Jinlin Wang, Qi Liu, Ran Feng, Haotian Ye, Xifan Xu, Rui Wang, Tao Wang, Xinqiang Wang
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引用次数: 0
摘要
高质量的铝(Al)/硅(Si)异质结在超导、界面热交换、硅基晶体管互连等广泛应用中至关重要。然而,在相对较高的温度下工作时,人们发现铝/硅异质结表面退化严重。因此,了解界面原子扩散是提高铝/硅界面质量的关键一步。我们利用铯校正扫描透射电子显微镜(STEM)报告了通过原位加热在铝/硅外延界面上的原子扩散行为。加热到 493 ± 20 K 后,铝/硅界面逐渐向铝侧迁移。这种界面原子迁移沿晶粒边界更为活跃,原因是晶粒的错位导致原子间的结合力减弱。新的界面呈现梯形,其特征是左侧面倾斜光滑,右侧面呈阶梯状。这种独特的形态可归因于界面能量的最小化。此外,迁移的硅原子倾向于按照铝的初始晶格取向形成新的纳米晶体,而扩散的铝原子通常是随机插入到硅晶格基体的一个大区域中,这可归因于铝的键能比硅低。本文受版权保护。
In‐situ Observation of Atomic Diffusion at Epitaxial Al/Si Interface
High‐quality aluminum (Al) /silicon (Si) heterojunction is crucial in a wide range of applications, such as superconductivity, interfacial heat exchanging, interconnection of Si‐based transistors, etc. However, serious Al/Si heterointerface degradation has been observed when operating at relatively higher temperatures. Understanding the interfacial atomic diffusion is thus a vital step for improving the Al/Si interface quality. We report the atomic diffusion behavior at an epitaxial Al/Si interface via in‐situ heating in Cs‐corrected scanning transmission electron microscopy (STEM). After heating to 493 ± 20 K, the Al/Si interface gradually migrates towards the Al side. This interfacial atomic migration is more active along grain boundaries due to weaker bonding between atoms caused by misorientation of grains. The new interface exhibits a trapezoidal shape, characterized by a slanted smooth left facet and a stepped right facet. This distinct morphology is attributed to minimizing the interfacial energy. Additionally, the migrated Si atoms tend to form a new nanocrystal following the initial lattice orientation in Al, while the diffused Al atoms are usually randomly inserted into the Si lattice matrix among a large region, which can be attributed to lower bonding energy of Al compared with Si.This article is protected by copyright. All rights reserved.
期刊介绍:
Physica status solidi (RRL) - Rapid Research Letters was designed to offer extremely fast publication times and is currently one of the fastest double peer-reviewed publication media in solid state and materials physics. Average times are 11 days from submission to first editorial decision, and 12 days from acceptance to online publication. It communicates important findings with a high degree of novelty and need for express publication, as well as other results of immediate interest to the solid-state physics and materials science community. Published Letters require approval by at least two independent reviewers.
The journal covers topics such as preparation, structure and simulation of advanced materials, theoretical and experimental investigations of the atomistic and electronic structure, optical, magnetic, superconducting, ferroelectric and other properties of solids, nanostructures and low-dimensional systems as well as device applications. Rapid Research Letters particularly invites papers from interdisciplinary and emerging new areas of research.
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