Dedoping of Lead Halide Perovskites Incorporating Monovalent Cations.

Mojtaba Abdi-Jalebi,Jolla Kullgren,Meysam Pazoki,Aditya Sadhanala,Bertrand Philippe,Michael Grätzel,Samuele Lilliu,Håkan Rensmo,Richard H Friend,Giorgio Divitini,Roghayeh Imani,Mejd Alsari,M Ibrahim Dar

doi:10.1021/acsnano.8b03586

Abstract

We report significant improvements in the optoelectronic properties of lead halide perovskites with the addition of monovalent ions with ionic radii close to Pb2+. We investigate the chemical distribution and electronic structure of solution processed CH3NH3PbI3 perovskite structures containing Na+, Cu+, and Ag+, which are lower valence metal ions than Pb2+ but have similar ionic radii. Synchrotron X-ray diffraction reveals a pronounced shift in the main perovskite peaks for the monovalent cation-based films, suggesting incorporation of these cations into the perovskite lattice as well as a preferential crystal growth in Ag+ containing perovskite structures. Furthermore, the synchrotron X-ray photoelectron measurements show a significant change in the valence band position for Cu- and Ag-doped films, although the perovskite bandgap remains the same, indicating a shift in the Fermi level position toward the middle of the bandgap. Such a shift infers that incorporation of these monovalent cations dedope the n-type perovskite films when formed without added cations. This dedoping effect leads to cleaner bandgaps as reflected by the lower energetic disorder in the monovalent cation-doped perovskite thin films as compared to pristine films. We also find that in contrast to Ag+ and Cu+, Na+ locates mainly at the grain boundaries and surfaces. Our theoretical calculations confirm the observed shifts in X-ray diffraction peaks and Fermi level as well as absence of intrabandgap states upon energetically favorable doping of perovskite lattice by the monovalent cations. We also model a significant change in the local structure, chemical bonding of metal-halide, and the electronic structure in the doped perovskites. In summary, our work highlights the local chemistry and influence of monovalent cation dopants on crystallization and the electronic structure in the doped perovskite thin films.

Highlights

Hybrid organic−inorganic lead halide perovskites display significant intrinsic properties including high absorption coefficient,[1] sharp and tunable bandgap,[2,3] long charge carrier diffusion length,[4,5] low trap densities, high
We have investigated the influence of these cations on the growth and crystal structure of lead halide perovskite with a comprehensive insight on the chemical distribution of these dopants within the lattice and their effect on the band structure
We observe a distinct shift in the main diffraction peak of both PbI2 and CH3NH3PbI3 upon addition of the above-mentioned monovalent cations, which is a sign of partial incorporation in the perovskite structure

Summary

Introduction

Hybrid organic−inorganic lead halide perovskites display significant intrinsic properties including high absorption coefficient,[1] sharp and tunable bandgap,[2,3] long charge carrier diffusion length,[4,5] low trap densities, high. We explore the chemical distribution, chemical bonding, and electronic and structural effects of Na, Cu, and Ag monovalent cation iodide dopants in hybrid organic− inorganic perovskite films with enhanced optoelectronic quality upon doping. Our findings reveal a clear picture of the distribution of monovalent cation dopants and their effects on the structure and growth of perovskite films

Methods

Results

Conclusion