Investigation of tetrakis(ethylmethylamido)hafnium adsorption mechanism in initial growth of atomic layer deposited-HfO2 thin films on H-/OH-terminated Si (100) surfaces

Jihye Park, Minji Jeong, Young Joon Cho, Kyung Joong Kim, Truong Ba Tai, Hyeyoung Shin, Jong Chul Lim, Hyo Sik Chang
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Abstract

The continuous scaling down of dynamic random access memory devices has necessitated a comprehensive understanding of the initial growth mechanism in atomic layer deposition. In this study, HfO2 was deposited using tetrakis(ethylmethylamido)hafnium (TEMAHf)-H2O on H-/OH-terminated Si (100) surfaces. By analyzing the Hf-O peak in the FTIR spectra and medium-energy ion scattering measurements, it was determined that a monolayer was formed on the H-Si surface at a rate (10 cycles) lower than that for the OH-Si surface (4 cycles). The ligand variations during each cycle, as determined by FTIR measurements, enabled the suggestion of the initial precursor adsorption mechanism. An analysis of the infrared spectra and secondary ion mass spectrometry depth profiles revealed surface-dependent differences in interfacial bonding. This explained the variation in the rate of formation of 1 Ml. Additionally, theoretical investigations using density functional theory calculations identified the reaction pathway with the lowest energy barrier, thereby validating the experimentally proposed mechanism. This study to elucidate the Si surface and the TEMAHf-H2O reaction mechanism provided insights into the analysis of the initial precursor adsorption mechanism for other types of precursors.
四(乙基甲基酰胺)铪在H-/ oh端Si(100)表面原子层沉积hfo2薄膜初始生长过程中的吸附机理研究
动态随机存取存储器器件的不断缩小要求对原子层沉积的初始生长机制有一个全面的了解。在这项研究中,用四(乙基甲基酰胺)铪(TEMAHf)- h2o在H-/ oh端Si(100)表面沉积HfO2。通过分析FTIR光谱中的Hf-O峰和中能离子散射测量,确定H-Si表面形成单层的速率(10个循环)低于OH-Si表面(4个循环)。在每个循环过程中,配体的变化,通过FTIR测量确定,使初步的前驱体吸附机制的建议。红外光谱和二次离子质谱深度剖面的分析揭示了界面键合的表面依赖性差异。这解释了1ml生成速率的变化。此外,使用密度泛函理论计算的理论研究确定了具有最低能量势垒的反应途径,从而验证了实验提出的机制。本研究阐明了Si表面和TEMAHf-H2O反应机理,为分析其他类型前驱体的初始吸附机理提供了见解。
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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