Gain degradation of lateral and substrate pnp bipolar junction transistors

The effect of dose rate on radiation-induced current gain degradation at 20 krad(Si) was quantified for lateral and substrate pnp bipolar transistors over the range of 0.001 to 294 rad(Si)/s. Degradation increases monotonically with decreasing dose rate, such that, at an emitter-to-base voltage of 0.7 V, radiation-induced excess base current differs by a factor of approximately eight at the extreme dose rates. Degradation shows little dependence on dose rate below 0.005 rad(Si)/s, suggesting that further degradation enhancement at space-like dose rates may be negligible. In addition, the effect of ambient temperature on radiation-induced gain degradation at 294 rad(Si)/s was thoroughly investigated over the range of 25 to 240/spl deg/C. Degradation is enhanced with increasing temperature while simultaneously being moderated by in situ annealing such that, for a given total dose, an optimum irradiation temperature for maximum degradation results. Optimum irradiation temperature decreases logarithmically with total dose and is larger and more sensitive to dose in the substrate device than in the lateral device. Based on the measurement of midgap interface trap density in the base oxide, enhancement in transistor gain degradation due to elevated temperature is explained as an increase in surface recombination velocity in the base. Maximum high dose rate degradation at elevated temperature closely approaches low dose rate degradation for both devices. Based on high-temperature irradiations, a flexible procedure for the accelerated prediction of low dose rate gain degradation at 20 krad(Si) is developed for each of the devices studied.

[1]  E. W. Enlow,et al.  Response of advanced bipolar processes to ionizing radiation , 1991 .

[2]  V. V. Belyakov,et al.  Use of MOS structures for the investigation of low-dose-rate effects in bipolar transistors , 1995 .

[3]  R. L. Pease,et al.  Modeling ionizing radiation induced gain degradation of the lateral PNP bipolar junction transistor , 1996 .

[4]  A. H. Johnston,et al.  A Total Dose Homogeneity Study of the 108a Operational Amplifier , 1979, IEEE Transactions on Nuclear Science.

[5]  B. Johlander,et al.  Dose rate and annealing effects on total dose response of MOS and bipolar circuits , 1995 .

[6]  peixiong zhao,et al.  Radiation effects at low electric fields in thermal, SIMOX, and bipolar-base oxides , 1996 .

[7]  A. Johnston,et al.  Models for Total Dose Degradation of Linear Integrated Circuits , 1987, IEEE Transactions on Nuclear Science.

[8]  Allan H. Johnston,et al.  Total dose effects in conventional bipolar transistors and linear integrated circuits , 1994 .

[9]  Allan H. Johnston,et al.  Enhanced damage in linear bipolar integrated circuits at low dose rate , 1995 .

[10]  C. Kermarrec,et al.  A double-polysilicon self-aligned npn bipolar process (ADRF) with optional NMOS transistors for RF and microwave applications , 1994, Proceedings of IEEE Bipolar/BiCMOS Circuits and Technology Meeting.

[11]  M. Gehlhausen,et al.  Elevated temperature irradiation of bipolar linear microcircuits , 1996 .

[12]  Allan H. Johnston The Application of Operational Amplifiers to Hardened Systems , 1977, IEEE Transactions on Nuclear Science.

[13]  T. Carriere,et al.  Total dose effects on negative voltage regulator , 1994 .

[14]  R. Pease,et al.  Dependence of total dose response of bipolar linear microcircuits on applied dose rate , 1994 .

[15]  Daniel M. Fleetwood,et al.  Using laboratory X-ray and cobalt-60 irradiations to predict CMOS device response in strategic and space environments , 1988 .

[16]  R. L. Pease,et al.  Hardness-assurance and testing issues for bipolar/BiCMOS devices , 1993 .

[17]  L. Terman An investigation of surface states at a silicon/silicon oxide interface employing metal-oxide-silicon diodes , 1962 .

[18]  peixiong zhao,et al.  Physical mechanisms contributing to enhanced bipolar gain degradation at low dose rates , 1994 .

[19]  Ronald D. Schrimpf Recent advances in understanding total-dose effects in bipolar transistors , 1995 .

[20]  R. L. Pease,et al.  Comparison of ionizing-radiation-induced gain degradation in lateral, substrate, and vertical PNP BJTs , 1995 .

[21]  R. L. Pease,et al.  Trends in the total-dose response of modern bipolar transistors , 1992 .

[22]  Allan H. Johnston,et al.  Enhanced damage in bipolar devices at low dose rates: effects at very low dose rates , 1996 .