Radiation induced leakage current and stress induced leakage current in ultra-thin gate oxides

Author

Ceschia, M. ; Paccagnella, A. ; Cester, A. ; Scarpa, A. ; Ghidini, G.

Author_Institution

Dipt. di Elettronica e Inf., Padova Univ., Italy

Volume

45

Issue

6

fYear

1998

fDate

12/1/1998 12:00:00 AM

Firstpage

2375

Lastpage

2382

Abstract

Low-field leakage current has been measured in thin oxides after exposure to ionising radiation. This Radiation Induced Leakage Current (RILC) can be described as an inelastic tunnelling process mediated by neutral traps in the oxide, with an energy loss of about 1 eV. The neutral trap distribution is influenced by the oxide field applied during irradiation, thus indicating that the precursors of the neutral defects are charged, likely to be defects associated with trapped holes. The maximum leakage current is found under zero-field condition during irradiation, and it rapidly decreases as the field is enhanced, due to a displacement of the defect distribution across the oxide towards the cathodic interface. The RILC kinetics are linear with the cumulative dose, in contrast with the power law found on electrically stressed devices

Keywords

CMOS integrated circuits; ULSI; electron traps; insulating thin films; integrated circuit reliability; leakage currents; radiation effects; tunnelling; IC reliability; cathodic interface; cumulative dose; deep-submicron CMOS; energy loss; inelastic tunnelling process; neutral traps; radiation induced leakage current; stress induced leakage current; ultra-thin gate oxides; zero-field condition; Acceleration; Capacitance; Capacitance-voltage characteristics; Carbon capture and storage; Doping; Electrons; Leakage current; Permittivity; Stress; Voltage;

fLanguage

English

Journal_Title

Nuclear Science, IEEE Transactions on

Publisher

ieee

ISSN

0018-9499

Type

jour

DOI

10.1109/23.736457

Filename

736457