O. Semenov scite author profile

As the technology feature size is reduced, the thermal management of high-performance very large scale integrations (VLSIs) becomes an important design issue. The self-heating effect and nonuniform power distribution in VLSIs lead to performance and long-term reliability degradation. In this paper, we analyze the self-heating effect in high-performance sub-0.18-µm bulk and silicon-on-insulator (SOI) CMOS circuits using fast transient quasi-dc thermal simulations. The impact of the self-heating effect and technology scaling on the metallization lifetime and the gate oxide time-to-breakdown (TBD) reduction are also investigated. Based on simulation results, an optimized clock-driver design is proposed. The proposed layout reduces the hot-spot temperature by 15 • C and by 7 • C in 0.09-µm SOI and bulk CMOS technologies, respectively.

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ESD Protection Device and Circuit Design for Advanced CMOS Technologies

Semenov

Sarbishaei

Sachdev

2008

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Novel gate and substrate triggering techniques for deep sub-micron ESD protection devices

Semenov

Sarbishaei

Axelrad

et al. 2006

Microelectronics Journal

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Effect of cmos technology scaling on thermal management during burn-in

Semenov

Vassighi

Sachdev

et al. 2003

IEEE Trans. Semicond. Manufact.

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Burn-in is a quality improvement procedure challenged by the high leakage currents that are rapidly increasing with IC technology scaling. These currents are expected to increase even more under the new burn-in environments leading to higher junction temperatures, possible thermal runaway, and yield loss during burn-in. The authors estimate the increase in junction temperature with technology scaling. Their research shows that under normal operating conditions, the junction temperature is increasing 1.45 /generation. The increase in junction temperature under the burn-in condition was found to be exponential. The range of optimal burn-in voltage and temperature is reduced significantly with technology scaling.

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CMOS IC Technology Scaling and Its Impact on Burn-In

Vassighi

Semenov

Sachdev

et al. 2004

IEEE Trans. Device Mater. Relib.

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This article describes how CMOS IC technology scaling impacts semiconductor burn-in and burn-in procedures.Burn-in is a quality improvement procedure challenged by the high leakage currents that are rapidly increasing with IC technology scaling. These currents are expected to increase even more under the new burn-in environments leading to higher junction temperatures, possible thermal runaway, and yield loss of good parts during burn-in. The paper discusses the effect of junction temperature on device reliability, aging, and burn-in procedure optimization. The effect of device thermal runaway and the requirements it forces on commercial burn-in ovens, device package, and device cooling are also described.

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O. Semenov

Impact of Self-Heating Effect on Long-Term Reliability and Performance Degradation in CMOS Circuits

ESD Protection Device and Circuit Design for Advanced CMOS Technologies

Novel gate and substrate triggering techniques for deep sub-micron ESD protection devices

Effect of cmos technology scaling on thermal management during burn-in

CMOS IC Technology Scaling and Its Impact on Burn-In

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