摘要
The total ionizing dose(TID) effect is a key cause for the degradation/failure of semiconductor device performance under energetic-particle irradiation. We developed a dynamic model of mobile particles and defects by solving the rate equations and Poisson's equation simultaneously, to understand threshold voltage shifts induced by TID in silicon-based metal–oxide–semiconductor(MOS) devices. The calculated charged defect distribution and corresponding electric field under different TIDs are consistent with experiments. TID changes the electric field at the Si/SiO_(2) interface by inducing the accumulation of oxide charged defects nearby, thus shifting the threshold voltage accordingly. With increasing TID, the oxide charged defects increase to saturation, and the electric field increases following the universal 2/3 power law. Through analyzing the influence of TID on the interfacial electric field by different factors, we recommend that the radiation-hardened performance of devices can be improved by choosing a thin oxide layer with high permittivity and under high gate voltages.
作者
陆广宝
刘俊
张传国
高扬
李永钢
Guangbao Lu;Jun Liu;Chuanguo Zhang;Yang Gao;Yonggang Li(Key Laboratory of Materials Physics,Institute of Solid State Physics,HFIPS,Chinese Academy of Sciences,Hefei 230031,China;University of Science and Technology of China,Hefei 230026,China)
基金
Project supported by the Science Challenge Project of China (Grant No.TZ2018004)
the National Natural Science Foundation of China (Grant Nos.11975018 and 11775254)
the National MCF Energy R&D Program of China (Grant No.2018YEF0308100)
the outstanding member of Youth Innovation Promotion Association CAS (Grant No.Y202087)。
