First Demonstration of 3D stacked Finfets at a 45nm fin pitch and 110nm gate pitch technology on 300mm wafers

2018 IEEE International Electron Devices Meeting (IEDM) Pub Date : 2018-12-01 DOI:10.1109/IEDM.2018.8614654

A. Vandooren, J. Franco, Z. Wu, B. Parvais, W. Li, L. Witters, A. Walke, L. Peng, V. Deshpande, N. Rassoul, G. Hellings, G. Jamieson, F. Inoue, K. Devriendt, L. Teugels, N. Heylen, E. Vecchio, T. Zheng, E. Rosseel, W. Vanherle, A. Hikavyy, G. Mannaert, B. Chan, R. Ritzenthaler, J. Mitard, L. Ragnarsson, N. Waldron, V. De Heyn, S. Demuynck, J. Boemmels, D. Mocuta, J. Ryckaert, N. Collaert

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引用次数: 20

Abstract

3 Dstacking using a sequential integration approach is demonstrated for finfet devices on 300mm wafers at a 45nm fin pitch and 110nm poly pitch technology. This demonstrates the compatibility of the 3D sequential approach for aggressive device density stacking at advanced nodes thanks to the tight alignment precision of the first processed top layer to the last processed bottom layer through the top silicon channel and bonding stack during 193nm immersion lithography. The top devices are junction-less devices fabricated at low temperature $(\mathrm{T}\leq 525^{\circ}\mathrm{C})$ in a top Si layer transferred by wafer-to-wafer bonding with a bonding dielectric stack down to 170nm. The top devices offer similar performance as the high temperature bulk finfet technology for LSTP applications. The use of TiN/TiA1/TiN/HfO2 gate stack provides the proper threshold voltage adjustment while the insertion of the LaSiOx dipole improves device performance and brings the BTI reliability within specification at low temperature.

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首次在300mm晶圆上演示45纳米翅片间距和110纳米栅极间距的3D堆叠finfet技术

采用顺序集成方法对300毫米晶圆上45纳米鳍间距和110纳米多间距技术的finet器件进行了Dstacking演示。由于在193nm浸没式光刻过程中，通过顶部硅通道和键合堆栈，第一个加工顶层到最后一个加工底层的紧密对准精度，这证明了3D顺序方法在先进节点上侵略性器件密度堆叠的兼容性。顶部器件是在低温$(\mathrm{T}\leq 525^{\circ}\mathrm{C})$下制造的无结器件，在顶部Si层中通过晶片到晶片键合传输，键合介电堆栈低至170nm。顶级器件为LSTP应用提供了与高温体finet技术相似的性能。TiN/TiA1/TiN/HfO2栅极堆栈的使用提供了适当的阈值电压调节，而LaSiOx偶极子的插入提高了器件性能，并使BTI在低温下的可靠性符合规格。

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 International Electron Devices Meeting (IEDM)

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