Interface Structure and Doping of Chemical Vapor Deposition‐Grown MoS2 on 4H–SiC by Microscopic Analyses and Ab Initio Calculations

physica status solidi (RRL) – Rapid Research Letters Pub Date : 2023-07-25 DOI:10.1002/pssr.202300218

S. Panasci, I. Deretzis, E. Schilirò, A. La Magna, F. Roccaforte, A. Koos, B. Pécz, S. Agnello, M. Cannas, F. Giannazzo

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Abstract

The interface structure and electronic properties of monolayer (1L) MoS2 domains grown by chemical vapor deposition on 4H–SiC(0001) are investigated by microscopic/spectroscopic analyses combined with ab initio calculations. The triangular domains are epitaxially oriented on the (0001) basal plane, with the presence of a van der Waals (vdW) gap between 1L–MoS2 and the SiC terraces. The high crystalline quality of the domains is confirmed by photoluminescence emission. Furthermore, a very low tensile strain (ε ≈ 0.03%) of 1L–MoS2, consistent with the small in‐plane lattice mismatch, and a p‐type doping of (0.45 ± 0.11) × 1013 cm−2, is evaluated by Raman mapping. Density functional theory (DFT) calculations of the MoS2/4H–SiC(0001) system are also performed, considering different levels of refinement of the model: 1) the simple case of the junction between Si‐terminated SiC and MoS2, showing a covalent bond between the Si–S atoms and n‐type doping of MoS2; 2) the complete passivation of Si dangling bonds with a monolayer (1 ML) of oxygen atoms, resulting in a vdW bond with dSi–S ≈ 3.84 Å bond length and p‐type doping of MoS2; and 3) partial (¼ ML and ½ ML) oxygen coverages of the 4H–SiC surface, resulting in intermediate values of dSi–S and doping behavior.

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化学气相沉积生长MoS2在4H-SiC上的界面结构和掺杂的微观分析和从头计算

采用显微/光谱分析和从头计算相结合的方法研究了化学气相沉积在4H-SiC(0001)上生长的单层(1L) MoS2畴的界面结构和电子性能。三角形畴在(0001)基面上外延取向，在1L-MoS2和SiC阶地之间存在范德华(vdW)间隙。光致发光证实了结构域的高结晶性。此外，通过拉曼映射评估了1L-MoS2的极低拉伸应变(ε≈0.03%)，与小的平面内晶格失配一致，p型掺杂为(0.45±0.11)× 1013 cm−2。本文还对MoS2/ 4h - SiC(0001)体系进行了密度泛函理论(DFT)计算，考虑了模型的不同改进程度:1)Si端SiC和MoS2之间的结的简单情况，显示Si - s原子之间的共价键和MoS2的n型掺杂;2)单层(1 ML)氧原子完全钝化Si悬空键，得到键长dSi-S≈3.84 Å的vdW键和p型MoS2掺杂;3) 4H-SiC表面的部分(¼ML和½ML)氧覆盖，导致dSi-S的中间值和掺杂行为。

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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physica status solidi (RRL) – Rapid Research Letters

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