Tuning electronic and magnetic states of pseudospin-½ square lattice in artificial iridate superlattice

The discovery of J_eff=1/2 Mott insulating state in the Sr₂IrO₄ has drawn a lot of attention since this 2D pseudospin-1/2 square lattice is analogous to high-T_c cuprates. On the other hand, the emergent phenomena exhibited by the pseudospin-1/2 electrons could be highly susceptible to small changes in the structural degrees of freedom due to the cooperation between electronic correlation and spin-orbit coupling (SOC). Engineering a layered structure of pseudospin-1/2 square lattice in artificial superlattices can afford extra tunability of the electronic and magnetic interactions for stabilizing novel collective quantum states. Through controlling dimensionality, spacing layer and epitaxial strain in perovskite iridate-based superlattices, we have investigated the evolution of the spin-orbit-entangled electronic and magnetic ground state under different control parameters. The results from a suite of characterizations, including transport measurements, magnetometry, and synchrotron-based x-ray spectroscopy and scattering, reveal new routes to drive the collective behavior of the interacting pseudospin-1/2 electrons, which is not achievable in the bulk.