Reconciling monolayer and bilayer $J_{\rm eff} = 1/2$ square lattices in hybrid oxide superlattice

TL;DR

This paper reports the experimental realization of a hybrid SrIrO$_3$/SrTiO$_3$ superlattice combining monolayer and bilayer $J_{eff} = 1/2$ square lattices, revealing unique magnetic and electronic properties not seen in uniform layers.

Contribution

It demonstrates that integrating monolayer and bilayer $J_{eff} = 1/2$ lattices in a superlattice creates novel properties, showing a new way to engineer quantum states.

Findings

Hybrid superlattice exhibits a single antiferromagnetic transition.

Moments mainly point in the $ab$-plane, combining features of both layers.

Properties are distinct from simple addition of monolayer and bilayer behaviors.

Abstract

The number of atomic layers confined in a two-dimensional structure is crucial for the electronic and magnetic properties. Single-layer and bilayer $J_{\rm eff} = 1/2$ square lattices are well-known examples where the presence of the extra layer turns the XY-anisotropy to the $c$-axis anisotropy. We report on experimental realization of a hybrid SrIrO$_3$/SrTiO$_3$ superlattice that integrates monolayer and bilayer square lattices in one layered structure. By synchrotron x-ray diffraction, resonant x-ray magnetic scattering, magnetization, and resistivity measurements, we found that the hybrid superlattice exhibits properties that are distinct from both the single-layer and bilayer systems and cannot be explained by a simple addition of them. In particular, the entire hybrid superlattice orders simultaneously through a single antiferromagnetic transition at temperatures similar to the bilayer system but with all the $J_{\rm eff} = 1/2$ moments mainly pointing in the $ab$-plane similar to the single-layer system. The results show that bringing monolayer and bilayer with orthogonal properties in proximity to each other in a hybrid superlattice structure is a powerful way to stabilize a unique state not obtainable in a uniform structure.