Engineering Graphene Phototransistors for High Dynamic Range Applicationsh
Shadi Nashashibi, Young Researcher of the Hector Fellow Academy, is first author of the publication “Engineering Graphene Phototransistors for High Dynamic Range Applications”, which was published in May 2024 in the journal ACS Nano. During his work, he was supervised by Hector Fellow Prof. Dr. Jürg Leuthold. The study focuses on a graphene-based phototransistor that utilizes the photogating effect and exhibits photodetection in the picowatt to microwatt range.
he proposed device offers the highest dynamic range and lowest detected optical power compared to the state of the art in interfacial photogating and is also air stable. Optimization of the device geometry and the addition of a semi-transparent top gate allows a 20- to 30-fold improvement in sensitivity. It also provides more degrees of freedom to tune the device performance to its ideal operating point. The device geometry is optimized with respect to the aspect ratio of the graphene channel, which can be used to improve photodetection performance.
These features are not limited to interface photodetectors, but can be adapted to a variety of photogate devices. These combined capabilities are valuable for applications that require a high dynamic range, such as artificial vision and vision restoration, and has potential for bio-inspired applications such as retinal implants.