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Rutherford Backscattering Spectrometry analysis of the formation of superconducting V3Si thin films

IF 1.4 3区物理与天体物理 Q3 INSTRUMENTS & INSTRUMENTATION

Nuclear Instruments & Methods in Physics Research Section B-beam Interactions With Materials and Atoms Pub Date : 2025-08-26 DOI:10.1016/j.nimb.2025.165838

Fshatsion B. Gessesew , Manjith Bose , Kumaravelu Ganesan , Brett C. Johnson , Jeffrey C. McCallum

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引用次数: 0

Abstract

Vanadium silicide, V

_{3}

Si, is a promising superconductor for silicon-based superconducting (SC) devices due to its compatibility with silicon substrates and its potential for integration into existing semiconductor technologies. However, to date there have been only a limited number of studies of the formation of SC V

_{3}

Si thin films and the associated structural and superconducting properties. This work aims to explore the structural characteristics and SC properties of V

_{3}

Si films, paving the way for the development of functional SC devices for quantum technology applications. We have investigated the formation of V

_{3}

Si films by directly depositing vanadium (V) onto thermally grown SiO₂ on Si, followed by high-vacuum annealing to induce the phase transformation into V

_{3}

Si. Rutherford Backscattering Spectrometry (RBS) was employed throughout the sample growth process to analyze the material composition as a function of depth using a

^{4} {He}^{+}

ion beam. Analysis of the RBS data confirmed that the V layer fully reacted with the SiO₂ substrate to form V

_{3}

Si at the interface, in addition to a vanadium oxide (VO

_{x}

) layer forming atop the V

_{3}

Si film. The thickness of the V

_{3}

Si layer ranges from 63 to 130 nm, with annealing temperatures between 750 °C and 800 °C. A sharp SC transition was observed at T

_{c}

= 13 K in the sample annealed at 750 °C, with a narrow transition width

(Δ T_{c}) of 0.6 K

. Initial reactive ion etching (RIE) studies yielded promising results for local removal of the (VO

_{x}

) to facilitate electrical contact formation to the SC layer.

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超导V3Si薄膜形成的卢瑟福后向散射光谱分析

由于其与硅衬底的兼容性以及集成到现有半导体技术中的潜力，硅化钒V3Si是硅基超导（SC）器件中很有前途的超导体。然而，迄今为止，关于SC V3Si薄膜的形成及其相关的结构和超导性能的研究数量有限。本工作旨在探索V3Si薄膜的结构特征和SC特性，为开发用于量子技术应用的功能SC器件铺平道路。本文研究了将钒(V)直接沉积在Si上热生长的SiO2上，然后通过高真空退火诱导V3Si相变形成V3Si薄膜的方法。卢瑟福后向散射光谱法（RBS）在整个样品生长过程中使用4He+离子束分析材料成分作为深度的函数。对RBS数据的分析证实，V层与SiO2衬底充分反应，在界面处形成V3Si， V3Si薄膜顶部形成氧化钒（VOx）层。V3Si层的厚度为63 ~ 130 nm，退火温度为750 ~ 800℃。在750℃退火的样品中，在Tc = 13 K处观察到明显的SC转变，转变宽度（ΔTc）为0.6K。初始反应离子蚀刻（RIE）研究在局部去除（VOx）以促进SC层电接触形成方面取得了有希望的结果。

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

Nuclear Instruments & Methods in Physics Research Section B-beam Interactions With Materials and Atoms 物理-核科学技术

CiteScore

2.80

自引率

7.70%

发文量

231

审稿时长

1.9 months

期刊介绍： Section B of Nuclear Instruments and Methods in Physics Research covers all aspects of the interaction of energetic beams with atoms, molecules and aggregate forms of matter. This includes ion beam analysis and ion beam modification of materials as well as basic data of importance for these studies. Topics of general interest include: atomic collisions in solids, particle channelling, all aspects of collision cascades, the modification of materials by energetic beams, ion implantation, irradiation - induced changes in materials, the physics and chemistry of beam interactions and the analysis of materials by all forms of energetic radiation. Modification by ion, laser and electron beams for the study of electronic materials, metals, ceramics, insulators, polymers and other important and new materials systems are included. Related studies, such as the application of ion beam analysis to biological, archaeological and geological samples as well as applications to solve problems in planetary science are also welcome. Energetic beams of interest include atomic and molecular ions, neutrons, positrons and muons, plasmas directed at surfaces, electron and photon beams, including laser treated surfaces and studies of solids by photon radiation from rotating anodes, synchrotrons, etc. In addition, the interaction between various forms of radiation and radiation-induced deposition processes are relevant.