Andrew M. Greene

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Featured researches published by Andrew M. Greene.

international electron devices meeting | 2016

R. Xie; Pietro Montanini; Kerem Akarvardar; Neeraj Tripathi; Balasubramanian S. Haran; S. Johnson; Terence B. Hook; B. Hamieh; D. Corliss; Junli Wang; X. Miao; J. Sporre; Jody A. Fronheiser; Nicolas Loubet; M. Sung; S. Sieg; Shogo Mochizuki; Christopher Prindle; Soon-Cheon Seo; Andrew M. Greene; Jeffrey Shearer; A. Labonte; S. Fan; L. Liebmann; Robin Chao; A. Arceo; Kisup Chung; K. Y. Cheon; Praneet Adusumilli; H.P. Amanapu

We present a 7nm technology with the tightest contacted poly pitch (CPP) of 44/48nm and metallization pitch of 36nm ever reported in FinFET technology. To overcome optical lithography limits, Extreme Ultraviolet Lithography (EUV) has been introduced for multiple critical levels for the first time. Dual strained channels have been also implemented to enhance mobility for high performance applications.

symposium on vlsi technology | 2017

Nicolas Loubet; Terence B. Hook; Pietro Montanini; C.-W. Yeung; Sivananda K. Kanakasabapathy; M. Guillom; Tenko Yamashita; J. Zhang; X. Miao; Junli Wang; A. Young; Robin Chao; Min-Gu Kang; Zuoguang Liu; S. Fan; B. Hamieh; S. Sieg; Y. Mignot; W. Xu; Soon-Cheon Seo; Jae-yoon Yoo; Shogo Mochizuki; Muthumanickam Sankarapandian; Oh-Suk Kwon; A. Carr; Andrew M. Greene; Youn-sik Park; J. Frougier; Rohit Galatage; Ruqiang Bao

In this paper, for the first time we demonstrate that horizontally stacked gate-all-around (GAA) Nanosheet structure is a good candidate for the replacement of FinFET at the 5nm technology node and beyond. It offers increased Weff per active footprint and better performance compared to FinFET, and with a less complex patterning strategy, leveraging EUV lithography. Good electrostatics are reported at Lg=12nm and aggressive 44/48nm CPP (Contacted Poly Pitch) ground rules. We demonstrate work function metal (WFM) replacement and multiple threshold voltages, compatible with aggressive sheet to sheet spacing for wide stacked sheets. Stiction of sheets in long-channel devices is eliminated. Dielectric isolation is shown on standard bulk substrate for sub-sheet leakage control. Wrap-around contact (WAC) is evaluated for extrinsic resistance reduction.

symposium on vlsi technology | 2017

Gen Tsutsui; Huimei Zhou; Andrew M. Greene; Robert R. Robison; Jie Yang; Juntao Li; Christopher Prindle; John R. Sporre; Eric R. Miller; Derrick Liu; Ryan Sporer; Bob Mulfinger; Tim McArdle; Jin Cho; Gauri Karve; Fee Li Lie; Siva Kanakasabapathy; Rick Carter; Dinesh Gupta; Andreas Knorr; Dechao Guo; Huiming Bu

SiGe FinFET has been explored for its benefit of high current drivability provided by channel strain [1-5]. We have demonstrated SiGe CMOS FinFET at 10nm technology ground rules including epitaxial defectivity control, DC performance and reliability benefit [6-8]. One concern of SiGe FinFET is channel strain relaxation by fin cut process [9] inducing local layout effect (LLE), which is crucial for product design. In this paper, we thoroughly examined LLE in SiGe pFinFET and explored its mitigation techniques. Two techniques are proposed and demonstrated successful LLE mitigation, which drives forward SiGe FinFET insertion to technology.

international electron devices meeting | 2016

Gen Tsutsui; Ruqiang Bao; Kwan-yong Lim; Robert R. Robison; Reinaldo A. Vega; Jie Yang; Zuoguang Liu; Miaomiao Wang; Oleg Gluschenkov; Chun Wing Yeung; Koji Watanabe; Steven Bentley; Hiroaki Niimi; Derrick Liu; Huimei Zhou; Shariq Siddiqui; Hoon Kim; Rohit Galatage; Rajasekhar Venigalla; Mark Raymond; Praneet Adusumilli; Shogo Mochizuki; Thamarai S. Devarajan; Bruce Miao; B. Liu; Andrew M. Greene; Jeffrey Shearer; Pietro Montanini; Jay W. Strane; Christopher Prindle

Low Ge content SiGe-based CMOS FinFET is one of the promising technologies [1-2] offering solutions for both high performance and low power applications. In this paper, we established a competitive SiGe-based CMOS FinFET baseline and examined various elements for high performance offering. The performance elements in gate stack, channel doping, contact resistance, and junction have been explored to provide a cumulative 20% / 25% (n/pFET) performance enhancement. These elements provide a viable path towards performance enhancement for future technology nodes.

Archive | 2017