Hybrid perovskites, especially methylammonium lead iodide (MAPbI 3 ), exhibit excellent solar power conversion efficiencies. However, their application is plagued by poor chemical and structural stability. Using direct calorimetric measurement of heats of formation, MAPbI 3 is shown to be thermodynamically unstable with respect to decomposition to lead iodide and methylammonium iodide, even in the absence of ambient air or light or heat-induced defects, thus limiting its long-term use in devices. The formation enthalpy from binary halide components becomes less favorable in the order MAPbCl 3 , MAPbBr 3 , MAPbI 3 , with only the chloride having a negative heat of formation. Optimizing the geometric match of constituents as measured by the Goldschmidt tolerance factor provides a potentially quantifiable thermodynamic guide for seeking chemical substitutions to enhance stability.hybrid halide perovskites | thermodynamic instability | solar cells | tolerance factor | enthalpy of formation O rganic-inorganic hybrid materials which adopt the perovskite structure have gained increasing attention due to their excellent solar to electric power conversion efficiencies (PCEs). Methylammonium lead halide (MAPbX 3 ) perovskite leads the race with a PCE of 20%. Although these perovskites were discovered in 1978 by Weber, who described their structural and physical properties (1, 2), their solar cell application was explored only in 2009 by Miyasaka and coworkers. (3). Recently a very impressive PCE of 20% has been claimed for these materials (4). The extraordinary performance of hybrid perovskites has been attributed to their large absorption efficiency, favorable band gap, high charge mobility, and long-range electron hole transport (5-8). The AMX 3 perovskite structure provides great flexibility for modifications where, in principle, a range of similar compounds with different energy gaps can be synthesized by variation and/or partial substitution of the organic moiety (A = methylammonium, ethylammonium, formamidinium, or other possible organic cations), the metal (M = Pb, Sn and possible others), or the halide (X = I, Br, Cl). All these factors make organic metal halide perovskites frontrunners compared with other conventional solar cell materials (9).
