Suppression of plasmonic interference in helicity sensitive broadband terahertz detectors

IF 3.1 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Carbon Trends Pub Date : 2024-03-01 DOI:10.1016/j.cartre.2024.100331

Ilya Mazurenko , Dmitriy Vovk , Yakov Matyushkin , Alesia Paddubskaya , Maxim Rybin , Elena Obraztsova

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Abstract

The recently observed helicity-sensitive response, occurring in graphene based field-effect transistors (FETs) is interpreted as a result of the intrinsic phase asymmetry of these devices and interference of plasmons in the FET channel. The graphene-based plasmonic interferometers presented in this work enable the room temperature detection of THz radiation as well as allows us to distinguish between the rotation direction of circular polarized waves. To illustrate the broadband nurture of the observed effects, similar measurements were carried out at both THz and mid-infrared frequencies. The precise control of the carriers type and their concentration throughout the channel length allows us to demonstrate the helicity-sensitive response over a wide range of the gate potentials (from negative to positive values). We experimentally show that the formation of p–n junction inside the graphene channel leads to additional scattering of excited plasma waves, resulting in the suppression of their interference and consequent reduction of the helicity-sensitive contribution.

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抑制螺旋敏感宽带太赫兹探测器中的等离子干扰

最近在基于石墨烯的场效应晶体管（FET）中观察到的螺旋敏感响应被解释为这些器件固有的相位不对称和场效应晶体管通道中的质子干扰的结果。本研究中介绍的石墨烯基等离子体干涉仪可实现太赫兹辐射的室温检测，并允许我们区分圆极化波的旋转方向。为了说明所观察到的效应的宽带性质，我们在太赫兹和中红外频率下都进行了类似的测量。通过对载流子类型及其在整个通道长度上的浓度进行精确控制，我们可以在很宽的栅极电位范围（从负值到正值）内展示螺旋敏感响应。我们的实验表明，石墨烯通道内 p-n 结的形成会导致激发等离子体波的额外散射，从而抑制了它们之间的干扰，进而降低了螺旋敏感贡献。

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