sub- 100nm cmosfet的设计:栅极电介质和沟道工程

2000 Symposium on VLSI Technology. Digest of Technical Papers (Cat. No.00CH37104) Pub Date : 2000-06-13 DOI:10.1109/VLSIT.2000.852821

Seungheon Song, W.S. Kim, J.S. Lee, T. Choe, J.H. Choi, M. Kang, U. Chung, N. Lee, K. Fujihara, H. Kang, S.I. Lee, M.Y. Lee

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引用次数: 9

摘要

采用2.0 nm以下的超薄栅极电介质制备了亚100 nm的CMOS晶体管，并对其进行了表征。利用硼(NMOS)或砷(PMOS)通道植入，然后选择性外延生长未掺杂的si，可以有效地减少短通道效应并提高电流可驱动性，即使在亚100 nm范围内也是如此。对于NMOS，铟植入器件表现出更好的短通道免疫，然而，电流驱动性没有改善。研究了直接隧穿泄漏情况下栅极氧化层厚度与栅极长度的关系，并首次提出了氧化层结垢的实验准则。对于PMOS，为了抑制硼的渗透，开发了氮氧化物和LPCVD氮化物的亚2.0 nm堆叠栅介电体，具有优异的晶体管特性。

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Design of sub-100 nm CMOSFETs: gate dielectrics and channel engineering

Sub-100 nm CMOS transistors with ultra-thin gate dielectrics below 2.0 nm were fabricated and characterized. Super-steep retrograde channel profiles using boron (NMOS) or arsenic (PMOS) channel implantation followed by selective epitaxial growth of undoped-Si were found to effectively reduce short-channel effect and improve current drivability even in the sub-100 nm regime. For NMOS, indium implanted devices showed better short-channel immunity, however, no improvement in current drivability was observed. Optimization of the gate oxide thickness versus gate length was investigated in the presence of direct tunneling leakages and for the first time, an experimental guideline of oxide scaling is proposed. For PMOS, to suppress boron penetration, sub-2.0 nm stack gate dielectrics of oxynitride and LPCVD nitride were developed, which showed excellent transistor characteristics.

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来源期刊

2000 Symposium on VLSI Technology. Digest of Technical Papers (Cat. No.00CH37104)

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