Title :
Modeling low-dose-rate effects in irradiated bipolar-base oxides
Author :
Graves, R.J. ; Cirba, C.R. ; Schrimpf, R.D. ; Milanowski, R.J. ; Michez, A. ; Fleetwood, D.M. ; Witczak, S.C. ; Saigne, F.
Author_Institution :
SILVACO Int., Scottsdale, AZ, USA
fDate :
12/1/1998 12:00:00 AM
Abstract :
A physical model is developed to quantify the contribution of oxide-trapped charge to enhanced low-dose-rate gain degradation in bipolar junction transistors. Multiple-trapping simulations show that space charge limited transport is partially responsible for low-dose-rate enhancement. At low dose rates, more holes are trapped near the silicon-oxide interface than at high dose rates, resulting in larger midgap voltage shifts. The additional trapped charge near the interface causes an exponential increase in excess base current and a resultant decrease in current gain for some NPN bipolar technologies. Space charge effects also may be responsible for differences in interface trap formation at low and high dose rates
Keywords :
bipolar transistors; electron traps; insulating thin films; radiation effects; semiconductor device models; semiconductor device reliability; space-charge-limited conduction; bipolar junction transistors; current gain; excess base current; gain degradation; interface trap formation; irradiated bipolar-base oxides; low-dose-rate effects; midgap voltage shifts; multiple-trapping simulations; oxide-trapped charge; physical model; space charge limited transport; Bipolar integrated circuits; Crystallization; Degradation; Integrated circuit technology; Laboratories; MOSFETs; Modems; Positron emission tomography; Space technology; USA Councils;
Journal_Title :
Nuclear Science, IEEE Transactions on
