Molybdenum Chloride Double Perovskites: Dimensionality Control of Optical and Magnetic Properties
Molybdenum Chloride Double Perovskites: Dimensionality Control of Optical and Magnetic Properties
Halide double perovskites are a promising class of semiconducting materials for applications in solar cells and other optoelectronic devices. Recently, there has been a surge of interest in these materials to study phenomena beyond optoelectronics, especially magnetism. Here, we report three new Mo3+ (4d3) based chloride double perovskites: a 3-D rock-salt ordered Cs2NaMoCl6, a 1-D chain (MA)2AgMoCl6 and a Dion-Jacobson type 2-D layered (1,4-BDA)2AgMoCl8 (MA = methylammonium; 1,4-BDA = 1,4-butanediammonium). Their structures and dimensionality can be tuned by means of the A-cation. The measured bandgaps are relatively narrow (2.0-2.1 eV) which show blueshift on reducing dimensionality. At low temperatures, we observe antiferromagnetic coupling between the nearest-neighbour Mo3+ ions in all these systems. Cs2NaMoCl6 shows much stronger coupling with a frustration index f of 5 which we attribute to geometrically frustrating fcc lattice of Mo3+ ions. This work expands the scope of halide double perovskites beyond main group metals and beyond optoelectronics, and we hope it will lead future developments in magnetic halide perovskites.