Bipolar Fabry-Pérot charge interferometer in periodically electron-irradiated graphene

arXiv - PHYS - Mesoscale and Nanoscale Physics Pub Date : 2024-09-07 DOI:arxiv-2409.04858

Nicola Melchioni, Federico Paolucci, Paolo Marconcini, Massimo Macucci, Stefano Roddaro, Alessandro Tredicucci, Federica Bianco

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Abstract

Electron optics deals with the wave-nature of charge carriers to induce, investigate and exploit coherent phenomena in solid state devices, in analogy with optics and photonics. Typically, these goals are achieved in complex electronic devices taking advantage of the macroscopically coherent charge transport in two dimensional electron gases and superconductors. Here, we demonstrate a simple counterintuitive architecture employing intentionally-created lattice defects to induce collective coherent effects in the charge transport of graphene. More specifically, multiple Fabry-P\'erot cavities are produced by irradiating graphene via low-energy electron-beam to form periodically alternated defective and pristine nano-stripes. The enhanced hole-doping in the defective stripes creates potential barriers behaving as partially reflecting mirrors and resonantly confining the carrier-waves within the pristine areas. The interference effects are both theoretically and experimentally investigated and manifest as sheet resistance oscillations up to 30 K for both polarities of charge carriers, contrarily to traditional electrostatically-created Fabry-P\'erot interferometers. Our findings propose defective graphene as an original platform for the realization of innovative coherent electronic devices with applications in nano and quantum technologies.

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周期性电子辐照石墨烯中的双极法布里-佩罗电荷干涉仪

电子光学研究电荷载流子的波性质，以诱导、研究和利用固态设备中的相干现象，类似于光学和光子学。通常，这些目标是在复杂的电子器件中利用二维电子气体和超导体中的宏观相干载流子传输来实现的。在这里，我们展示了一种简单的反直觉结构，利用有意制造的晶格缺陷，在石墨烯的电荷传输中诱导集体相干效应。更具体地说，通过低能电子束照射石墨烯，使其形成周期性交替的缺陷和原始纳米条纹，从而产生多个 Fabry-P\'erot cavities。缺陷条纹中增强的孔掺杂产生了潜在的势垒，这些势垒就像部分反射镜一样，共振地限制了原始区域内的载流子波。与传统的静电产生的法布里-普罗干涉仪不同，我们对干涉效应进行了理论和实验研究，并发现对于两种极性的电荷载流子，其片电阻振荡可达 30 K。我们的研究结果提出，缺陷石墨烯是实现创新相干电子器件的原始平台，可应用于纳米和量子技术。

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arXiv - PHYS - Mesoscale and Nanoscale Physics

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