在 200 毫米平台上通过大容量批量 ALD 生成高度均匀的氮化铝薄膜

Partha Mukhopadhyay, Ivan Fletcher, Zuriel Caribe Couvertier, Brent Schwab, John Gumpher, W. Schoenfeld, Jon Kretzschmar, Anton deVilliers, Jim Fulford
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摘要

利用热原子层沉积 (ALD) 技术开发出了高度均匀的氮化铝薄膜,该技术专为处理大批量 200 毫米晶片而设计。通过在 100 多个晶圆反应器中采用优化配方,重复批量沉积超过 500 Å 的薄膜,厚度的三西格玛变化小于 0.5 Å,而晶圆内晶圆(WinW)和晶圆到晶圆(WtoW)的变化仍小于 5%。对各种 ALD 沉积温度、薄膜厚度以及硅、石英和 GaN/Si(111)模板的衬底类型进行了研究,以了解氮化铝薄膜的材料和光学特性。结果表明,300-350 ℃ 的窄温度范围最适合沉积过程,其中 350 ℃ 是最优温度范围。已观察到 AlN 的基底抑制生长和沉积速率的非线性,这可能与外来基底表面成核时的可用反应位点有关。通过对 Al2p、N1s、C1s 和 O1s 等 XPS 单个峰进行深入探讨的一组特殊实验显示,碳和氧污染可以忽略不计,Al-N 结合率为百分之百。通过横截面 TEM 可以看到硅上有一层无定形的 AlN 薄膜,而在氮化镓模板上则有一层微量的多晶薄膜,其与 AlGaN/GaN 结构的异质界面非常光滑。根据透射率实验,光带隙估计为 5.8 eV。一项深入的折射率调查显示,TEL Alpha-8SEiTM 批次 ALD 实现了高密度氮化铝,而且在成分和厚度上表现出优异的均匀性,运行到运行(RtoR)、WtoW 和 WinW 的均匀性均低于 0.5%,凸显了该工艺的可靠性和精确性,同时具有高产能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Nucleation of highly uniform AlN thin films by high volume batch ALD on 200 mm platform
A highly uniform aluminum nitride thin film has been developed by thermal atomic layer deposition (ALD), which is designed to handle high volume of 200 mm wafers. A three-sigma thickness variation of <0.5 Å resulted from repeatable batch depositions of over 500 Å, while wafer-within-wafer (WinW) and wafer-to-wafer (WtoW) remained <5% by the optimized recipe in a 100+ wafer reactor. Various ALD deposition temperatures, film thicknesses, and substrate types of Si, quartz, and GaN/Si(111) templates have been examined for material and optical properties of an AlN film. A narrow temperature window of 300–350 °C was identified as the most suitable for the deposition process with 350 °C as the optimized one. Substrate-inhibited growth and nonlinearity in deposition rate have been observed for AlN which is possibly related to the available reaction sites at the time of nucleation on foreign substrate surfaces. A special set of experiments with a thorough exploration of XPS individual peaks such as Al2p, N1s, C1s, and O1s reveals negligible carbon and oxygen contamination with cent-percent Al–N bonding. An amorphous AlN film is evident on Si by cross-sectional TEM while a trace of polycrystalline film on GaN templates with smooth heterointerfaces to AlGaN/GaN structures. The optical bandgap is estimated to be 5.8 eV from the transmittance experiment. An in-depth refractive-index investigation shows high-density AlN by TEL Alpha-8SEiTM batch ALD which also exhibits excellent uniformity over composition and thickness with run-to-run (RtoR), WtoW, and WinW uniformity under 0.5%, highlighting the reliability and precision of the process while having high throughput.
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