论文信息 - Development of MOS Transistors for Radiation-Hardened Large Scale Integrated Circuits and Analysis of Radiation-Induced Degradation

Development of MOS Transistors for Radiation-Hardened Large Scale Integrated Circuits and Analysis of Radiation-Induced Degradation

Radiation-hardened MOSFETs were developed, and experimental results on their total dose degradation were collected to evaluate effects of three techniques for radiation hardening. The three techniques are; (1) adding a silicon-nitride layer onto the phospho-silicate glass passivation layer, (2) thinning of the field oxide by increasing resistance of the channel stopper, and (3) annealing the gate oxide at lower temperature. Technique (1) suppressed the leakage current generated by the parasitic MOSFET, because the negative threshold voltage shift of the parasitic MOSFET was compensated by the positive shift due to the interface states generated by hydrogen trapped in the oxide by the silicon nitride deposition. Furthermore, leakage current decreased with technique (2) as well. Technique (3) was not effective because the gate oxide is inherently thin. Results gotten using a linear model for the threshold voltage shift represented well the measured data up to 1.5 kGy(Si) at a dose rate of 5Gy(Si)/h.

[1] Anant G. Sabnis,et al. Process Dependent Build-Up of Interface States in Irradiated N-Channel MOSFETs , 1985, IEEE Transactions on Nuclear Science.

[2] P. S. Winokur,et al. Correlating the Radiation Response of MOS Capacitors and Transistors , 1984, IEEE Transactions on Nuclear Science.

[3] Richard E. Anderson. Post-Gate Plasma and Sputter Process Effects on the Radiation Hardness of Metal Gate CMOS Integrated Circuits , 1978, IEEE Transactions on Nuclear Science.

[4] M. Sakagami,et al. Prediction method for total dose effects on complementary metal oxide semiconductor integrated circuits using impulse response model for threshold voltage shift. , 1991 .

[5] C. Hawkins,et al. The Effect of Operating Frequency in the Radiation Induced Buildup of Trapped Holes and Interface States in MOS Devices , 1985, IEEE Transactions on Nuclear Science.

[6] T. P. Ma,et al. Ionizing radiation effects in MOS devices and circuits , 1989 .

[7] F. B. McLean. A Framework for Understanding Radiation-Induced Interface States in SiO2 MOS Structures , 1980, IEEE Transactions on Nuclear Science.

[8] Keith W. Golke,et al. Characterization Summary for a Radiation Hardened 16KX1 SRAM , 1986, IEEE Transactions on Nuclear Science.