Interplay of non-symmorphic symmetry and spin-orbit coupling in hyperkagome spin liquids: Applications to Na$_4$Ir$_3$O$_8$

TL;DR

This paper classifies and analyzes quantum spin liquids on the hyperkagome lattice of Na$_4$Ir$_3$O$_8$, highlighting the role of non-symmorphic symmetry and spin-orbit coupling in stabilizing gapless states and influencing their properties.

Contribution

It provides a comprehensive classification of $bZ_2$ and $U(1)$ spin liquids on hyperkagome lattices considering symmetry constraints and identifies the effects of spin-orbit coupling, especially Dzyaloshinskii-Moriya interactions.

Findings

Only three $bZ_2$ and two $U(1)$ spin liquids are possible.

Non-symmorphic symmetry forbids $bZ_2$ flux phases like $rac{ ext{pi}}{ ext{flux}}$ phases.

A $U(1)$ spin liquid with spinon Fermi surfaces is energetically favored.

Abstract

Na$_4$Ir$_3$O$_8$ provides a material platform to study three-dimensional quantum spin liquids in the geometrically frustrated hyperkagome lattice of Ir$^{4+}$ ions. In this work, we consider quantum spin liquids on hyperkagome lattice for generic spin models, focusing on the effects of anisotropic spin interactions. In particular, we classify possible $\mathbb{Z}_2$ and $U(1)$ spin liquid states, following the projective symmetry group analysis in the slave-fermion representation. There are only three distinct $\mathbb{Z}_2$ spin liquids, together with 2 different $U(1)$ spin liquids. The non-symmorphic space group symmetry of hyperkagome lattice plays a vital role in simplifying the classification, forbidding "$\pi$-flux" or "staggered-flux" phases in contrast to symmorphic space groups. We further prove that both $U(1)$ states and one $Z_2$ state among all 3 are symmetry-protected gapless spin liquids, robust against any symmetry-preserving perturbations. Motivated by the "spin-freezing" behavior recently observed in Na$_4$Ir$_3$O$_8$ at low temperatures, we further investigate the nearest-neighbor spin model with dominant Heisenberg interaction subject to all possible anisotropic perturbations from spin-orbit couplings. We found a $U(1)$ spin liquid ground state with spinon fermi surfaces is energetically favored over $Z_2$ states. Among all spin-orbit coupling terms, we show that only Dzyaloshinskii-Moriya (DM) interaction can induce spin anisotropy in the ground state when perturbing from the isotropic Heisenberg limit. Our work paves the way for a systematic study of quantum spin liquids in various materials with a hyperkagome crystal structure.