Cocrystal Engineering of Organic Semiconductors for Photovoltaic Applications: Modeling Excited-State Properties of a Charge Transfer Cocrystal of a Dicarbazole Donor and a Fluoranil Acceptor.
Arkalekha Mandal, Chris Erik Mohn, Carl Henrik Görbitz, Anurag Roy
Abstract
Open AccessWith the recent advancements in lightweight, flexible, and environmentally benign organic supramolecular aggregates for various optoelectronic applications, cocrystals of aromatic π-donors and π-acceptors have emerged as promising n-type semiconductors and near-infrared absorbers for enhanced photovoltaic properties. Herein, we demonstrate the electron-dominant charge transport and wide absorption spanning from ultraviolet (UV) to NIR-I region (375-800 nm) of a cocrystal with π-donor 4,4'-bis-(carbazol-9-yl)-biphenyl (CBP) and π-acceptor 1,4-tetrafluoro-p-benzoquinone (fluoranil) as the components. The crystal packing in CBP:(fluoranil)2 is characterized by mixed stacks of alternative CBP and fluoranil molecules tethered by strong face-to-face π···π stacking interactions. The electron-dominant charge transport in the CBP:(fluoranil)2 cocrystal is governed by the "superexchange" hopping mechanism along the D-A mixed π-stack and is dominated by factors like the energy and symmetry of the frontier molecular orbitals of the CBP and fluoranil moieties. The narrow bandgap (≈1.2 eV) and the high value of the superexchange electron transfer integral (≈100 meV) confirm the potential application of this cocrystal as the active layer material in n-type organic field effect transistors (OFETs). In addition, the strong absorption spanning from the UV to near-infrared region, narrow and direct bandgap, and low exciton binding energy indicate that the CBP:(fluoranil)2 cocrystal can also be exploited for photovoltaic applications. The electron-hole distribution offset, exciton size, and one-electron transition density matrix analyses confirm facile charge transfer exciton generation and dissociation leading to free charge carriers. The calculated value of spectroscopy-limited maximum efficiency (SLME) from periodic density functional theory (DFT) calculations for this cocrystal shows that it can reach a photoconversion efficiency (PCE) of 31%, implying its potential applicability as a practical photovoltaic material.