基于双层石墨烯的超深斜低温场效应晶体管。

IF 11.3 1区化学 Q1 CHEMISTRY, PHYSICAL

ACS Catalysis Pub Date : 2024-09-18 Epub Date: 2024-09-04 DOI:10.1021/acs.nanolett.4c02463

Eike Icking, David Emmerich, Kenji Watanabe, Takashi Taniguchi, Bernd Beschoten, Max C Lemme, Joachim Knoch, Christoph Stampfer

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引用次数: 0

摘要

低温场效应晶体管（FET）具有巨大的应用潜力，最显著的例子就是量子信息处理器的经典控制电子器件。对于后者，低功耗片上场效应晶体管至关重要。这就需要毫伏级的工作电压，而这只有具有超深亚阈值斜率的器件才能实现。然而，在基于块状材料的传统低温金属氧化物半导体（MOS）场效应晶体管中，由于 MOS 界面的无序和带电缺陷，实验实现的反向亚阈值斜率在几 mV/dec 左右就会饱和。基于二维材料的场效应晶体管提供了一种很有前景的替代方案。在这里，我们展示了基于封装在六方氮化硼和石墨栅极中的贝纳尔堆叠双层石墨烯的场效应晶体管，其在 0.1 K 时的反向次阈值斜率低至 250 μV/dec，接近玻尔兹曼极限。这一结果表明，在没有体界面的范德华异质结构中，能有效抑制带尾，从而在低温条件下实现卓越的器件性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Ultrasteep Slope Cryogenic FETs Based on Bilayer Graphene.

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Ultrasteep Slope Cryogenic FETs Based on Bilayer Graphene.

Cryogenic field-effect transistors (FETs) offer great potential for applications, the most notable example being classical control electronics for quantum information processors. For the latter, on-chip FETs with low power consumption are crucial. This requires operating voltages in the millivolt range, which are only achievable in devices with ultrasteep subthreshold slopes. However, in conventional cryogenic metal-oxide-semiconductor (MOS)FETs based on bulk material, the experimentally achieved inverse subthreshold slopes saturate around a few mV/dec due to disorder and charged defects at the MOS interface. FETs based on two-dimensional materials offer a promising alternative. Here, we show that FETs based on Bernal stacked bilayer graphene encapsulated in hexagonal boron nitride and graphite gates exhibit inverse subthreshold slopes of down to 250 μV/dec at 0.1 K, approaching the Boltzmann limit. This result indicates an effective suppression of band tailing in van der Waals heterostructures without bulk interfaces, leading to superior device performance at cryogenic temperature.

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来源期刊

ACS Catalysis CHEMISTRY, PHYSICAL-

CiteScore

20.80

自引率

6.20%

发文量

1253

审稿时长

1.5 months

期刊介绍： ACS Catalysis is an esteemed journal that publishes original research in the fields of heterogeneous catalysis, molecular catalysis, and biocatalysis. It offers broad coverage across diverse areas such as life sciences, organometallics and synthesis, photochemistry and electrochemistry, drug discovery and synthesis, materials science, environmental protection, polymer discovery and synthesis, and energy and fuels. The scope of the journal is to showcase innovative work in various aspects of catalysis. This includes new reactions and novel synthetic approaches utilizing known catalysts, the discovery or modification of new catalysts, elucidation of catalytic mechanisms through cutting-edge investigations, practical enhancements of existing processes, as well as conceptual advances in the field. Contributions to ACS Catalysis can encompass both experimental and theoretical research focused on catalytic molecules, macromolecules, and materials that exhibit catalytic turnover.