Title :
Self-stressing structures for wafer-level oxide breakdown to 200 MHz
Author :
Snyder, Eric S. ; Tanner, Danelle M. ; Bowles, Matthew R. ; Swanson, Scot E. ; Anderson, Clinton H. ; Perry, Joseph P.
Author_Institution :
Electron. Quality/Reliability Center, Sandia Nat. Labs., Albuquerque, NM, USA
Abstract :
We have demonstrated for the first time high frequency (210 MHz) oxide breakdown at the wafer-level using on-chip, self-stressing test structures. This is the highest frequency oxide breakdown that has been reported. We used these structures to characterize the variation in oxide breakdown with frequency (from 1 Hz to over 200 MHz) and duty cycle (from 10% to 90%). Since the stress frequency, duty cycle and temperature are controlled by DC signals in these structures, we used conventional DC wafer-level equipment without any special modifications (such as high frequency cabling). This self-stressing structure significantly reduces the cost of performing realistic high frequency oxide breakdown experiments necessary for developing reliability models and building-in-reliability
Keywords :
CMOS integrated circuits; dielectric thin films; electric breakdown; integrated circuit reliability; integrated circuit testing; 1 Hz to 210 MHz; CMOS process; DC wafer-level equipment; high frequency oxide breakdown; onchip test structures; self-stressing structures; wafer-level oxide breakdown; Automatic testing; Circuit testing; Electric breakdown; Electronic equipment testing; Frequency; Hafnium; Integrated circuit reliability; Inverters; Semiconductor device breakdown; Stress;
Conference_Titel :
Integrated Reliability Workshop, 1994. Final Report., 1994 International
Conference_Location :
Lake Tahoe, CA
Print_ISBN :
0-7803-1908-7
DOI :
10.1109/IRWS.1994.515837
