Title :
CVD Co and its application to Cu damascene interconnections
Author :
Nogami, T. ; Maniscalco, J. ; Madan, A. ; Flaitz, P. ; DeHaven, P. ; Parks, C. ; Tai, L. ; Lawrence, B. St ; Davis, R. ; Murphy, R. ; Shaw, T. ; Cohen, S. ; Hu, C.-K. ; Cabral, C., Jr. ; Chiang, S. ; Kelly, J. ; Zaitz, M. ; Schmatz, J. ; Choi, S. ; Tsumur
Author_Institution :
IBM in Albany Nano Sci. & Technol. Res. Center, IBM Corp., Albany, NY, USA
Abstract :
Fundamental material interactions as pertinent to nano-scale copper interconnects were studied for CVD Co with a variety of micro-analytical techniques. Native Co oxide grew rapidly within a few hours (XPS). Incorporation of oxygen and carbon in the CVD Co films (by AES and SIMS) depended on underlying materials, such as Ta, TaN, or Ru. Copper film texture (by XRD) and agglomeration resistance (by AFM) showed correlations with amounts of in-film oxygen/carbon. Cobalt diffused through copper at normal processing temperatures (by SIMS). CVD Co demonstrated diffusion barrier performance to Cu (by Triangular Voltage Sweep, TVS), but not to O2. CVD Co was applied to 32 nm/22 nm damascene Cu interconnect fabrication in a scheme defined by the material studies. Lower post-CMP defect density and longer electromigration lifetimes were obtained.
Keywords :
chemical vapour deposition; electromigration; integrated circuit interconnections; nanotechnology; AES; AFM; CVD Co; Cu; Cu damascene interconnection; SIMS; XRD; agglomeration resistance; copper film texture; diffusion barrier; electromigration lifetime; micro-analytical technique; nano-scale copper interconnects; post-CMP defect density; triangular voltage sweep; Annealing; Atherosclerosis; Cobalt; Copper; Electromigration; Impurities; Microelectronics; Oxidation; Testing; X-ray scattering;
Conference_Titel :
Interconnect Technology Conference (IITC), 2010 International
Conference_Location :
Burlingame, CA
Print_ISBN :
978-1-4244-7676-3
DOI :
10.1109/IITC.2010.5510584
