Analyze the ESD Discrepancy between Grounded-Gate and Floating-Gate Power Transistors with Gate Electric Field and Magnetic Field Induced by ESD

2022 IEEE International Symposium on the Physical and Failure Analysis of Integrated Circuits (IPFA) Pub Date : 2022-07-18 DOI:10.1109/IPFA55383.2022.9915710

Jian-Hsing Lee, K. Nidhi, Tingyou Lin, Hsueh-Chun Liao, Scott Lee, M. Ker

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引用次数: 2

Abstract

The mechanism of electrostatic-discharge (ESD) performance discrepancy between the floating gate and grounded-gate NMOS power transistors is analyzed in this work. A power transistor uses the bipolar current to discharge ESD current as the gate is grounded, while the channel current to discharge ESD current as the gate is floating since the gate voltage is couped up by the ESD. Under the time-varying ESD current induced magnetic field (B), the Lorentz force (J×B) has the less effect on the channel current of power transistor since it is controlled by the gate electric field. However, the Lorentz force can push the bipolar current to the finger edge of power transistor as all electrons are the free electrons after injected from the source into the p-substrate from the TCAD simulation. This is different from the classic model that ESD couples up the gate voltage of the floating-gate NMOS to turn-on all channels to give rise to the substrate currents on whole drain junction. So, the current crowded at the first turn-on region is prevented.

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分析了静电放电产生的栅极电场和磁场对地栅和浮栅功率晶体管静电放电差异的影响

分析了浮栅与地栅NMOS功率晶体管静电放电性能差异的机理。当栅极接地时，功率晶体管使用双极电流释放ESD电流，而当栅极释放ESD电流的通道电流是浮动的，因为栅极电压被ESD耦合。在时变ESD电流感应磁场(B)下，洛伦兹力(J×B)受栅极电场控制，对功率晶体管沟道电流的影响较小。然而，洛伦兹力可以将双极电流推向功率晶体管的指缘，因为所有电子都是TCAD模拟中从源注入p基板后的自由电子。这与经典模型不同，即ESD将浮栅NMOS的栅极电压耦合到所有通道，从而在整个漏极结上产生衬底电流。因此，避免了第一导通区域的电流拥挤。

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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2022 IEEE International Symposium on the Physical and Failure Analysis of Integrated Circuits (IPFA)

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