Abstract
Molecular engineering plays a critical role in the development of electron donor and acceptor materials for improving power conversion efficiency (PCE) of organic photovoltaics (OPVs). The halogenated acceptor materials in OPVs have shown high PCE. Here, to investigate the halogenation mechanism and the effects on OPV performances, based on the density functional theory calculations with the optimally tuned screened range-separated hybrid functional and the consideration of solid polarization effects, we addressed the halogenation effects of acceptor ITIC, which were modeled by bis-substituted ITIC with halogen and coded as IT-2X (X = F, Cl, Br), and PBDB-T:ITIC, PBDB-T:IT-2X (X = F, Cl, Br) complexes on their geometries, electronic structures, excitations, electrostatic potentials, and the rate constants of charge transfer, exciton dissociation (ED), and charge recombination processes at the heterojunction interface. The results indicated that halogenation of ITIC slightly affects molecular geometric structures, energy levels, optical absorption spectra, exciton binding energies, and excitation properties. However, the halogenation of ITIC significantly enlarges the electrostatic potential difference between the electron acceptor and donor PBDB-T with the order from fluorination and chlorination to bromination. The halogenation also increases the transferred charges of CT states for the complexes. Meanwhile, the halogenation effects on CT energies and electron process rates depend on different haloid elements. No matter which kinds of haloid elements were introduced in the halogenation of acceptors, the ED is always efficient in these OPV devices. This work provides an understanding of the halogenation mechanism, and is also conducive to the designing of novel materials with the aid of the halogenation strategy.
Highlights
Most of the electron processes for organic photovoltaics (OPVs) power conversion happen in the active layer which is composed of both electron donor and acceptor materials
The main conclusions are as followings: Halogenation of electron acceptor ITIC in OPV heterojunction slightly affect the molecular geometric structures, molecular orbitals (MOs) energy levels, optical absorption spectra, exciton binding energies, and excitation properties
The halogenation of ITIC significantly enlarge the electrostatic potential (ESP) difference between electron acceptor and donor PBDB-T with the order from fluorination and chlorination to bromination that can induce an electric field at the heterojunction interface, and the halogenation can increase the transferred charges of charge transfer (CT) states for the complexes, corresponding to the increase of Jsc
Summary
Organic photovoltaics (OPVs) have received extensive attention in recent years due to their light weight, low cost, semitransparency, flexibility, etc. The design and development of high-performance OPV devices are of great significance to solving the energy crisis [1,2,3]. The power conversion efficiency (PCE) record of OPVs was over 18% [4,5,6,7]. Most of the electron processes for OPV power conversion happen in the active layer which is composed of both electron donor and acceptor materials. As the core of the OPV device, the changing active layer materials can tune photovoltaic performances [8,9]
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