基于高频石墨烯晶体管的光电混合技术。

Optoelectronic mixing with high-frequency graphene transistors.

作者信息

Montanaro A, Wei W, De Fazio D, Sassi U, Soavi G, Aversa P, Ferrari A C, Happy H, Legagneux P, Pallecchi E

机构信息

Thales Research and Technology, Palaiseau, France.

Photonic Networks and Technologies Lab - CNIT, Pisa, Italy.

出版信息

Nat Commun. 2021 May 12;12(1):2728. doi: 10.1038/s41467-021-22943-1.

DOI:10.1038/s41467-021-22943-1

PMID:33980859

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8115296/

Abstract

Graphene is ideally suited for optoelectronics. It offers absorption at telecom wavelengths, high-frequency operation and CMOS-compatibility. We show how high speed optoelectronic mixing can be achieved with high frequency (~20 GHz bandwidth) graphene field effect transistors (GFETs). These devices mix an electrical signal injected into the GFET gate and a modulated optical signal onto a single layer graphene (SLG) channel. The photodetection mechanism and the resulting photocurrent sign depend on the SLG Fermi level (E). At low E (<130 meV), a positive photocurrent is generated, while at large E (>130 meV), a negative photobolometric current appears. This allows our devices to operate up to at least 67 GHz. Our results pave the way for GFETs optoelectronic mixers for mm-wave applications, such as telecommunications and radio/light detection and ranging (RADAR/LIDARs.).

摘要

石墨烯非常适合用于光电子学。它在电信波长处具有吸收特性、高频操作能力以及与CMOS的兼容性。我们展示了如何利用高频（约20 GHz带宽）石墨烯场效应晶体管（GFET）实现高速光电子混频。这些器件将注入到GFET栅极的电信号和调制后的光信号混合到单层石墨烯（SLG）通道上。光探测机制和由此产生的光电流符号取决于SLG费米能级（E）。在低E（<130 meV）时，会产生正光电流，而在高E（>130 meV）时，会出现负光热电流。这使得我们的器件能够运行至至少67 GHz。我们的研究结果为用于毫米波应用（如电信以及无线电/光探测与测距（雷达/激光雷达））的GFET光电子混频器铺平了道路。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/219c/8115296/7140a3cbb23e/41467_2021_22943_Fig1_HTML.jpg

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基于高频石墨烯晶体管的光电混合技术。

Optoelectronic mixing with high-frequency graphene transistors.

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