Book contents
- Electromigration in Metals
- Electromigration in Metals
- Copyright page
- Dedication
- Contents
- Preface
- 1 Introduction to Electromigration
- 2 Fundamentals of Electromigration
- 3 Thermal Stress Characteristics and Stress-Induced Void Formation in Aluminum and Copper Interconnects
- 4 Stress Evolution and Damage Formation in Confined Metal Lines under Electric Stressing
- 5 Electromigration in Cu Interconnect Structures
- 6 Scaling Effects on Microstructure of Cu and Co Nanointerconnects
- 7 Analysis of Electromigration-Induced Stress Evolution and Voiding in Cu Damascene Lines with Microstructure
- 8 Massive-Scale Statistical Studies for Electromigration
- 9 Assessment of Electromigration Damage in Large On-Chip Power Grids
- Index
- References
3 - Thermal Stress Characteristics and Stress-Induced Void Formation in Aluminum and Copper Interconnects
Published online by Cambridge University Press: 05 May 2022
Book contents
- Electromigration in Metals
- Electromigration in Metals
- Copyright page
- Dedication
- Contents
- Preface
- 1 Introduction to Electromigration
- 2 Fundamentals of Electromigration
- 3 Thermal Stress Characteristics and Stress-Induced Void Formation in Aluminum and Copper Interconnects
- 4 Stress Evolution and Damage Formation in Confined Metal Lines under Electric Stressing
- 5 Electromigration in Cu Interconnect Structures
- 6 Scaling Effects on Microstructure of Cu and Co Nanointerconnects
- 7 Analysis of Electromigration-Induced Stress Evolution and Voiding in Cu Damascene Lines with Microstructure
- 8 Massive-Scale Statistical Studies for Electromigration
- 9 Assessment of Electromigration Damage in Large On-Chip Power Grids
- Index
- References
Summary
This chapter first showed how electromigration for the on-chip interconnects is distinctly different from that of bulk metals. As the microelectronics technology rapidly advances following Moore’s law, electromigration becomes a key reliability problem for on-chip interconnects. This significantly changes the characteristics of electromigration, rendering thermal stresses as equally important in controlling mass transport and damage formation in the interconnects. This led to the discovery of the Blech short-length effect, establishing the concept of a critical current density-length (jLc) product as an important reliability criterion for on-chip interconnects. In this chapter, thermal stress characteristics and stress-induced void formation in passivated Al and Cu lines are investigated. The effect of dielectric confinement on thermal stress characteristics is discussed and verified by results of X-ray diffraction measurements of passivated Al and Cu lines. Then stress relaxation in passivated Al and Cu lines is discussed and correlated to stress-induced void formation.
Keywords
- Type
- Chapter
- Information
- Electromigration in MetalsFundamentals to Nano-Interconnects, pp. 34 - 79Publisher: Cambridge University PressPrint publication year: 2022
References
Blech, A. and Sello, H., The failure of thin aluminum current carrying strips on oxidized silicon, Fifth Annual Symposium on the Physics of Failure in Electronics (1966), 496–505.Google Scholar
Schwartz, G. C. and Srikrishnan, K. V., Metallization. Handbook of Semiconductor Interconnection Technology, 2nd ed., ed. Schwartz, G. C. and Srikrishnan, K. V. (London: Taylor & Francis Group, 2006), 311–384.Google Scholar
Moore, G. E., Cramming more components onto integrated circuits, Electronics 38 (8) (1965), 8–11.Google Scholar
Edelstein, D., Heidenreich, J, Goldblatt, R, et al. Full copper wiring in a sub-0.25 micron CMOS ULSI technology, Tech. Dig. IEEE International Electron Devices Conference (1997), 773–776.Google Scholar
International Technology Roadmap for Semiconductors, Interconnect Section, 2007 Edition. Semiconductor Industry Association (2007).Google Scholar
Blech, I. A., Electromigration in thin aluminum films on titanium nitride. Journal of Applied Physics 47 (1976) 1203–1208.Google Scholar
Blech, I. A. and Herring, C., Stress generation by electromigration. Applied Physics Letters 29 (1976) 131–133.Google Scholar
Blech, I. A. and Tai, K. L., Measurement of stress gradients generated by electromigration, Applied Physics Letters 30 (1977), 387.Google Scholar
Klema, J., Pyle, R., and Domangue, E., Reliability implications of nitrogen contamination during deposition of sputtered aluminum/silicon metal films, IEEE Proceedings International. Reliability Physics Symposium 22 (1984), 1–5.Google Scholar
Curry, J., Fitzgibbon, G., Guan, Y., Muollo, R., Nelson, G., and Thomas, A., New failure mechanisms in sputtered aluminum-silicon films, IEEE Proceedings International. Reliability Physics Symposium 22 (1984), 6– 10.Google Scholar
Alam, S. M., Gan, C. L., Thompson, C. V., and Troxel, D. E., Reliability computer-aided design tool for full-chip electromigration analysis and comparison with different interconnect metallizations. Microelectronics Journal 38 (2007), 463–473.Google Scholar
Korhonen, M. A., Borgesen, P., and Li, Che-Yu, Mechanisms of stress-induced and electromigration-induced damage in passivated narrow metallizations on rigid substrates, Materials Research Society Bulletin 17 (1992), 61–69.Google Scholar
Korhonen, M. A., Black, R. D., and Li, C-Y., Stress relaxation of passivated aluminum line metallizations on silicon substrates, Journal of Applied Physics 69 (1991), 1748.Google Scholar
Korhonen, M. A., Borgesen, P., and Li, C-Y., Thermal stress and stress induced voiding in passivated narrow line metallizations. Thermal Stress and Strain in Microelectronics Packaging, ed. Lau, J. H. (New York: Van Nostrand Reinhold, 1992), 133.Google Scholar
Steinwall, J. E. and Johnson, H. H., Mechanical properties of thin film aluminum fibers: grain size effects. Thin films: stresses and mechanical properties II. Materials Research Society Symposium Proceedings 188, ed. Doerner, M., Oliver, W. C., Pharr, G. M., and Brotzen, F. R. (1990), 177.Google Scholar
Paszkiet, C. A., Korhonen, M. A., and Li, C-Y., The effect of a passivation over-layer on the mechanisms of stress relaxation in continuous films and narrow lines of aluminum, Materials Reliability Issues in Microelectronics, ed. Lloyd, J.R., Ho, P.S., Sah, C.T., and Yost, F. (Materials Resource Society Symposium Proceedings 225 ( 1991), 161.Google Scholar
Ashby, M. F., The deformation of plastically non-homogeneous materials, Philosophical Magazine 21 , (1970), 299–424.Google Scholar
Nix, W. D., Mechanical properties of thin films. Metallurgical and Materials Transactions A, 20 (1989), 2217–2245.Google Scholar
Vinci, R. P., Zielinski, E. M., and Bravman, J. C., Thermal strain and stress in copper thin films, Thin Solid Films 262 (1995), 142–153.Google Scholar
Kasthurirangan, J., Thermal stress and microstructure in Al(Cu) and Cu interconnects for advanced ULSI applications, unpublished Ph.D. dissertation, Materials Science and Engineering, University of Texas at Austin, 1998.Google Scholar
Kasthurirangan, J., Du, Y. and Ho, P. S. et al., Thermal stresses in Cu damascene submicron line structures, AIP Conference Proceedings 491 (1999), 304–314.Google Scholar
Gardner, D. S., Onuki, J., Kudoo, K., Misawa, Y., and Vu, Q. T., Encapsulated copper interconnection devices using sidewall barriers, Thin Solid Films 262 (1995), 104–119.Google Scholar
Flinn, P. A., Gardner, D. S. and Nix, W. D., Measurement and interpretation of stress in aluminum-based metallization as a function of thermal history, IEEE Transactions on Electron Devices 34 (1987), 689–698.Google Scholar
Doerner, M. F., Gardner, D. S., and Nix, W. D., Plastic properties of thin films on substrates as measured by submicron indentation hardness and substrate curvature techniques, Journal of Materials Research 1 (1986) 845–851.Google Scholar
Noyan, I. C. and Cohen, J. B., Residual Stress Measurement by Diffraction and Interpretation (New York: Springer, 1987).Google Scholar
Segmuller, A. S. and Murakami, M., Analytical Techniques for Thin Films, Treatise on Materials Science and Technology, Vol. 27 (San Diego: Academic Press, 1988), 143–200.Google Scholar
Rhee, S. H., Thermal stress behaviors of Al(Cu)/low-k and Cu/low-k submicron interconnect structures, unpublished PhD dissertation, Materials Science and Engineering, University of Texas at Austin, 2001.Google Scholar
Clarke, A. P., High intensity X-ray instrumentation for residual strain measurements in composites and textured materials, unpublished PhD dissertation, Queen’s University at Kingston, 1993, 174.Google Scholar
Yagi, H., Niwa, H., Hosoda, T., Inoue, M., and Tsuchikawa, H., Analytical calculation and direct measurement of stress in an aluminum interconnect of very large scale integration, American Institute for Physics Conference Proceedings 263 (1992), 44.Google Scholar
Niwa, H., Yagi, H., Tsuchikawa, H., and Kato, M., Stress distribution in an aluminum interconnect of very large scale integration, Journal of Applied Physics 68 (1990), 328.Google Scholar
Sauter, A. I. and Nix, W. D., Finite element calculations of thermal stresses in passivated and unpassivated lines bonded to substrates, Thin Films: Stresses and Mechanical Properties II, ed. Doerner, M., Oliver, W. C., Pharr, G. M., and Brotzen, F. R. (Pittsburgh: Materials Research Society Symposium Proceedings 188 (1990), 15.Google Scholar
Yeo, I.-S., Anderson, S. G. H., Ho, P. S., and Hu, C. K., Characteristics of thermal stresses in Al(Cu) fine lines. II. Passivated line structures, Journal of Applied Physics 78, (1995), 953–964.Google Scholar
Chaudhari, P., Plastic properties of polycrystalline thin films on a substrate, Philosophical Magazine A 39 (1979), 507–516.Google Scholar
Wang, P. H., Thermal stresses and electromigration behaviors of Al/low k polymer interconnect structures, unpublished PhD dissertation, University of Texas at Austin (1997).Google Scholar
Edelstein, D., Heidenreich, J., Goldblatt, R., et al. Full copper wiring in a sub-0.25 micron CMOS ULSI technology, Tech. Dig. IEEE International Electron Devices Conference (1997), 773–776.Google Scholar
Rosenberg, R., Edelstein, D. C., Hu, C.-K., and Rodbell, K. P., Copper metallization for high performance silicon technology, Annual Review of+ Materials Science 30 (2000), 229–262.Google Scholar
Gambino, J., Chen, F., and He, J., Copper interconnect technology for the 32 nm node and beyond, 2009 IEEE Custom Integrated Circuits Conference, Rome (2009), 141–148, doi: 10.1109/CICC.2009.5280904.Google Scholar
Rhee, S. H., Du, Y., and Ho, P. S., Thermal stress characteristics of Cu/oxide and Cu/low- submicron interconnect structures, Journal of Applied Physics 93 (2003), 3926–3933.Google Scholar
Besser, P. R., Joo, Y.-C., Winter, D., Van Ngo, M., and Ortega, R., Mechanical stresses in aluminum and copper interconnect lines for 0.18 µm logic technologies, Materials Research Society Symposium Proceedings 563, (1999), 189–200.Google Scholar
Besser, P. R., Zschech, E., Blum, W., et al. Microstructural characterization of inlaid copper interconnect lines. Journal of Electronics Materials 30 (2001) 320–330.Google Scholar
Zhang, H., Cargill, G. S., and Maniatty, A. M., Thermal strains in passivated aluminum and copper conductor lines, Journal of Materials Research 26 (2011), 633–639.Google Scholar
Wang, P.-C., Cargill, G. S., and Hu, C.-K., Local strain measurements during electromigration, American Institute for Physics Conference Proceedings 491 (1999), 112–122.Google Scholar
Wilson, C. J., Croes, K., Zhao, C., et al., Synchrotron measurement of the effect of linewidth scaling on stress in advanced Cu/low k interconnects, Journal of Applied Physics 106 (2009), 053524.Google Scholar
Korhonen, M. A., Paszkiet, C. A., and Li, C-Y., Mechanisms of thermal stress relaxation and stress-induced voiding in narrow aluminum-based metallizations, Journal of Applied Physics 69 (1991), 8083–8091.Google Scholar
Okabayashi, H., Stress-induced void formation in metallization for integrated circuits, Materials and Science Engineering R 11 (1993), 191–241.Google Scholar
Sullivan, T. D., Stress-induced voiding in microelectronic metallization: void growth models and refinements, Annual Reviews in Materials Science 26 ( 1996), 333–364.Google Scholar
Fischer, A. H. and Zitzelsberger, A. E., The quantitative assessment of stress-induced voiding in process qualification, 2001 IEEE International Reliability Physics Symposium Proceedings 39th Annual (2001), 334–340.Google Scholar
Ogawa, E. T., McPherson, J. W., Rosal, J. A., et al., Stress-induced voiding under vias connected to wide Cu metal leads, 40th Annual International Reliability Physics Symposium (IRPS) (2002), 312–331.Google Scholar
Lin, H. Y., Lee, S. C., and Oates, A. S., Characterization of stress-voiding of Cu/low k narrow lines, 46th International Reliability Physics Symposium (2008), 687–688.Google Scholar
Tőkei, Z., Croes, K., and Beyer, G. P., Reliability of copper low-k interconnects, Microelectronic Engineering 87, (2010), 348–354.Google Scholar
Rosenberg, R., and Ohring, N., Void formation and growth during electromigration in thin films, Journal of Applied Physics 42 (1971) 5671–5679.Google Scholar
Nix, W. D. and Arzt, E., On void nucleation and growth in metal interconnect lines and electromigration conditions, Metallurgical and Materials Transactions A 23 (1992), 2007–2013.Google Scholar
Suo, Z., Reliability of interconnect structures. Volume 8: Interfacial and Nanoscale Failure. Comprehensive Structural Integrity, ed. Gerberich, W. and Yang, W. (Amsterdam: Elsevier, 2003), 265–324.Google Scholar
Yeo, I.-S., Ho, P. S., Anderson, S. G. H., and Kawasaki, H., Stress relaxation and void formation in passivated Al(Cu) line structures, AIP Conference Proceedings 418 (1998), 262–276.Google Scholar
Tezaki, A., Mineta, T., and Egawa, H., Measurement of three dimensional stress and modeling of stress induced migration failure in aluminum interconnects, 1990 IEEE International Reliability Physics Symposium Proceedings 28th Annual (1990), 221–229.Google Scholar
McPherson, J. W. and Dunn, C. F., A model for stress-induced metal notching and voiding in very large-scale-integrated Al-Si(1%) metallization, Journal of Vacuum Science and Technology B 5 ( 1987), 1321–1325.Google Scholar
Yue, J. T., Funsten, W. P., and Taylor, R. V., Stress induced voids in aluminium interconnects during IC processing, IEEE International Reliability Physics Symposium Proceedings 23 (1985), 126.Google Scholar
Hu, C. K. and Harper, J. M. E., Copper interconnects and reliability, Materials Chemistry and Physics 52 (1998), 5–16.Google Scholar
Ogawa, E., Lee, K. D., and Ho, P. S., Electromigration reliability issues in dual-damascene Cu interconnections, IEEE Transactions on Reliability 51 (2002), 403–419.Google Scholar
Hu, C. K., Rosenberg, R., and Lee, K. Y., Electromigration path in Cu thin film lines, Applied Physics Letters 74 (1999), 2945.Google Scholar
Besser, P., Marathe, A., Zhao, L., Herrick, M., Capasso, C., and Kawasaki, H., Optimizing the electromigration performance of copper interconnects, IEDM Technical Digest 2000 (Piscataway: IEEE, 2000), 119.Google Scholar
Lane, M. W., Liniger, E. G., and Lloyd, J. R., Relationship between interfacial adhesion and electromigration in Cu metallization, Journal of Applied Physics 93 , 1417 (2003), 1417.Google Scholar
Hu, C. K., Gignac, L., Rosenberg, R., et al., Reduced electromigration of Cu wires by surface coating, Applied Physics Letters 81 , (2002), 1782.Google Scholar
Flinn, P. A., Measurement and interpretation of stress in copper films as a function of thermal history, Journal of Materials Research 6 ( 1991), 1498–1501.Google Scholar
Thouless, M. D., Gupta, J., and Harper, J. M. E., Stress development and relaxation in copper films during thermal cycling, Journal of Materials Research 8 (1993), 1845–1852.Google Scholar
Vinci, R. P., Zielinski, E. M., and Bravman, J. C., Thermal strain and stress in copper thin films, Thin Solid Films 262 (1995), 142–151.Google Scholar
Shen, Y. L., Suresh, S., He, M. Y., et al., Stress evolution in passivated thin films of Cu on silica substrates, Journal of Materials Research 13, (1998), 1928–1937.Google Scholar
Keller, R. M., Baker, S. P., and Arzt, E., Quantitative analysis of strengthening mechanisms in thin Cu films: effects of film thickness, grain size, and passivation, Acta Materialia 47 (1999), 1307–1317.Google Scholar
Thouless, M. D., Effect of surface diffusion on the creep of thin films and sintered arrays of particles, Acta Metallurgica et Materialia 41 (1993), 1057–1064.Google Scholar
Gao, H., Zhang, L., Nix, W. D., Thompson, C. V., and Arzt, E., Crack-like grain-boundary diffusion wedges in thin metal films, Acta Materialia 47 ( 1999), 2865–2878.Google Scholar
Gan, D., Thermal stresses and stress relaxation in copper metallization for ULSI interconnects, unpublished PhD dissertation, Materials Science and Engineering, University of Texas at Austin, 2005.Google Scholar
Gan, D. et al. Effect of passivation on stress relaxation in electroplated copper films, Journal of Materials Research 21, 6 (June 2006), doi: 10.1557/JMR.2006.0196.Google Scholar
Lloyd, J. R., Lane, M. W., Liniger, E. G., Hu, C-K., Shaw, T. M., and Rosenberg, R., Electromigration and adhesion, IEEE Transactions on Device Materials Reliability 50 , (2005), 113.Google Scholar
Huang, R., Gan, D. and Ho, P. S., Isothermal stress relaxation in electroplated Cu films. II. Kinetic modeling, Journal of Applied Physics 97 (2005), 103532.Google Scholar
Gupta, D., Hu, C. K., and Lee, K. L., Grain boundary diffusion and electromigration in Cu-Sn alloy thin films and their VLSI interconnects, Defect and Diffusion Forum 143 –147 (1997), 1397–1406.Google Scholar
Gan, D., Yoon, S., Ho, P. S., et al., Effects of passivation layer on stress relaxation in Cu line structures, Proceedings of the IEEE 2003 International Interconnect Technology Conference (2003), 180–182.Google Scholar
Singh, N., Bower, A. F., Gan, D., Yoon, S., and Ho, P. S., Numerical simulations and experimental measurements of stress relaxation by interface diffusion in a patterned copper interconnect structure, Journal of Applied Physics 97 (2005), 013539.Google Scholar
Korhonen, M. A., Borgesen, P., Tu, K. N., and Li, C. Y., Stress evolution due to electromigration in confined metal lines, Journal of Applied Physics 73 (1993), 3790–3796.Google Scholar
Kawano, M. et al., Stress relaxation in dual-damascene Cu interconnects to suppress stress-induced voiding, Proceedings of the IEEE 2003 International Interconnect Technology Conference (2003), 210–212. 10.1109/IITC.2003.1219756.Google Scholar
Shao, W., Gan, Z. H., Mhaisalkar, S. G., et al., The effect of line width on stress-induced voiding in Cu dual damascene interconnects, Thin Solid Films 504 (2006), 298–301.Google Scholar
Paik, J. M., Park, I. M., and Joo, Y. C., Effect of grain growth stress and stress gradient on stress-induced voiding in damascene Cu/low-k interconnects for ULSI, Thin Solid Films 504 (2006), 284–287.Google Scholar
Zhai, C. J., Yao, H. W., Marathe, A. P., Besser, P. R. and Blish, R. C., Simulation and experiments of stress migration for Cu/low-k BEOL, IEEE Transactions on Device and Materials Reliability 4 (2004), 523–529.Google Scholar
Baek, W. C. et al. Stress migration studies on dual damascene Cu/oxide and Cu/low k interconnects, American Institute of Physicists Conference Proceedings 741 (2004), 249–255.Google Scholar
Glasow, A. and Fischer, A. H., New approaches for the assessment of stress-induced voiding in Cu interconnects, Proceedings of the IEEE International Interconnect Technology Conference (2002), 274–276.Google Scholar
Shaw, T. M., Gignac, L., Liu, X-H., and Rosenberg, R., Stress voiding in wide copper lines, Sixth International Workshop on Stress induced Phenomena in Metallization (2001), 25–27.Google Scholar
Gan, D., Li, B., and Ho, P. S., Stress-induced void formation in passivated Cu films, Materials Research Society Symposium Proceedings 863 (2005), 259–266.Google Scholar
Li, B. and Badami, D., Stress voiding characteristics of Cu/low k interconnects under long term stresses, 2012 IEEE International Reliability Physics Symposium (IRPS), Anaheim, CA (2012), 5E.2.1–5E.2.6, doi: 10.1109/IRPS.2012.6241857.Google Scholar