Device and Circuit Performance of the Future Hybrid III-V and Ge-Based CMOS Technology

Brahim Benbakhti; Kah Hou Chan; Ali Soltani; Karol Kalna

doi:10.1109/TED.2016.2603188

Device and Circuit Performance of the Future Hybrid III-V and Ge-Based CMOS Technology

Brahim Benbakhti, Kah Hou Chan, Ali Soltani, Karol Kalna

Research output: Contribution to journal › Article › peer-review

6 Citations (Scopus)

Abstract

The device and circuit performance of a 20-nm gate length InGaAs and Ge hybrid CMOS based on an implant free quantum well (QW) device architecture is studied using a multiscale approach combining ensemble Monte Carlo simulation, drift-diffusion simulation, compact modeling, and TCAD mixed-mode circuit simulation. We have found that the QW and doped substrate, used in the hybrid CMOS, help to reduce shortchannel effects by enhancing carrier confinement. The QW also reduces the destructive impact of a low density of states in III-V materials. In addition, the calculated access resistance is found to be a much lower than in Si counterparts thanks to a heavily doped overgrowth source/drain contact. We predict an overall low gate capacitance and a large drive current when compared with Si-CMOS that leads to a significant reduction in a circuit propagation time delay (~5.5 ps).

Original language	English
Article number	7563860
Pages (from-to)	3893-3899
Number of pages	7
Journal	IEEE Transactions on Electron Devices
Volume	63
Issue number	10
DOIs	https://doi.org/10.1109/TED.2016.2603188
Publication status	Published - Oct 2016
Externally published	Yes

Keywords

CMOS
Ge
III-V
Monte Carlo (MC)
TCAD
compact modeling
drift diffusion (DD)

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10.1109/TED.2016.2603188

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title = "Device and Circuit Performance of the Future Hybrid III-V and Ge-Based CMOS Technology",

abstract = "The device and circuit performance of a 20-nm gate length InGaAs and Ge hybrid CMOS based on an implant free quantum well (QW) device architecture is studied using a multiscale approach combining ensemble Monte Carlo simulation, drift-diffusion simulation, compact modeling, and TCAD mixed-mode circuit simulation. We have found that the QW and doped substrate, used in the hybrid CMOS, help to reduce shortchannel effects by enhancing carrier confinement. The QW also reduces the destructive impact of a low density of states in III-V materials. In addition, the calculated access resistance is found to be a much lower than in Si counterparts thanks to a heavily doped overgrowth source/drain contact. We predict an overall low gate capacitance and a large drive current when compared with Si-CMOS that leads to a significant reduction in a circuit propagation time delay (~5.5 ps).",

keywords = "CMOS, Ge, III-V, Monte Carlo (MC), TCAD, compact modeling, drift diffusion (DD)",

author = "Brahim Benbakhti and Chan, {Kah Hou} and Ali Soltani and Karol Kalna",

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AU - Soltani, Ali

AU - Kalna, Karol

PY - 2016/10

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KW - compact modeling

KW - drift diffusion (DD)

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Device and Circuit Performance of the Future Hybrid III-V and Ge-Based CMOS Technology

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Keywords

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