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Sub-30nm Mosfet Fabrication Technology Incorporating Precise Dopant Profile Design using Diffusion-Less High-Activation Laser Annealing

2006 14th IEEE International Conference on Advanced Thermal Processing of Semiconductors Pub Date : 2006-10-01 DOI:10.1109/RTP.2006.367995
M. Narihiro, T. Iwamoto, T. Yamamoto, T. Ikezawa, K. Yako, M. Tanaka, A. Mineji, Y. Okuda, K. Uejima, S. Shishiguchi, M. Hane
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引用次数: 3

Abstract

Sub-30nm MOSFET fabrication technology is proposed based on a dedicated process redesign suitable for a non-melt laser annealing technique. Two major features of the laser annealing (LA), i.e. diffusion-less and higher dopant activation enable us to apply more elaborate channel engineering, involving multiple halo implantations and optimized gate-predoping, that contributes further scaling of a functional gate-length (Lg) and effective gate-insulator thickness (Tinv), maintaining sufficient current drivability prior to any local stress engineering applied, for instance, ION = 650/340 [muA/mum] (nMOS/pMOS) at IOFF = 100 nA/mum, Vdd = 0.9V, were obtained for sub-30nm Lg (and also sidewall length) devices
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采用无扩散高活化激光退火技术的精确掺杂轮廓设计的30nm以下Mosfet制造技术
提出了一种适合于非熔体激光退火技术的亚30nm MOSFET制造工艺。激光退火(LA)的两个主要特点,即无扩散和高掺杂活化,使我们能够应用更精细的通道工程,包括多个晕注入和优化的栅极预掺杂,这有助于进一步缩放功能栅极长度(Lg)和有效栅极绝缘体厚度(Tinv),在应用任何局部应力工程之前保持足够的电流可驱动性,例如,在IOFF = 100 nA/mum时,离子= 650/340 [muA/mum] (nMOS/pMOS)。对于低于30nm的Lg(以及侧壁长度)器件,得到了Vdd = 0.9V
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2006 14th IEEE International Conference on Advanced Thermal Processing of Semiconductors
2006 14th IEEE International Conference on Advanced Thermal Processing of Semiconductors
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