Thermal Atomic Layer Etching of Zinc Oxide from 30–300 °C Using Sequential Exposures of Hydrogen Fluoride and Trimethylgallium

IF 7 2区材料科学 Q2 CHEMISTRY, PHYSICAL

Chemistry of Materials Pub Date : 2025-03-31 DOI:10.1021/acs.chemmater.5c0002810.1021/acs.chemmater.5c00028

Taewook Nam, David R. Zywotko, Troy A. Colleran, Jonathan L. Partridge and Steven M. George*,

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Abstract

Thermal atomic layer etching (ALE) of zinc oxide (ZnO) was demonstrated over a large temperature range from 30–300 °C using sequential exposures of HF (hydrogen fluoride) and Ga(CH₃)₃ (trimethylgallium (TMG)). In contrast to earlier studies of thermal ZnO ALE using sequential exposures of HF and trimethylaluminum (TMA), ZnO ALE with sequential HF and TMG exposures occurred without competing GaF₃ atomic layer deposition (ALD) or ZnO conversion. Quartz crystal microbalance (QCM) studies during ZnO ALE revealed a stepwise mass increase during fluorination by HF exposures and a larger mass decrease during ligand-exchange by TMG exposures. The mass changes per cycle (MCPC) were self-limiting versus HF and TMG exposures at 100 °C. Spectroscopic ellipsometry measured etch rates over a wide temperature range. The etch rates varied from 0.24 Å/cycle at 30 °C to 3.82 Å/cycle at 300 °C. The temperature-dependent etch rates were consistent with an activation barrier of E_a = 3.3 kcal/mol. TMG exposures were also compared with TMA exposures at 100 °C on fresh ZnO surfaces grown by ZnO ALD. TMG exposures led to a mass gain consistent with TMG adsorption. In contrast, TMA exposures produced a mass loss consistent with the conversion of ZnO to Al₂O₃. Previous studies showed that conversion of ZnO to Al₂O₃ prevented ZnO ALE using HF and TMA exposures at temperatures less than 205 °C. Etching at <205 °C was restricted because HF adsorption on fluorinated Al₂O₃ led to competing AlF₃ ALD. In contrast, ZnO ALE at temperatures as low as 30 °C is possible because no competing GaF₃ ALD occurs using HF and TMG exposures. Quadrupole mass spectrometry (QMS) experiments were also performed to identify the etch products during ZnO ALE. The QMS experiments support fluorination and ligand-exchange reactions without conversion during ZnO ALE using HF and TMG exposures. The HF and TMG exposures were selective for ZnO ALE compared with HfO₂, ZrO₂ or Al₂O₃ ALE. ZnO ALE could also smooth ZnO surfaces progressively versus number of ZnO ALE cycles.

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使用氟化氢和三甲基镓连续暴露在30-300°C的氧化锌的热原子层蚀刻

采用HF（氟化氢）和Ga(CH3)3（三甲基镓（TMG））连续暴露，在30-300℃的大温度范围内证明了氧化锌（ZnO）的热原子层蚀刻（ALE）。与早期使用HF和三甲基铝（TMA）连续暴露的ZnO热ALE研究相反，连续HF和TMG暴露的ZnO ALE没有竞争的GaF3原子层沉积（ALD）或ZnO转化。石英晶体微平衡（QCM）研究表明，在HF暴露的氟化过程中，ZnO的质量逐步增加，而在TMG暴露的配体交换过程中，ZnO的质量下降幅度更大。与100°C的HF和TMG暴露相比，每周期的质量变化（MCPC）是自限性的。光谱椭偏法测量了宽温度范围内的蚀刻速率。蚀刻速率从30°C时的0.24 Å/cycle到300°C时的3.82 Å/cycle不等。温度相关的腐蚀速率符合Ea = 3.3 kcal/mol的激活势垒。还比较了TMG和TMA在100℃下对ZnO ALD生长的新鲜ZnO表面的影响。TMG暴露导致了与TMG吸附一致的质量增加。相比之下，TMA暴露产生的质量损失与ZnO转化为Al2O3一致。先前的研究表明，在低于205°C的温度下，HF和TMA暴露可以阻止ZnO转化为Al2O3。由于HF在氟化Al2O3上的吸附会导致AlF3 ALD的竞争，因此在205°C下的蚀刻受到限制。相比之下，ZnO ALE在低至30°C的温度下是可能的，因为使用HF和TMG暴露时不会发生竞争性的GaF3 ALD。采用四极杆质谱法（QMS）对ZnO ALE过程中的腐蚀产物进行了表征。QMS实验支持在HF和TMG暴露的ZnO ALE过程中氟化和配体交换反应没有转化。与HfO2、ZrO2或Al2O3相比，HF和TMG暴露对ZnO ALE具有选择性。ZnO ALE还可以随着ZnO ALE循环次数的增加而逐渐使ZnO表面光滑。

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来源期刊

Chemistry of Materials 工程技术-材料科学：综合

CiteScore

14.10

自引率

5.80%

发文量

929

审稿时长

1.5 months

期刊介绍： The journal Chemistry of Materials focuses on publishing original research at the intersection of materials science and chemistry. The studies published in the journal involve chemistry as a prominent component and explore topics such as the design, synthesis, characterization, processing, understanding, and application of functional or potentially functional materials. The journal covers various areas of interest, including inorganic and organic solid-state chemistry, nanomaterials, biomaterials, thin films and polymers, and composite/hybrid materials. The journal particularly seeks papers that highlight the creation or development of innovative materials with novel optical, electrical, magnetic, catalytic, or mechanical properties. It is essential that manuscripts on these topics have a primary focus on the chemistry of materials and represent a significant advancement compared to prior research. Before external reviews are sought, submitted manuscripts undergo a review process by a minimum of two editors to ensure their appropriateness for the journal and the presence of sufficient evidence of a significant advance that will be of broad interest to the materials chemistry community.