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Projective symmetry group classifications of quantum spin liquids on the simple cubic, body centered cubic, and face centered cubic lattices

Jonas Sonnenschein, Aishwarya Chauhan, Yasir Iqbal, Johannes Reuther

2020Physical review. B./Physical review. B14 citationsDOIOpen Access PDF

Abstract

We perform extensive classifications of ${\mathbb{Z}}_{2}$ quantum spin liquids on the simple cubic, body centered cubic, and face centered cubic (fcc) lattices using a spin-rotation-invariant fermionic projective symmetry group approach. Taking into account that all three lattices share the same point group ${O}_{h}$, we apply an efficient gauge where the classification for the simple cubic lattice can be partially carried over to the other two lattices. We identify hundreds of projective representations for each of the three lattices, however, when constructing short-range mean-field models for the fermionic partons (spinons) these phases collapse to only very few relevant cases. We self-consistently calculate the corresponding mean-field parameters for frustrated Heisenberg models on all three lattices with up to third-neighbor spin interactions and discuss the spinon dispersions, ground-state energies, and dynamical spin structure factors. Our results indicate that phases with nonuniform spinon hopping or pairing amplitudes are energetically favored. An unusual situation is identified for the fcc lattice where the spinon dispersion minimizing the mean-field energy features a network of symmetry-protected linelike zero modes in reciprocal space. We further discuss characteristic fingerprints of these phases in the dynamical spin structure factor which may help to identify and distinguish them in future numerical or experimental studies.

Topics & Concepts

SpinonCubic crystal systemPhysicsReciprocal latticeCondensed matter physicsLattice (music)Symmetry groupQuantum mechanicsMean field theoryTheoretical physicsQuantumGeometryMathematicsDiffractionAcousticsAdvanced Condensed Matter PhysicsPhysics of Superconductivity and MagnetismQuantum many-body systems