3D sequential stacked planar devices on 300 mm wafers featuring replacement metal gate junction-less top devices processed at 525°C with improved reliability

2018 IEEE Symposium on VLSI Technology Pub Date : 2018-06-01 DOI:10.1109/VLSIT.2018.8510705

A. Vandooren, J. Franco, B. Parvais, Z. Wu, L. Witters, A. Walke, W. Li, L. Peng, V. Desphande, F. M. Bufler, N. Rassoul, G. Hellings, G. Jamieson, F. Inoue, G. Verbinnen, K. Devriendt, L. Teugels, N. Heylen, E. Vecchio, T. Zheng, E. Rosseel, W. Vanherle, A. Hikavyy, B. Chan, R. Ritzenthaler, G. Besnard, W. Schwarzenbach, G. Gaudin, I. Radu, B. Nguyen, N. Waldron, V. D. Heyn, D. Mocuta, N. Collaert

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引用次数: 16

Abstract

3D sequential integration requires top MOSFETs processed at low thermal budget, which can impair the device reliability. In this work, top junction-less device are fabricated with a maximum processing temperature of 525°C. The devices feature high k /metal replacement gate and low temperature Si:P and SiGe:B 60% raised SD for NMOS and PMOS respectively. Device matching, analog and RF performance of the top tier devices are in-line with state-of-the-art Si technology processed at high temperature (>1000°C). The top Si layer is transferred on CMOS planar bulk wafers with W metal-1 interconnects, using a SiCN to SiCN direct wafer bonding.

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在300毫米晶圆上的3D顺序堆叠平面器件，具有在525°C下加工的替代金属栅无结顶部器件，提高了可靠性

3D顺序集成需要在低热预算下处理顶级mosfet，这可能会损害器件的可靠性。在本工作中，制作了无顶结器件，最高加工温度为525℃。该器件具有高k /金属替换栅极和低温Si:P和SiGe:B，分别为NMOS和PMOS提高了60%的SD。顶级器件的器件匹配、模拟和射频性能符合在高温(>1000°C)下处理的最先进的Si技术。采用SiCN到SiCN的直接晶圆键合，将顶部Si层转移到具有W金属-1互连的CMOS平面块状晶圆上。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2018 IEEE Symposium on VLSI Technology

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