By process of illumination: Revealing the causes of dramatic anharmonicity in CH$ _{3} $NH$ _{3} $PbI$ _{3} $ with Raman scattering

Motivated by promising photovoltaic performance, recent works have established halide perovskites as a unique class of semiconductors. Recent evidence links their novel optoelectronic responses to pronounced electron-phonon interactions that stem from strongly anharmonic lattice fluctuations. Here, we reveal the microscopic mechanisms that lead to the strong structural anharmonicity in methylammonium lead iodide (MAPI). Our findings are based on Raman polarizationorientation measurements and first-principles molecular dynamics (MD) across the phase sequence of the crystal. We identify two mechanisms that lead to strong anharmonicity and differ in their temperature dependence. The first is the abrupt breaking of hydrogen bonds, which unlocks the PbI$_6$ octahedra from the methylammonium molecules. This leads to a phase transition from orthorhombic to tetragonal structure. The second is relaxational movement of the PbI$_6$ octahedra whose anharmonicity continuously strengthens through both the tetragonal and cubic phases. These strongly anharmonic motions limit phonon lifetimes to the point that the phonon picture breaks down. These conclusions transform our understanding of the structural dynamics of the technologically-relevant tetragonal phase of MAPI, whose anharmonic nature has not been previously demonstrated.