Pentacene/non-fullerene acceptor heterojunction type phototransistors for broadened spectral photoresponsivity and ultralow level light detection

ITIC-type non-fullerene acceptors (NFAs) have attracted substantial attention in organic photovoltaics due to their advantages over fullerene derivative molecules. Briefly, the strengthened absorption coefficient, broadened spectral photoresponse, efficient exciton dissociation as well as tunable energy levels of ITIC-NFAs make them competitive components for organic optoelectronics. Here, a high-performance organic phototransistor is displayed using a simple bi-layer heterojunction of pentacene and ITIC. As a high performing semiconductor, pentacene serves as the p-type channel to transport the photo-generated carriers. Meanwhile, the representative NFA molecule, ITIC, is first applied in the organic heterojunction phototransistors (OHPTs) to improve the light detection range by extending the absorption into NIR and to enhance the light detection limit (0.3 mu W cm(-2)). The maximum values of photoresponsivity (R), I-photo/I-dark ratio and external quantum efficiency (EQE) are up to 1.0 x 10(5) A W-1, 4.7 x 10(5) and 2.0 x 10(5)%, respectively. The overall performances of our device are among the highest values in all-organic thin-film heterojunction phototransistors. These results demonstrate that ITIC-type NFAs could be highly efficient alternative acceptors for high-performance OHPTs.

Automated summary

ITIC-type non-fullerene acceptors (NFAs) offer advantages over fullerene derivative molecules in organic photovoltaics, with enhanced absorption coefficient, broadened spectral photoresponse, efficient exciton dissociation, and tunable energy levels. The combination of pentacene and ITIC in a bi-layer heterojunction demonstrates high performance in organic phototransistors, enhancing light detection range and limits. The results indicate that ITIC-type NFAs could serve as highly efficient alternative acceptors for high-performance OHPTs.