Title :
Diffusion ability of Stress Induced Voiding in advanced BEOL copper process
Author :
Huang, Chao ; Liang, James W. ; Juan, Alfons ; Su, K.C.
Author_Institution :
Reliability Technol. & Assurance Div., UMC Inc., Hsinchu, Taiwan
Abstract :
Stress Induced Voiding is strongly influenced by test key structure. Wider and longer interconnect will have larger total supply of vacancies for voiding than a narrower one (reservoir effect). The critical diffusion volume which could cause RC open failure of advanced node Cu process is about 100um2. The vacancy diffusion length is about ~250um, that means a vacancy that is incredibly far away could participate in the via voiding process through random diffusion, and the diffusion coefficient would be about 0.34cm2/sec. As was determined using Creep rate equation, the diffusion activation energy would be about 0.83eV, which might be consistent with an interface diffusion problem.
Keywords :
copper; creep; diffusion; integrated circuit interconnections; voids (solid); RC open failure; advanced BEOL copper process; creep rate equation; critical diffusion volume; diffusion activation energy; interface diffusion problem; random diffusion coefficient; reservoir effect; stress induced voiding process; test key structure; vacancy diffusion length; Copper; Creep; Reliability; Reservoirs; Resistance; Stress; Diffusion length; Diffusion volume; Plate structure; Reservoir effect; Stress Induced Voiding; Stress gradient; Stress migration; Vacancy source; creep rate;
Conference_Titel :
Physical and Failure Analysis of Integrated Circuits (IPFA), 2012 19th IEEE International Symposium on the
Conference_Location :
Singapore
Print_ISBN :
978-1-4673-0980-6
DOI :
10.1109/IPFA.2012.6306247
