Abstract
We investigate the impact of various levels of approximation in density functional theory calculations for the structural and binding properties of the prototypical halide perovskite MAPbI3. Specifically, we test how the inclusion of different correction schemes for including dispersive interactions, and how in addition using hybrid density functional theory, affects the results for pertinent structural observables by means of comparison to experimental data. In particular, the impact of finite temperature on the lattice constants and bulk modulus, and the role of dispersive interactions in calculating them, is examined by using molecular dynamics based on density functional theory. Our findings confirm previous theoretical work showing that including dispersive corrections is crucial for accurate calculation of structural and binding properties of MAPbI3. They, furthermore, highlight that using a computationally much more expensive hybrid density functional has only minor consequences for these observables. This allows for suggesting the use of semilocal density functional theory, augmented by pairwise dispersive corrections, as a reasonable choice for structurally more complicated calculations of halide perovskites. Using this method, we perform molecular dynamics calculations and discuss the dynamic effect of molecular rotation on the structure of and binding in MAPbI3, which allows for rationalizing microscopically the simultaneous occurrence of a cubic octahedral symmetry and methylammonium disorder.
Highlights
Such insight can be generated from first-principles based computations
It is well established that spin-orbit coupling (SOC) due to the presence of the lead atom in MAPbI3 leads to strong modifications in the electronic structures, i.e., it lifts the degeneracy of the conduction and valence band and lowers the band gap
The results from the static unit cell calculations confirmed previous findings that showed the importance of including dispersive interaction in density functional theory (DFT) calculations for the structure and binding in MAPbI3.12,21–27 Here, we went beyond in testing a range of dispersive-correction schemes: PBE calculations corrected by the TS scheme with the regular Hirshfeld partitioning and the many-body dispersion (MBD) scheme showed good agreement with experimental data
Summary
Such insight can be generated from first-principles based computations. from a theoretical point of view, there are a number of physical effects and properties, all of which could play a role regarding the structure of and binding in HaPs. We find that the improvement because of using the HSE functional is minor compared to using dispersive corrections, which is found to be the essential computational ingredient for obtaining accurate structural and binding properties of MAPbI3.
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