Title :
Wafer level reliability assessment of stress-induced voiding
Author :
Hoang, H.H. ; MacNaughton, R.B. ; Lin, Y.S. ; Zamanian, M. ; Chen, F.S. ; Carpenter, E. ; Tullos, L. ; Tso, S. ; Liou, F.-T.
Author_Institution :
SGS-Thomson Microelectron., Carrollton, TX, USA
Abstract :
As device technology advances toward submicron geometry, the linewidth of VLSI metallization interconnects continues to scale down and stress-induced migration becomes an increasingly important issue. Wafer level stress-induced migration testing of metallization was introduced as a technique for obtaining greater levels of quality assurance with a shorter feedback time at an affordable cost. Slit-like voids are typically formed causing catastrophic open-circuit failures. The results indicate that metal linewidths of around 1 μm and below are more susceptible to stress-induced voiding. Multilevel submicron technology requires either a new metal or a barrier metal system such as TiN under metal-1. Furthermore, the use of a well designed look-ahead test vehicle has proven its effectiveness in assessing potential metallization reliability issues early in the technology development phase
Keywords :
VLSI; aluminium alloys; metallisation; reliability; titanium compounds; DLM; VLSI; affordable cost; barrier metal system; catastrophic open-circuit failures; feedback time; linewidth of VLSI metallization; look-ahead test vehicle; multilevel interconnection; quality assurance; reliability issues; slit like voids; stress-induced migration; stress-induced migration testing; stress-induced voiding; submicron geometry; wafer level reliability assessment; Circuit testing; Costs; Feedback; Integrated circuit interconnections; Metallization; Quality assurance; Stress; Tin; Vehicles; Very large scale integration;
Conference_Titel :
VLSI Multilevel Interconnection Conference, 1991, Proceedings., Eighth International IEEE
Conference_Location :
Santa Clara, CA
Print_ISBN :
0-87942-673-X
DOI :
10.1109/VMIC.1991.153033
