Analysis of superconducting silicon epilayers by atom probe tomography: Composition and Evaporation field

The European Physical Journal Applied Physics Pub Date : 2023-04-27 DOI:10.1051/epjap/2023230018

K. Hoummada, F. Dahlem, F. Panciera, É. Bustarret, C. Marcenat, D. Débarre, Y. Amraoui, D. Mangelinck, L. Tetard, H. Oughaddou, A. Kara, Y. Dappe, N. Rochdi

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Abstract

Three dimensional distributions of boron atoms incorporated into crystalline silicon (3-9 B % at.) well above the solubility limit are measured by atom probe tomography (APT). Samples have been prepared either by gas immersion laser doping (GILD) or by implantation followed by laser annealing (Pulsed Laser Induced Epitaxy: PLIE). GILD and PLIE silicon samples show superconducting properties at low temperature thanks to the achieved high doping level. In both cases, boron atoms are found to be randomly distributed within the silicon as revealed by statistical distribution analysis. No cluster or precipitate are detected, which can be related to the high speed of recrystallization of the Si:B alloy. A sharp 2D interface between the doped silicon region and the undoped substrate is also observed, characterizing a Si:B/Si epitaxy. Finally, the variation of the evaporation field is investigated in both materials by considering either the silicon charge states ratio or the variation of the total voltage applied during the analysis of the Si:B layer.

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超导硅薄膜的原子探针层析:成分和蒸发场

通过原子探针断层扫描(APT)测量了远高于溶解度极限的硼原子并入晶体硅(3- 9b % at.)的三维分布。制备样品的方法有两种，一种是气体浸没激光掺杂(GILD)，另一种是注入后激光退火(脉冲激光诱导外延:PLIE)。由于达到了高掺杂水平，GILD和PLIE硅样品在低温下表现出超导性能。在这两种情况下，硼原子被发现是随机分布在硅的统计分布分析。没有检测到团簇和沉淀，这可能与Si:B合金的再结晶速度快有关。在掺杂硅区和未掺杂衬底之间还观察到一个尖锐的二维界面，表征了Si:B/Si外延。最后，通过考虑硅电荷态比和硅:B层分析过程中施加的总电压的变化，研究了两种材料中蒸发场的变化。

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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The European Physical Journal Applied Physics

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