Title :
Channel cracking in low-k films on patterned multi-layers
Author :
Liu, X.H. ; Shaw, T.M. ; Lane, M.W. ; Rosenberg, R.R. ; Lane, S.L. ; Doyle, J.P. ; Restaino, D. ; Vogt, S.F. ; Edelstaeing, D.C.
Author_Institution :
IBM TJ Watson Res. Center, Yorktown Heights, NY, USA
Abstract :
This paper considers cracking of a low-k tensile film fabricated on top of a patterned multilayer. A finite element model has been established to study all the geometry effects of the top film and underlying layers. It is found that the driving force for film cracking, as calculated from the energy release rate, is greatly enhanced by the underlying layers of copper and low-k materials. The geometry dependence has been verified by a test structure. The results indicate that a low-k film that is intact when deposited on silicon may crack when integrated in a multilayer BEOL. IBM has successfully engineered a CVD SiCOH low-k film with reduced film stress and increased modulus without degrading the cohesive strength (or the dielectric constant). Accordingly, cracking of the film has been prevented even for the worst case interconnect structures.
Keywords :
chemical vapour deposition; copper; cracks; finite element analysis; integrated circuit interconnections; metallic thin films; multilayers; silicon compounds; CVD SiCOH low-k film; Cu; IBM; SiCOH; channel cracking; cohesive strength; copper; deposition; dielectric constant; energy release rate; film cracking; finite element model; geometry effect; interconnect structures; low-k materials; low-k tensile film; multilayer BEOL; patterned multilayer; reduced film stress; top film; underlying layers; Copper; Finite element methods; Geometry; Nonhomogeneous media; Power engineering and energy; Semiconductor films; Silicon; Solid modeling; Stress; Testing;
Conference_Titel :
Interconnect Technology Conference, 2004. Proceedings of the IEEE 2004 International
Print_ISBN :
0-7803-8308-7
DOI :
10.1109/IITC.2004.1345699
