Unraveling energetics and states of adsorbing oxygen species with MoS2 for modulated work function.

IF 8 2区 材料科学 Q1 CHEMISTRY, PHYSICAL Nanoscale Horizons Pub Date : 2024-11-20 DOI:10.1039/d4nh00441h
Hejin Yan, Hongfei Chen, Xiangyue Cui, Qiye Guan, Bowen Wang, Yongqing Cai
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Abstract

MoS2 and related transition metal dichalcogenides (TMDs) have recently been reported as having extensive applications in nanoelectronics and catalysis because of their unique physical and chemical properties. However, one practical challenge for MoS2-based applications arises from the easiness of oxygen contamination, which is likely to degrade performance. To this end, understanding the states and related energetics of adsorbed oxygen is critical. Herein, we identify various states of oxygen species adsorbed on the MoS2 surface with first-principles calculations. We reveal a "dissociative" mechanism through which a physisorbed oxygen molecule trapped at a sulfur vacancy can split into two chemisorbed oxygen atoms, namely a top-anchoring oxygen and a substituting oxygen, both of which show no adsorbate induced states in the bandgap. The electron and hole masses show an asymmetric effect in response to oxygen species with the hole mass being more sensitive to oxygen content due to a strong hybridization of oxygen states in the valence band edge of MoS2. Alteration of oxygen content allows modulation of the work function up to 0.5 eV, enabling reduced Schottky barriers in MoS2/metal contact. These results show that oxygen doping on MoS2 is a promising method for sulfur vacancy healing, carrier mass controlling, contact resistance reduction, and anchoring of surface electron dopants. Our study suggests that tuning the chemical composition of oxygen is viable for modulating the electronic properties of MoS2 and likely other chalcogen-incorporated TMDs, which offers promise for new optoelectronic applications.

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用 MoS2 揭示吸附氧物种的能量和状态,实现调制功函数。
据报道,MoS2 和相关的过渡金属二钙化物(TMDs)因其独特的物理和化学特性,最近在纳米电子学和催化领域得到了广泛应用。然而,基于 MoS2 的应用所面临的一个实际挑战是容易受到氧气污染,这可能会降低性能。为此,了解吸附氧的状态和相关能量学至关重要。在此,我们通过第一原理计算确定了吸附在 MoS2 表面的氧物种的各种状态。我们揭示了一种 "解离 "机制,通过这种机制,被困在硫空位上的物理吸附氧分子可以分裂成两个化学吸附氧原子,即一个顶部锚定氧和一个置换氧,这两个氧原子在带隙中都不显示吸附物诱导态。电子和空穴质量对氧原子的反应不对称,空穴质量对氧原子含量更敏感,这是因为氧原子在 MoS2 价带边缘有很强的杂化状态。改变氧含量可以调节高达 0.5 eV 的功函数,从而降低 MoS2/金属接触的肖特基势垒。这些结果表明,在 MoS2 上掺杂氧是一种很有前途的方法,可以治疗硫空位、控制载流子质量、降低接触电阻和锚定表面电子掺杂物。我们的研究表明,调整氧的化学成分可以调节 MoS2 以及其他可能加入了铬元素的 TMD 的电子特性,这为新的光电应用带来了希望。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Nanoscale Horizons
Nanoscale Horizons Materials Science-General Materials Science
CiteScore
16.30
自引率
1.00%
发文量
141
期刊介绍: Nanoscale Horizons stands out as a premier journal for publishing exceptionally high-quality and innovative nanoscience and nanotechnology. The emphasis lies on original research that introduces a new concept or a novel perspective (a conceptual advance), prioritizing this over reporting technological improvements. Nevertheless, outstanding articles showcasing truly groundbreaking developments, including record-breaking performance, may also find a place in the journal. Published work must be of substantial general interest to our broad and diverse readership across the nanoscience and nanotechnology community.
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Unraveling energetics and states of adsorbing oxygen species with MoS2 for modulated work function. Back cover "Sweet MOFs": exploring the potential and restraints of integrating carbohydrates with metal-organic frameworks for biomedical applications. Extracellular vesicles of different cellular origin feature distinct biomolecular corona dynamics. Rhodium nanospheres for ultraviolet and visible plasmonics.
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