Electric field-induced phase transitions in the hybrid halide perovskite MAPbI3

Y. Liljegren
Master′s Thesis (2026)
doi: 20.500.12380/311356

Hybrid halide perovskites have attracted significant attention due to their remarkable optoelectronic properties, which are sensitive to structural phase transitions. This work investigates electric field-induced phase transitions in methylammonium lead iodide (MAPbI3), a prototypical hybrid halide perovskite, using molecular dynamics simulations with a charge-aware neuroevolution potential. The structural and dynamical response of MAPbI3 to both static and oscillating electric fields is characterized across a range of temperatures, focusing on octahedral tilting, methylammonium (MA) cation orientations and vibrational properties. Under static fields up to 0.1 V/Å, the orthorhombic-to-tetragonal phase transition temperature decreases while the tetragonal-to-cubic transition shifts to higher temperatures. Analysis of phonon mode projections indicates that electric fields induce a reorientation of the octahedral tilt pattern, with the dominant tilt axis preferentially oriented away from the field direction. A progressive alignment of MA molecular dipoles with increasing field strength is observed. For oscillating fields, frequency-temperature phase diagrams constructed for two field strengths reveal a substantial suppression of transition temperatures across many frequencies, with pronounced resonant features at 1.3 THz and 2.4 THz. Vibrational analysis suggests that these resonances couple to infrared-active PbI6 framework modes rather than direct MA dipole reorientation, providing insights into the intricate coupling between the inorganic lattice and organic cations that governs phase behavior under external fields.