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

Volume

45

Issue

6

fYear

1998

fDate

12/1/1998 12:00:00 AM

Firstpage

2352

Lastpage

2360

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;

fLanguage

English

Journal_Title

Nuclear Science, IEEE Transactions on

Publisher

ieee

ISSN

0018-9499

Type

jour

DOI

10.1109/23.736454

Filename

736454