Coherent Absorption Synergizes with Plasmon-Enhanced Graphene Terahertz Photo-thermoelectric Response

TL;DR

This paper demonstrates a hybrid graphene-based terahertz photodetector with enhanced absorption and responsivity through interferometric and plasmonic effects, enabling room-temperature, high-sensitivity THz imaging.

Contribution

It introduces a novel integration of interferometric enhancement with plasmonic graphene detectors, significantly boosting absorption and responsivity at room temperature.

Findings

Responsivity increased by approximately 30 times.

Response time maintained below 130 microseconds.

Effective in distinguishing concealed liquids.

Abstract

Terahertz (THz) technology shows great potential in 6G communications and imaging, but faces challenges related to detector sensitivity, noise, and cryogenic operation. Here, we integrate interferometric enhancement of absorption (IEA) from a metal reflection layer with a graphene plasmon polariton atomic cavity (PPAC)-based photodetector. The hybrid configuration enhances the in-plane electric field and improves the plasmon-induced thermal gradient. Numerical simulations and photoresponse measurements were employed to systematically investigate the influence of a metal reflective layer on the photothermoelectric behavior of the device, which reveals the IEA design significantly boosts the THz absorption rate in graphene nanostructures and promotes asymmetry in the lateral diffusion of hot carriers. Compared with the bare device, the responsivity of the device is enhanced by approximately 30-folds, while maintaining a response time below 130 microseconds. We further demonstrate the potential of the device to distinguish concealed liquids, advancing high-responsivity, room-temperature, and compact terahertz imaging technology.