What question did this study set out to answer?

The central aim is to investigate terahertz rectification in an asymmetric dual-grating gate graphene-based field effect transistor.

January 22, 2026

High-Frequency Terahertz Rectification in Bilayer Graphene-Based Asymmetric Dual Grating Gates Field Effect Transistor

Key Points

The central aim is to investigate terahertz rectification in an asymmetric dual-grating gate graphene-based field effect transistor.
Constructed an asymmetric dual-grating gate graphene-based field effect transistor.
Excited the device using terahertz radiation at frequencies of 2.5, 2.9, and 3.9 THz.
Measured photocurrent at various frequencies, including modulation up to 2 kHz.
Achieved a maximum photocurrent of around 100 pA at 3.9 THz.
Observed a threefold increase in photocurrent with opposite bias on top gates.
The photocurrent remained stable with increasing modulation frequencies up to 2 kHz.

Abstract

In this work, we report on terahertz rectification, up to 3.9 THz, using an asymmetric dual-grating gate graphene-based field effect transistor. The device, at 8K, was excited by terahertz radiation at three tones (2.5, 2.9 and 3.9 THz). A maximum of photocurrent, around 100 pA, was measured for the excitation at 3.9 THz. This intensity was increased by a factor of 3 when the bias of both top gates were of opposite sign. This behavior was explained as due to the ratchet effect induced by the asymmetric structure and terahertz radiation. The photocurrent remains unchanged when the modulation frequency was increased up to 2 kHz demonstrating the high speed response feature of the device.

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Cite This Study

Abidi et al. (Tue,) studied this question.

synapsesocial.com/papers/6971bd4c642b1836717e1fdf https://doi.org/https://doi.org/10.1142/s0129156426410053

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