標題: Nitride Induced Stress Affecting Crystallinity of Sidewall Damascene Gate-All-Around Nanowire Poly-Si FETs
作者: Shen, Chuan-Hui
Chen, Wei-Yen
Lee, Shen-Yang
Ku, Po-Yi
Chao, Tien-Sheng
電子物理學系
Department of Electrophysics
關鍵字: Crystallinity;gate-all-around;poly-Si;stress;thermal reliability
公開日期: 1-一月-2020
摘要: In this article, poly-Si gate-all-around (GAA) field effect transistors (FETs) using sidewall damascene method are successfully demonstrated. By manipulating the stress which is imposed by nitride layer, the crystallinity of poly-Si channels can be modified easily by changing the thickness of nitride layer. The better crystallinity of the devices with 60 & x00A0;nm top nitride is attributed to larger average grain size and fewer defects, leading to higher field-effect carrier mobility compared to 40 and 80 & x00A0;nm top nitride layer devices. Both n-type and p-type devices exhibit superior electrical characteristics including higher on-state current of 40 & x00A0;& x03BC;A & x002F;& x03BC;m (n-type) and 26 & x00A0;& x03BC;A & x002F;& x03BC;m (p-type), steep subthreshold swing of 82 & x00A0;mV & x002F;dec. (n-type) and 104 & x00A0;mV & x002F;dec. (p-type), an extremely low drain-induced barrier lowering (DIBL) of 4.6 & x00A0;mV & x002F;V (n-type) and 16.6 & x00A0;mV & x002F;V (p-type), and high I<sub>on</sub>& x002F;I<sub>off</sub> current ratio larger than seven orders of magnitude. The thermal stability and gate stress reliability measurement of sidewall damascene GAA nanowire poly-Si devices were also investigated. With better crystallinity, electrical characteristics of GAA nanowire poly-Si devices degrade less under same elevated temperature condition. Devices characteristics remain unchanged after long gate stress time. This simple fabrication process makes it a potential candidate for future three-dimensional integrated-circuit (3D-IC) and low-cost Internet of Things (IoTs) applications.
URI: http://dx.doi.org/10.1109/TNANO.2020.2981394
http://hdl.handle.net/11536/154371
ISSN: 1536-125X
DOI: 10.1109/TNANO.2020.2981394
期刊: IEEE TRANSACTIONS ON NANOTECHNOLOGY
Volume: 19
起始頁: 322
結束頁: 327
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