Zinc-Blende GeC Stabilized on GaN (001): An Ab Initio Study

IF 1.5 4区物理与天体物理 Q3 PHYSICS, CONDENSED MATTER

Advances in Condensed Matter Physics Pub Date : 2022-01-30 DOI:10.1155/2022/1506702

J. H. Camacho-García, Ma L. Ruiz-Peralta, G. Hernández-Cocoletzi, A. Bautista-Hernández, M. Salazar-Villanueva, A. Escobedo-Morales, E. Chigo-Anota, J. C. Moreno-Hernández

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Abstract

First-principle calculations have been performed to explore the initial stages of the zinc blende-like germanium carbide epitaxial growth on the gallium nitride (001)-(2 × 2) surface. First, we studied the Ge/C monolayer adsorption and incorporation at high symmetry sites. Results show that the adsorptions at the top and hcp1 sites are the most stable structures of C and Ge, respectively. Different terminated surfaces were used on the GeC epitaxial growth. According to the surface formation energies, only the first two bilayers are stable; therefore, the GeC epitaxial growth is favorable only under N-rich conditions on a Ge-terminated surface and with Ge bilayers terminated. In addition, it is demonstrated that GeC bilayers on the C-terminated surfaces are unstable and preclude the epitaxial growth. Electronic properties have been investigated by calculating the density of states (DOS) and the projected density of states (PDOS) of the most favorable structures.

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锌-闪锌矿GeC在GaN(001)上稳定:从头算研究

采用第一性原理计算方法，探讨了在氮化镓(001)-(2 × 2)表面上，锌掺杂样碳化锗外延生长的初始阶段。首先，我们研究了Ge/C单层膜在高对称位点的吸附和掺入。结果表明，C和Ge在顶部和hcp1位点的吸附结构最为稳定。采用不同的端接面进行GeC外延生长。根据表面形成能，只有前两层是稳定的;因此，只有在富n条件下，在终止Ge的表面和终止Ge双分子层上，才有利于GeC的外延生长。此外，还证明了c端表面的GeC双分子层是不稳定的，阻碍了外延生长。通过计算最有利结构的态密度(DOS)和投影态密度(PDOS)来研究电子性质。

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

Advances in Condensed Matter Physics PHYSICS, CONDENSED MATTER-

CiteScore

2.30

自引率

0.00%

发文量

审稿时长

6-12 weeks

期刊介绍： Advances in Condensed Matter Physics publishes articles on the experimental and theoretical study of the physics of materials in solid, liquid, amorphous, and exotic states. Papers consider the quantum, classical, and statistical mechanics of materials; their structure, dynamics, and phase transitions; and their magnetic, electronic, thermal, and optical properties. Submission of original research, and focused review articles, is welcomed from researchers from across the entire condensed matter physics community.