Coexistence of Ohmic Contact and Fermi Level Pinning at 2D Electride/2D Semiconductor Interfaces

Chengfeng Pan; Dazhong Sun; Zhennan Lin; Xianghong Niu; Yu Ning Wu

doi:10.1021/jacs.5c18589

Coexistence of Ohmic Contact and Fermi Level Pinning at 2D Electride/2D Semiconductor Interfaces

Chengfeng Pan
, Dazhong Sun
, Zhennan Lin
, Xianghong Niu^*
, Yu Ning Wu^*

^*此作品的通讯作者

物理与电子科学学院

科研成果: 期刊稿件 › 文章 › 同行评审

摘要

It is well known that Fermi level pinning (FLP) always leads to hardly tunable Schottky barriers, thereby hindering the formation of an Ohmic contact (OhC). As a result, FLP and OhC are often implicitly regarded as being mutually exclusive. Herein, we demonstrate a rare case of two-dimensional (2D) electride/2D semiconductor interfaces, where OhC and FLP coexist. Owing to the large work function differences and the presence of 2D electron gas, n-type (p-type) OhC can be formed as the Fermi level is pinned within the conduction (valence) band. In n-type OhC, FLP results from significant interface dipoles, whereas in p-type OhC, the Fermi level is pinned by localized electronic states in the van der Waals gap, which is fundamentally distinct from conventional metal-induced or disorder-induced gap states. This work not only presents robust OhC under strong FLP but also enriches the fundamental understanding of FLP mechanisms.

源语言	英语
页（从-至）	1655-1661
页数	7
期刊	Journal of the American Chemical Society
卷	148
期	1
DOI	https://doi.org/10.1021/jacs.5c18589
出版状态	已出版 - 14 1月 2026

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abstract = "It is well known that Fermi level pinning (FLP) always leads to hardly tunable Schottky barriers, thereby hindering the formation of an Ohmic contact (OhC). As a result, FLP and OhC are often implicitly regarded as being mutually exclusive. Herein, we demonstrate a rare case of two-dimensional (2D) electride/2D semiconductor interfaces, where OhC and FLP coexist. Owing to the large work function differences and the presence of 2D electron gas, n-type (p-type) OhC can be formed as the Fermi level is pinned within the conduction (valence) band. In n-type OhC, FLP results from significant interface dipoles, whereas in p-type OhC, the Fermi level is pinned by localized electronic states in the van der Waals gap, which is fundamentally distinct from conventional metal-induced or disorder-induced gap states. This work not only presents robust OhC under strong FLP but also enriches the fundamental understanding of FLP mechanisms.",

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AU - Wu, Yu Ning

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N2 - It is well known that Fermi level pinning (FLP) always leads to hardly tunable Schottky barriers, thereby hindering the formation of an Ohmic contact (OhC). As a result, FLP and OhC are often implicitly regarded as being mutually exclusive. Herein, we demonstrate a rare case of two-dimensional (2D) electride/2D semiconductor interfaces, where OhC and FLP coexist. Owing to the large work function differences and the presence of 2D electron gas, n-type (p-type) OhC can be formed as the Fermi level is pinned within the conduction (valence) band. In n-type OhC, FLP results from significant interface dipoles, whereas in p-type OhC, the Fermi level is pinned by localized electronic states in the van der Waals gap, which is fundamentally distinct from conventional metal-induced or disorder-induced gap states. This work not only presents robust OhC under strong FLP but also enriches the fundamental understanding of FLP mechanisms.

AB - It is well known that Fermi level pinning (FLP) always leads to hardly tunable Schottky barriers, thereby hindering the formation of an Ohmic contact (OhC). As a result, FLP and OhC are often implicitly regarded as being mutually exclusive. Herein, we demonstrate a rare case of two-dimensional (2D) electride/2D semiconductor interfaces, where OhC and FLP coexist. Owing to the large work function differences and the presence of 2D electron gas, n-type (p-type) OhC can be formed as the Fermi level is pinned within the conduction (valence) band. In n-type OhC, FLP results from significant interface dipoles, whereas in p-type OhC, the Fermi level is pinned by localized electronic states in the van der Waals gap, which is fundamentally distinct from conventional metal-induced or disorder-induced gap states. This work not only presents robust OhC under strong FLP but also enriches the fundamental understanding of FLP mechanisms.

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Coexistence of Ohmic Contact and Fermi Level Pinning at 2D Electride/2D Semiconductor Interfaces

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