Device Temperature Reduction Methodology with a New Layout Drawing Technique for Ultra-thin FET

2021 IEEE Region 10 Symposium (TENSYMP) Pub Date : 2021-08-23 DOI:10.1109/TENSYMP52854.2021.9550978

Minhyun Jin, S. Kim, Minkyu Song

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Abstract

Conventionally, conductive material stacks composed of many metals and holes on silicon devices have kept excellent thermal paths which reduces junction temperature. However, according to the development of CMOS process technology, parasitic capacitance are also rapidly increasing and the thermal paths are also degrading. Thus, many ultra-thin FETs (Field Effect Transistor) are recently suffering from high temperature device problems. In this paper, device temperature reduction methodology with a new layout drawing technique is proposed for ultra-thin CMOS FETs. To verify the proposed new layout drawing technique, the secondary effects of various thermal paths with different metal stacks on junction temperature are analyzed, in terms of power consumption, oscillation frequency of ring oscillators, and etc. From the measured results of the oscillators, it is shown that the best heat-path design has about a 20%-lower change in junction temperature and a 1.5% higher oscillation frequency, compared to the conventional layouts. Furthermore, it is also shown that the proposed layout technique should be more effective with the ultra-thin FETs process rather than with the planar CMOS process.

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一种新的超薄场效应管的器件温度降低方法

传统上，硅器件上由许多金属和孔组成的导电材料堆栈保持了良好的热路径，从而降低了结温。然而，随着CMOS工艺技术的发展，寄生电容也在迅速增加，热路径也在退化。因此，近年来许多超薄场效应晶体管(fet)都受到高温器件问题的困扰。针对超薄CMOS场效应管，提出了一种新的器件温度降低方法。为了验证所提出的新布局绘制技术，分析了不同金属堆叠的不同热路径对结温的二次影响，包括功耗、环形振荡器的振荡频率等。从振荡器的测量结果来看，与传统布局相比，最佳热路设计的结温变化降低了约20%，振荡频率提高了1.5%。此外，还表明，该布局技术在超薄fet工艺中比在平面CMOS工艺中更有效。

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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2021 IEEE Region 10 Symposium (TENSYMP)

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