0.18µm CMOS热载流子电阻优化

2008 33rd IEEE/CPMT International Electronics Manufacturing Technology Conference (IEMT) Pub Date : 2008-11-01 DOI:10.1109/IEMT.2008.5507889

Sim Poh Ching, Yook Hyung Sun, C. Ping

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引用次数: 1

摘要

随着CMOS器件的进一步缩小，热载流子引起的退化已成为最重要的可靠性问题之一。在热载流子效应中，载流子被通道电场加速并被困在氧化物中。这些被捕获的电荷在测量的器件参数中引起时间相关的位移。随着时间的推移，可能会出现大量的设备参数退化，导致设备故障。为了提高器件的热载流子抗扰度，已经进行了降低和远离漏极区高电场的研究。评估的重点是植入物的能量和剂量因素，以实现更分级的器件连接。实验结果表明，热载子注入(HCI)的直流寿命提高了10倍，为抑制0.18 μm CMOS技术中的热载子效应指明了良好的方向。

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Optimization of hot carrier resistance for 0.18µm CMOS technology

With the further scaling down of CMOS devices, hot carrier induced degradation has become one of the most important reliability concerns. In the hot carrier effect, carriers are accelerated by the channel electric fields and become trapped in the oxide. These trapped charges cause time dependent shifts in measured device parameters. In time, substantial device parameter degradation can occur, resulting in device failure. Studies have been carried out to enhance device hot carrier immunity by reducing and departure the high electrical field from the drain area. The evaluations were focused on the implant energy and dose factors in order to achieve more graded device junction. The substantial result shows 10 times improvement in hot carrier injection (HCI) DC lifetime and reveals a good direction for suppression the hot carrier effects in 0.18 μm CMOS technology.

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来源期刊

2008 33rd IEEE/CPMT International Electronics Manufacturing Technology Conference (IEMT)

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