. Fischer,
  • Giuseppe Carleo,
  • Titus Neupert

DOI
https://doi.org/10.1103/PhysRevX.11.041021
Journal volume & issue
Vol. 11, no. 4
p. 041021

Abstract

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The spin-1/2 Heisenberg model on the pyrochlore lattice is an iconic frustrated three-dimensional spin system with a rich phase diagram. Besides hosting several ordered phases, the model is debated to possess a spin-liquid ground state when only nearest-neighbor antiferromagnetic interactions are present. Here, we contest this hypothesis with an extensive numerical investigation using both exact diagonalization and complementary variational techniques. Specifically, we employ a resonating-valence-bond-like, many-variable, Monte Carlo ansatz and convolutional neural network quantum states for (variational) calculations with up to 4×4^{3} and 4×3^{3} spins, respectively. We demonstrate that these techniques yield consistent results, allowing for reliable extrapolations to the thermodynamic limit. We consider the (λ,j_{2}/j_{1}) parameter space, with j_{2}, j_{1} being nearest and next-to-nearest neighbor interactions and λ the XXZ interaction anisotropy. Our main results are (1) the determination of the phase transition between the putative spin-liquid phase and the neighboring magnetically ordered phase and (2) a careful characterization of the ground state in terms of symmetry-breaking tendencies. We find clear indications of a dimer order with spontaneously broken inversion and rotational symmetry, calling the scenario of a featureless quantum spin liquid into question. Our work showcases how many-variable variational techniques can be used to make progress in answering challenging questions about three-dimensional frustrated quantum magnets.