Modeling of Stress-Retarded Thermal Oxidation of Nonplanar Silicon Structures for Realization of Nanoscale Devices

Ma F.-J.; Rustagi S. C.; Samudra G. S.; Zhao H.; Singh N.; Lo G.-Q.; Kwong D.-L.

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Modeling of Stress-Retarded Thermal Oxidation of Nonplanar Silicon Structures for Realization of Nanoscale Devices

机译：非平面硅结构的应力阻滞热氧化建模以实现纳米器件

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Accurate modeling of stress-retarded orientation-dependent 2-D oxidation is carried out by matching the experimental and simulated oxide thicknesses of silicon FIN nanostructures over a wide range of temperatures and times in dry oxygen. Experimentally observed initial oxidation rate enhancement, orientation-dependent stress retardation, and self-limiting phenomena are modeled, and a new universal stress retardation parameter set is obtained for the first time. The new parameter set has been validated against oxidation experiments presented here and those reported in the literature. Furthermore, the new model is used to explore silicon nanowire shape engineering.

机译：通过在宽广的温度和时间范围内，在干燥的氧气中匹配硅FIN纳米结构的实验厚度和模拟氧化物厚度，可以对应力延迟取向的二维氧化进行精确建模。对实验观察到的初始氧化速率提高，取向相关的应力延迟和自限现象进行建模，并首次获得新的通用应力延迟参数集。新的参数集已针对此处提出的氧化实验和文献中报道的氧化实验进行了验证。此外，新模型用于探索硅纳米线形状工程。

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来源
《Electron Device Letters, IEEE》 |2010年第7期|p.719-721|共3页
作者
Ma F.-J.; Rustagi S. C.; Samudra G. S.; Zhao H.; Singh N.; Lo G.-Q.; Kwong D.-L.;
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作者单位

Institute of Microelectronics, Agency for Science, Technology and Research (A $^{ast}$STAR), Singapore, Singapore;

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收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);
原文格式 PDF
正文语种 eng
中图分类
关键词
2-D oxidation; Nanowire (NW); orientation dependence; self-limiting; shape engineering; stress retardation;

机译：二维氧化;纳米线;方向依赖性;自限性;形状工程;应力缓和;

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Modeling of Stress-Retarded Thermal Oxidation of Nonplanar Silicon Structures for Realization of Nanoscale Devices

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