Photosensitive Graphene P–N Junction Transistors and Ternary Inverters

We investigate the electric transport in a graphene–organic dye hybrid and the formation of p–n junctions. In the conventional approach, graphene p–n junctions are produced by using multiple electrostatic gates or local chemical doping, which produce different types of carriers in graphene. Instead of using multiple gates or typical chemical doping, a different approach to fabricate p–n junctions is proposed. The approach is based on optical gating of photosensitive dye molecules; this method can produce a well-defined sharp junction. The potential difference in the proposed p–n junction can be controlled by varying the optical power of incident light. A theoretical calculation based on the effective medium theory is performed to thoroughly explain the experimental data. The characteristic transport behavior of the photosensitive graphene p–n junction opens new possibilities for graphene-based devices, and we use the results to fabricate ternary inverters. Our strategy of building a simple hybrid p–n junction can further offer many opportunities in the near future of tuning it for other optoelectronic functionalities.