Bond ordering and phase transitions in Na2IrO3 under high pressure

Abstract

The Kitaev model of spin-1/2 on a honeycomb lattice supports degenerate topological ground states and may be useful in topological quantum computation. Na2IrO3 with honeycomb lattice of Ir ions have been extensively studied as candidates for the realization of the this model, due to the effective Jeff=1/2 low-energy excitations produced by spin-orbit and crystal-field effect. As the eventual realization of Kitaev model has remained evasive, it is highly desirable and challenging to tune the candidate materials toward such end. It is well known external pressure often leads to dramatic changes to the geometric and electronic structure of materials. In this work, the high pressure phase diagram of Na2IrO3 is examined by first-principles calculations. It is found that Na2IrO3 undergoes a sequence of structural and magnetic phase transitions, from the magnetically ordered phase with space group C2/m to two bond-ordered non-magnetic phases. The low-energy excitations in these high-pressure phases can be well described by the Jeff=1/2 states.