Title :
Growth and scaling of oxide conduction after breakdown
Author :
Linder, Barry P. ; Stathis, James H. ; Frank, David J. ; Lombardo, Salvatore ; Vayshenker, Alex
Author_Institution :
Res. Div., IBM T. J. Watson Res. Center, Yorktown Heights, NY, USA
fDate :
30 March-4 April 2003
Abstract :
Hard breakdown is shown to be a gradual process with the gate current increasing at a predictable rate, exponentially dependent on the instantaneous stress voltage. Adding the hard breakdown evolution time to the standard time to breakdown potentially reduces the projected fail rate of gate dielectrics by orders of magnitude. The scaling of the hard breakdown growth rate with respect to device area, substrate doping, oxide thickness, and channel length are explored. A two-voltage stress procedure is introduced that measures degradation rates on sub-micron devices several orders of magnitude more quickly than a conventional single voltage stress.
Keywords :
MOSFET; dielectric thin films; failure analysis; semiconductor device breakdown; semiconductor device reliability; NFETs; PFETs; channel length; degradation rates; device area; gate current; gate dielectrics; hard breakdown evolution time; hard breakdown growth rate; instantaneous stress voltage; oxide conduction growth; oxide conduction scaling; oxide thickness; projected fail rate; submicron devices; substrate doping; time to breakdown; two-voltage stress procedure; Breakdown voltage; Character generation; Circuits; Degradation; Dielectric breakdown; Doping; Electric breakdown; Microelectronics; Semiconductor process modeling; Stress measurement;
Conference_Titel :
Reliability Physics Symposium Proceedings, 2003. 41st Annual. 2003 IEEE International
Print_ISBN :
0-7803-7649-8
DOI :
10.1109/RELPHY.2003.1197781
