不同锗含量的外延SiGe薄膜对铁电HfZrOx可靠性的影响

2018 IEEE Symposium on VLSI Technology Pub Date : 2018-06-01 DOI:10.1109/VLSIT.2018.8510643

Kuen-Yi Chen, Yen-Hua Huang, Ruei-Wen Kao, Yan-Xiao Lin, Yung-Hsien Wu

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引用次数: 4

摘要

以TiN/铁电- hfzrox (HZO)/epi-SiGe (MFS)结构为平台，研究了Ge含量对可靠性性能的影响及其机理。与硅材料相比，Si0.56Ge0.44上的HZO不仅表现出58%的残余极化(Pr)增强，而且在±4 V/100k Hz双极交流应力下可忽略Pr降解高达109次的可靠性大大提高，在原始和循环状态下保持长达104秒，并且在85°C下随时间的印记效应较小。Ge含量相关的可靠性性能主要是由于较薄的亚氧化物界面层(IL)具有更好的质量，因为它太薄而无法捕获电荷，而由于更强的键合(较少的Vo)而不易产生缺陷。κ值较高的IL也有助于抑制其对面的e场，有利于提高可靠性。结果表明，随着技术进入SiGe平台，基于mfs的存储器更可行，因为Si的可靠性问题将大大缓解。

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Dependence of Reliability of Ferroelectric HfZrOx on Epitaxial SiGe Film with Various Ge Content

TiN/ferroelectric-HfZrOx (HZO)/epi-SiGe (MFS) structure was employed as the platform to investigate the dependence of Ge content on reliability performance and the mechanism behind it. As compared to Si counterpart, HZO on Si0.56Ge0.44 exhibits not only enhanced remnant polarization (Pr) by 58 % but much improved reliability in terms of negligible Pr degradation up to 109 cycles under ±4 V/100k Hz bipolar AC stress, desirable retention at pristine and cycled state up to 104 sec, and smaller imprint effect against time at 85 °C. The Ge content-dependent reliability performance is mainly due to the thinner sub-oxide interfacial layer (IL) with better quality since it is too thin to trap charges while less vulnerable to defect generation due to stronger bonding (fewer Vo). IL with higher κ value is also helpful to suppress E-field across it, beneficial to enhance reliability. The results suggest that as the technology advances into SiGe platform, it is more viable for MFS-based memory as the reliability issues for Si will be greatly mitigated.

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2018 IEEE Symposium on VLSI Technology

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