What is moving in hybrid halide perovskite solar cells?

TL;DR

This paper reviews the dynamic atomic and electronic motions in hybrid halide perovskite solar cells, highlighting their impact on material properties and photovoltaic performance through experimental and computational insights.

Contribution

It provides a comprehensive analysis of internal motions in hybrid perovskites, combining experimental data and multi-scale simulations to elucidate their effects on photovoltaic behavior.

Findings

Molecular rotation and ionic diffusion influence dielectric properties.

Electron and hole polarons exhibit drift and diffusion behaviors.

Hybrid perovskites are mixed-mode conductors with unique dynamic properties.

Abstract

Organic-inorganic semiconductors, which adopt the perovskite crystal structure, have perturbed the landscape of contemporary photovoltaics research. In this Account, we discuss the internal motion of methylammonium lead iodide (CH$_3$NH$_3$PbI$_3$) and formamidinium lead iodide ([CH(NH$_2$)$_2$]PbI$_3$), covering: (i) molecular rotation-libration in the cuboctahedral cavity; (ii) drift and diffusion of large electron and hole polarons; (iii) transport of charged ionic defects. These processes give rise to a range of properties that are unconventional for photovoltaic materials, including frequency-dependent permittivity, low electron-hole recombination rates, and current-voltage hysteresis. Multi-scale simulations - drawing from electronic structure, ab initio molecular dynamic and Monte Carlo techniques - have been combined with neutron scattering and ultra-fast vibrational spectroscopy to qualify the nature and timescales of the motions. Recent experimental evidence and theoretical models for simultaneous electron transport and ion transport in these materials has been presented, suggesting they are mixed-mode conductors with similarities to metal oxide perovskites developed for battery and fuel cell applications. We expound on the implications of these effects for the photovoltaic action. The temporal behaviour found in hybrid perovskites introduces a sensitivity in materials characterisation to the time and length scale of the measurement, as well as the history of each sample. It also poses significant challenges for accurate materials and device simulations. Herein, we critically discuss the atomistic origin of the dynamic processes.