A new physics-based model for time-dependent-dielectric-breakdown

Author

Schlund, Barry ; Messick, Cleston ; Suehle, John S. ; Chaparala, Prasad

Author_Institution

Motorola Inc., Scottsdale, AZ, USA

fYear

1996

fDate

April 30 1996-May 2 1996

Firstpage

84

Lastpage

92

Abstract

A new, physics-based model for time dependent dielectric breakdown has been developed, and is presented along with test data obtained by NIST on oxides provided by National Semiconductor. Testing included fields from 5.4 MV/cm to 12.7 MV/cm, and temperatures ranging from 60/spl deg/C to 400/spl deg/C. The physics, mathematical model, and test data, all confirm a linear, rather than an inverse field dependence. The primary influence on oxide breakdown was determined to be due to the dipole interaction energy of the field with the orientation of the molecular dipoles in the dielectric The resultant failure mechanism is shown to be the formation and coalescence of vacancy defects, similar to that proposed by Dumin et al. (1994).

Keywords

MIS devices; electric breakdown; failure analysis; semiconductor device models; semiconductor device reliability; vacancies (crystal); 60 to 400 degC; MOS devices; NIST; dipole interaction energy; failure mechanism; gate oxide breakdown; linear field dependence; molecular dipole orientation; physics-based model; time-dependent-dielectric-breakdown; vacancy defects; Dielectrics; Educational institutions; Impact ionization; NIST; Physics; Reliability engineering; Semiconductor device testing; Standards development; Thermal stresses; Tunneling;

fLanguage

English

Publisher

ieee

Conference_Titel

Reliability Physics Symposium, 1996. 34th Annual Proceedings., IEEE International

Conference_Location

Dallas, TX, USA

Print_ISBN

0-7803-2753-5

Type

conf

DOI

10.1109/RELPHY.1996.492065

Filename

492065