Photocurrent in Bismuth Junctions with Graphene

TL;DR

This paper presents a room-temperature photodetector using bismuth nanowire arrays coupled with graphene, demonstrating broad-spectrum light absorption and robust photocurrent generation suitable for detector and energy harvesting applications.

Contribution

It introduces a novel graphene-bismuth junction device with broad spectral response and detailed analysis of charge transfer and photoresponse characteristics.

Findings

Broad spectral absorption from visible to telecom wavelengths

Robust photocurrent without spectral sacrifice

Power-law frequency dependence of photoresponse

Abstract

We report on a room-temperature photodetector utilizing semimetal bismuth nanowire arrays coupled with graphene. The structural flatness and high electron mobility of graphene exhibit great potential for future generations of electronic materials. Bismuth nanowire arrays coupled with graphene have strong absorption because of light trapping. Bismuth (Bi), as a semimetal, complements graphene's gapless and mobility characteristics. Bi also features a long screening length (4 nm) comparable to semiconductors. Raman spectroscopy is used to characterize the charge transfer between graphene and Bi. The analyzed spectrum includes the visible (350 nm) through the near infrared (980 nm) and well into the telecommunication band (1550 nm). Because of photocarrier pair generation and transfer at the interface, the photocurrent generated by the interface built-in field is robust without sacrificing the detection spectrum. We observe a power-law frequency dependence of the photoresponse over three order of magnitude of excitation frequency consistent with a wide distribution of diffusion times. These key properties may enable application of the junctions of graphene with Bi in detector and light harvesting applications.