Hole doping in a negative charge transfer insulator
Ranjan Kumar Patel, Krishnendu Patra, Shashank Kumar Ojha, Siddharth Kumar, Sagar Sarkar, Akash Saha, Nandana Bhattacharya, J. W. Freeland, Jong‐Woo Kim, Philip J. Ryan, Priya Mahadevan, S. Middey
Abstract
Abstract R E NiO 3 is a negative charge transfer energy system and exhibits a temperature-driven metal-insulator transition (MIT), which is also accompanied by a bond disproportionation (BD) transition. In order to explore how hole doping affects the BD transition, we have investigated the electronic structure of single-crystalline thin films of Nd 1− x Ca x NiO 3 by synchrotron based experiments and ab-initio calculations. Here we show that for a small value of x , the doped holes are localized on one or more Ni sites around the dopant Ca 2+ ions, while the BD state for the rest of the lattice remains intact. The effective charge transfer energy (Δ) increases with Ca concentration and the formation of BD phase is not favored above a critical x , suppressing the insulating phase. Our present study firmly demonstrates that the appearance of BD mode is essential for the MIT of the R E NiO 3 series.