Maoyang Li, Chaochao Mo, Jiali Chen, P. Ji, Haiyun Tan, Xiaoman Zhang, Meili Cui, L. Zhuge, Xuemei Wu, Tianyuan Huang
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引用次数: 0
Abstract
This study delves into ion behavior at the substrate position within RF magnetron discharges utilizing an indium tin oxide (ITO) target. The positive ion energies exhibit an upward trajectory with increasing RF power, attributed to heightened plasma potential and initial emergent energy. Simultaneously, the positive ion flux escalates owing to amplified sputtering rates and electron density. Conversely, negative ions exhibit broad ion energy distribution functions (IEDFs) characterized by multiple peaks. These patterns are clarified by a combination of radiofrequency oscillation of cathode voltage and plasma potential, alongside ion transport time. This elucidation finds validation in a one-dimensional model encompassing the initial ion energy. At higher RF power, negative ions surpassing 100 eV escalate in both flux and energy, posing a potential risk of sputtering damages to ITO layers.
本研究深入探讨了利用铟锡氧化物(ITO)靶的射频磁控管放电中基片位置的离子行为。正离子能量随着射频功率的增加而呈现上升轨迹,这归因于等离子体势能和初始出现能量的增加。与此同时,由于溅射率和电子密度的提高,正离子流量也随之增加。相反,负离子则表现出以多峰为特征的宽离子能量分布函数(IEDF)。通过结合阴极电压和等离子体电位的射频振荡以及离子传输时间,这些模式得到了澄清。这一解释在包含初始离子能量的一维模型中得到了验证。在较高的射频功率下,超过 100 eV 的负离子流量和能量都会增加,从而对 ITO 层造成潜在的溅射损坏风险。
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