A study of 28nm LDMOS HCI improvement by layout optimization

Ruoyuan Li, Yongsheng Yang, Fang Chen, Ling Tang, Zhengyong Lv, Byunghak Lee, Ling Sun, Weizhong Xu, Tzuchiang Yu
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引用次数: 5

Abstract

LDMOS (lateral diffused MOS) is an important class of device finding applications in high voltage and smart power management due to their compatibility with the standard CMOS process. However, high operational drain voltage makes LDMOS devices highly vulnerable to the damage caused by hot-carrier injection (HCI). In this paper, the various layout parameters of NLDMOS with shallow trench isolation (STI) are systematically studied to check HCI performance using 28nm Poly/SiON logic process, including effective channel length (Lc), a drift region and poly gate overlap (Lp), a drift region and Pwell overlap/space (Lw) and STI width (Ls). Extensive TCAD simulations and experiments reveal that small Lp and large Lw overlap can greatly improve NLDMOS substrate current and HCI performance without any additional process step or process modification. The physical mechanism behinds the results should be that the impact ionization has been driven further away from the Si/SiO2 interface with a reduction in magnitude, which can improve substrate current and HCI performance.
基于布局优化的28nm LDMOS HCI改进研究
由于其与标准CMOS工艺的兼容性,LDMOS(横向扩散MOS)是一类重要的器件,可用于高压和智能电源管理。然而,高工作漏极电压使得LDMOS器件极易受到热载流子注入(HCI)的损坏。本文采用28nm Poly/SiON逻辑工艺,系统研究了具有浅沟槽隔离(STI)的NLDMOS的各种布局参数,包括有效通道长度(Lc)、漂移区域和多栅极重叠(Lp)、漂移区域和Pwell重叠/空间(Lw)和STI宽度(Ls),以检验HCI性能。大量的TCAD模拟和实验表明,小Lp和大Lw重叠可以大大提高NLDMOS衬底电流和HCI性能,而无需任何额外的工艺步骤或工艺修改。结果背后的物理机制应该是,冲击电离被进一步远离Si/SiO2界面,并降低了幅度,这可以改善衬底电流和HCI性能。
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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