Chih-Chao Yang, J. Shieh, Tung-Ying Hsieh, Wen-Hsien Huang, Hsing-Hsiang Wang, C. Shen, Tsung-Ta Wu, Y. Hou, Yi-Ju Chen, Yao-Jen Lee, Min-Cheng Chen, Fu-Liang Yang, Yu-Hsiu Chen, Meng-Chyi Wu, W. Yeh
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引用次数: 9
摘要
局部和选择性远红外激光退火(FIR-LA)工艺,加热时间极短(+ Si NWFET和多锗无结(JL) NWFET, BEOL兼容单片3D+纳米电子。通过绿色纳秒激光结晶(GNS-LC)和FIR-LA工艺制备的3D+ Si nwfet具有陡峭的亚阈值摆动(开/关比>5×104)和较小的DIBL。此外,由此制备的低驱动电压6T SRAM在Vd=0.4V时显示出130 mV的静态噪声裕度(SNM),使物联网(iot)的低功耗低成本3D+IC成为可能。
Enabling low power BEOL compatible monolithic 3D+ nanoelectronics for IoTs using local and selective far-infrared ray laser anneal technology
Local and selective far-infrared ray laser annealing (FIR-LA) process with very short heating duration (<;100μs) and low substrate temperature (<;400°C) enables sequentially stacked gate-first nanowire FETs (NWFETs), including 3D+ Si NWFET and poly-Ge junctionless (JL) NWFET, and BEOL compatible monolithic 3D+ nanoelectronics. The 3D+ Si NWFETs, demonstrated by green nano-second laser crystallization (GNS-LC) and FIR-LA processes exhibit steep subthreshold swing (<;90mV/dec.) and high driving current (n-type: 310μA/μm and p-type: 220μA/μm). The 7nm poly-Ge JLNWFET shows high Ion/Ioff ratio (>5×104) and small DIBL. Furthermore, the thus fabricated low driving voltage 6T SRAM shows a static noise margin (SNM) of 130 mV at Vd=0.4V enabling the low power and low cost 3D+IC for internet of things (IoTs).
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