Calibration and electric characterization of p-MNOS RADFETs at different dose rates and temperatures
G. I. Zebrev, P. A. Zimin, E. V. Mrozovskaya, P. A. Chubunov, V. S., Anashin

TL;DR
This study investigates the radiation response and electrical behavior of p-MNOS RADFETs under various dose rates and temperatures, revealing effects like enhanced charge trapping and temperature sensitivity, supported by experimental and simulation data.
Contribution
It provides a comprehensive analysis of RADFET behavior at different conditions, integrating experimental results with modeling to explain dose rate and temperature effects.
Findings
Enhanced charge trapping at low dose rates (ELDRS) in thick gate dielectrics.
Radiation sensitivity varies with irradiation temperature.
Simulations accurately predict the observed dependencies.
Abstract
This paper describes the radiation response and I-V characteristics of the stacked p-MNOS based RADFETs measured at different dose rates and irradiation temperatures. It is shown that the enhanced charge trapping takes place at the interface of the thick gate dielectrics in the MNOS transistors at low dose rates (ELDRS). The sensitivity of the radiation effect to irradiation temperature has also experimentally revealed. We associate both effects with the temperature and dose rate dependence of the effective charge yield in the thick oxides described within the framework of the previously proposed model. We have also simulated the I-V characteristics of the transistors for different total doses and irradiation conditions. It has been found the used electric and radiation models consistently describe the observed dependencies of the RADFETs sensitivity on dose rates and irradiation…
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Taxonomy
TopicsSemiconductor materials and devices · Radiation Effects in Electronics · Advanced Memory and Neural Computing
