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In this paper,total ionizing dose effect of NMOS transistors in advanced CMOS technology are examined.The radiation tests are performed at ~(60)Co sources at the dose rate of 50 rad(Si)/s.The investigation’s results show that the radiation-induced charge buildup in the gate oxide can be ignored,and the field oxide isolation structure is the main total dose problem.The total ionizing dose(TID) radiation effects of field oxide parasitic transistors are studied in detail.An analytical model of radiation defect charge induced by TID damage in field oxide is established.The Ⅰ-Ⅴ characteristics of the NMOS parasitic transistors at different doses are modeled by using a surface potential method.The modeling method is verified by the experimental Ⅰ-Ⅴ characteristics of 180 nm commercial NMOS device induced by TID radiation at different doses.The model results are in good agreement with the radiation experimental results,which shows the analytical model can accurately predict the radiation response characteristics of advanced bulk CMOS technology device.
In this paper, total ionizing dose effect of NMOS transistors in advanced CMOS technology are examined. The radiation tests are performed at ~ (60) Co sources at the dose rate of 50 rad (Si) /s.The investigation’s results show that the radiation -induced charge buildup in the gate oxide can be ignored, and the field oxide isolation structure is the main total dose problem. the total ionizing dose (TID) radiation effects of field oxide parasitic transistors are studied in detail. An analytical model of radiation defect charge induced by TID damage in field oxide is established. The Ⅰ-Ⅴ characteristics of the NMOS parasitic transistors at different doses are modeled by using a surface potential method. The modeling method is verified by the experimental Ⅰ-Ⅴ characteristics of 180 nm commercial NMOS device induced by TID radiation at different doses. The model results are in good agreement with the radiation experimental results, which shows the analytical model can accurately predict the radiat ion response characteristics of advanced bulk CMOS technology device.