Study of Structure and Electronic Properties of Heterointerfaces for Photovoltaic Applications

Abstract: The linkage between the atomic structure and the electronic property is complex for heterointerfaces involving multicomponent organic−inorganic systems because of large configurations and chemical possibilities. Understanding the structure−property relationship at the interface becomes further complicated with an asymmetric structure of organic molecules compared to the interface between planer solids. Here, we report on ab inito molecular dynamics (AIMD) simulations of the perovskite/PCBM ([6,6]-phenyl-C 61 -… Show more

“…The periodic calculations of perovskites have had some success in predicting the structure and relative properties of photoelectric conversion. [16][17][18][19] However, the bulk phase calculations are time-consuming 20 and the periodic model does not flexibly reflect the local information. The internal structure and the interactions between the organic cation and inorganic BX framework remain to be studied.…”

Small practical cluster models for perovskites based on the similarity criterion of central location environment and their applications

“…The periodic calculations of perovskites have had some success in predicting the structure and relative properties of photoelectric conversion. [16][17][18][19] However, the bulk phase calculations are time-consuming 20 and the periodic model does not flexibly reflect the local information. The internal structure and the interactions between the organic cation and inorganic BX framework remain to be studied.…”

Small practical cluster models for perovskites based on the similarity criterion of central location environment and their applications

“…Unfortunately, they are computationally rather expensive, 29 making it difficult to obtain trajectories of sufficient simulation time length for relevant model system sizes and complexity. 30 In this work, we instead employ the density-functional tightbinding (DFTB) method, [31][32][33] which is an approximation to traditional DFT that is 100 to 1000 times faster and provides a trade-off between accuracy and computational efficiency. 34 Since DFTB is a quantum chemical method and able to compute nuclear forces during MD simulations by solving Kohn-Sham equations on-the-y, DFTB/MD 35 trajectories not only provide structural features but also contain information on the electronic structure such as charge distributions.…”

Quantum chemical investigation of the effect of alkali metal ions on the dynamic structure of water in aqueous solutions

Passivation effect of theophylline on the surface defects of MAPbI3 perovskite