用第13族路易斯酸对黑磷进行表面改性以实现环境防护和电子调谐

Surface Modification of Black Phosphorus with Group 13 Lewis Acids for Ambient Protection and Electronic Tuning.

作者信息

Tofan Daniel, Sakazaki Yukako, Walz Mitra Kendahl L, Peng Ruoming, Lee Seokhyeong, Li Mo, Velian Alexandra

机构信息

Department of Chemistry, University of Washington, 4000 15th Ave NE, Seattle, WA, 98195, USA.

Department of Electrical and Computer Engineering, Department of Physics, University of Washington, Paul Allen Center, 185 E Stevens Way NE, Seattle, WA, 98195, USA.

出版信息

Angew Chem Int Ed Engl. 2021 Apr 6;60(15):8329-8336. doi: 10.1002/anie.202100308. Epub 2021 Mar 5.

DOI:10.1002/anie.202100308

PMID:33480169

Abstract

Herein we introduce a facile, solution-phase protocol to modify the Lewis basic surface of few-layer black phosphorus (bP) and demonstrate its effectiveness at providing ambient stability and tuning of electronic properties. Commercially available group 13 Lewis acids that range in electrophilicity, steric bulk, and Pearson hard/soft-ness are evaluated. The nature of the interaction between the Lewis acids and the bP lattice is investigated using a range of microscopic (optical, atomic force, scanning electron) and spectroscopic (energy dispersive, X-ray photoelectron) methods. Al and Ga halides are most effective at preventing ambient degradation of bP (>84 h for AlBr ), and the resulting field-effect transistors show excellent IV characteristics, photocurrent, and current stability, and are significantly p-doped. This protocol, chemically matched to bP and compatible with device fabrication, opens a path for deterministic and persistent tuning of the electronic properties in bP.

摘要

在此，我们介绍一种简便的溶液相方法来修饰少层黑磷（bP）的路易斯碱性表面，并展示其在提供环境稳定性和调节电子性质方面的有效性。我们评估了市售的第13族路易斯酸，这些路易斯酸在亲电性、空间位阻和皮尔逊软硬程度方面各不相同。使用一系列微观（光学、原子力、扫描电子）和光谱（能量色散、X射线光电子能谱）方法研究了路易斯酸与bP晶格之间相互作用的性质。铝和镓的卤化物在防止bP的环境降解方面最为有效（AlBr₃的情况下>84小时），并且由此制备的场效应晶体管表现出优异的IV特性、光电流和电流稳定性，并且显著p型掺杂。该方法与bP化学匹配且与器件制造兼容，为确定性和持久性地调节bP的电子性质开辟了一条途径。

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用第13族路易斯酸对黑磷进行表面改性以实现环境防护和电子调谐

Surface Modification of Black Phosphorus with Group 13 Lewis Acids for Ambient Protection and Electronic Tuning.

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