用于逻辑应用的量子增强型约瑟夫森结场效应晶体管

IF 3.9 3区材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Materials Science and Engineering B-advanced Functional Solid-state Materials Pub Date : 2024-09-26 DOI:10.1016/j.mseb.2024.117729

W. Pan , A.J. Muhowski , W.M. Martinez , C.L.H. Sovinec , J.P. Mendez , D. Mamaluy , W. Yu , X. Shi , K. Sapkota , S.D. Hawkins , J.F. Klem

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引用次数: 0

摘要

约瑟夫森结场效应晶体管（JJFET）最近再次成为超导计算的理想候选器件。在使用经典沟道材料制造的传统 JJFET 中，由于超导临界电流逐渐依赖于栅极偏压，αR 远远小于 1。在这封信中，我们提出了一种在零能隙 InAs/GaSb 异质结构中的量子增强 JJFET 的新器件结构。我们证明，由于这种零能隙异质结构中的激子绝缘体量子相变，超导临界电流显示出与栅极偏压函数相关的急剧转变，推导出的增益因子 αR ∼ 0.06 是经典 JJFET 所报告的增益因子（∼ 0.001）的 50 多倍。进一步优化可使逻辑应用的增益因子大于 1。

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Quantum enhanced Josephson junction field-effect transistors for logic applications

Josephson junction field-effect transistors (JJFETs) have recently re-emerged as promising candidates for superconducting computing. For JJFETs to perform Boolean logic operations, the so-called gain factor α_R must be larger than 1. In a conventional JJFET made with a classical channel material, due to a gradual dependence of superconducting critical current on the gate bias, α_R is much smaller than 1. In this Letter, we propose a new device structure of quantum enhanced JJFETs in a zero-energy-gap InAs/GaSb heterostructure. We demonstrate that, due to an excitonic insulator quantum phase transition in this zero-gap heterostructure, the superconducting critical current displays a sharp transition as a function of gate bias, and the deduced gain factor α_R ∼ 0.06 is more than 50 times that (∼0.001) reported in a classical JJFET. Further optimization may allow achieving a gain factor larger than 1 for logic applications.

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来源期刊

Materials Science and Engineering B-advanced Functional Solid-state Materials 工程技术-材料科学：综合

CiteScore

5.60

自引率

2.80%

发文量

481

审稿时长

3.5 months

期刊介绍： The journal provides an international medium for the publication of theoretical and experimental studies and reviews related to the electronic, electrochemical, ionic, magnetic, optical, and biosensing properties of solid state materials in bulk, thin film and particulate forms. Papers dealing with synthesis, processing, characterization, structure, physical properties and computational aspects of nano-crystalline, crystalline, amorphous and glassy forms of ceramics, semiconductors, layered insertion compounds, low-dimensional compounds and systems, fast-ion conductors, polymers and dielectrics are viewed as suitable for publication. Articles focused on nano-structured aspects of these advanced solid-state materials will also be considered suitable.