Proton effects in charge-coupled devices

Author

Hopkinson, G.R. ; Dale, C.J. ; Marshall, P.W.

Author_Institution

Sira Ltd., Chislehurst, UK

Volume

43

Issue

2

fYear

1996

fDate

4/1/1996 12:00:00 AM

Firstpage

614

Lastpage

627

Abstract

Basic mechanisms and ground-test data for radiation effects in solid-state imagers are reviewed, with a special emphasis on proton-induced effects on silicon charge-coupled devices (CCDs). For the proton fluxes encountered in the space environment, both transient ionization and displacement damage effects arise from single-particle interactions. In the former case, individual proton tracks will be seen; in the latter, dark-current spikes (or hot pixels) and trapping states that cause degradation in charge-transfer efficiency will be observed. Proton-induced displacement damage effects on dark current and charge transfer are considered in detail, and the practical implications for shielding, device hardening, and ground testing are discussed

Keywords

CCD image sensors; aerospace instrumentation; astronomical instruments; astronomical techniques; elemental semiconductors; infrared detectors; infrared imaging; ionisation; proton effects; semiconductor device testing; shielding; silicon; space vehicle electronics; ultraviolet detectors; Si; Si charge-coupled devices; charge transfer; charge-coupled devices; charge-transfer efficiency; dark current; dark-current spikes; degradation; displacement damage effects; ground testing; ground-test data; hardening; hot pixels; proton-induced effects; radiation effects; shielding; single-particle interactions; solid-state imagers; space environment; transient ionization; trapping states; Charge coupled devices; Dark current; Electron traps; Instruments; Laboratories; Proton effects; Radiation effects; Sensor arrays; Silicon; Solid state circuits;

fLanguage

English

Journal_Title

Nuclear Science, IEEE Transactions on

Publisher

ieee

ISSN

0018-9499

Type

jour

DOI

10.1109/23.490905

Filename

490905