碳微纤维上无定形氧化铝-二氧化硅薄膜的催化原子层沉积

Elise des Ligneris, D. Samélor, A. Sekkat, Claudie Josse, T. Hungria, Alessandro Pugliara, C. Vahlas, B. Caussat
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引用次数: 0

摘要

在碳微纤维上沉积硅基薄膜一直被认为是一项挑战。事实上,碳超细纤维在 550 K 以上的氧化敏感性及其亚微米级的纹理表面并不符合原子层沉积 (ALD) 所要求的沉积一致性,也不符合与二氧化硅 ALD 常见方案相关的热氧化条件。尽管如此,使用三甲基铝和三(叔戊氧基)硅烷醇 (TPS) 催化 ALD 工艺,可以在开氏 445 度时沉积无定形的氧化铝-二氧化硅双层膜。这项研究首次在平面硅片上利用光学光谱进行,研究了导致致密二氧化硅薄膜生长的动力学之间的相互作用与应用操作参数的关系。研究发现了薄膜催化生长与 TPS 中五氧衍生化合物完全排气之间的临界值,从而在 0.3 nm min-1 的普通 ALD 速率下,每个周期的等效生长沉积为 1.1 nm c-1,厚度梯度平坦。在碳超细纤维织物上的沉积是保形的,尽管由于超细纤维表面纹理的影响,厚度增长上限低于 20 nm。STEM-EDX 显示双层膜的界面清晰,碳扩散有限。氧化铝-二氧化硅薄膜在碳超细纤维上的保形和致密沉积为进一步用作耐火氧气阻挡层提供了巨大的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Catalytic atomic layer deposition of amorphous alumina–silica thin films on carbon microfibers
Deposition of silica-based thin films on carbon microfibers has long been considered a challenge. Indeed, the oxidation-sensitive nature of carbon microfibers over 550 K and their submicron-textured surface does not bode well with the required conformity of deposition best obtained by atomic layer deposition (ALD) and the thermal oxidative conditions associated with common protocols of silica ALD. Nonetheless, the use of a catalytic ALD process allowed for the deposition of amorphous alumina–silica bilayers from 445 K using trimethylaluminium and tris(tert-pentoxy)silanol (TPS). In this study, first undertaken on flat silicon wafers to make use of optical spectroscopies, the interplay between kinetics leading to a dense silica film growth was investigated in relation to the applied operation parameters. A threshold between the film catalyzed growth and the complete outgassing of pentoxy-derived compounds from TPS was found, resulting in a deposition of equivalent growth per cycle of 1.1 nm c−1, at a common ALD rate of 0.3 nm  min−1, with a flat thickness gradient. The deposition on carbon microfiber fabrics was found conformal, albeit with a thickness growth capped below 20 nm, imparted by the microfiber surface texture. STEM-EDX showed a sharp interface of the bilayer with limited carbon diffusion. The conformal and dense deposition of alumina–silica thin films on carbon microfibers holds great potential for further use as refractory oxygen barrier layers.
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