Fabrication and Performance Limits of Sub-0.1 µm Cu Interconnects

T. S. Kuan; C. K. Inoki; G. S. Oehrlein; K. Rose; Y. –P. Zhao; G. –C. Wang; S. M. Rossnagel; C. Cabral

doi:10.1557/PROC-612-D7.1.1

Abstract

As the on-chip interconnect linewidth and film thickness shrink below 0.1 µm, the size effect on Cu resistivity becomes important, and the electrical performance deliverable by such narrow metal lines needs to be assessed critically. From the fabrication viewpoint, it is also crucial to determine how structural parameters affect resistivity in the sub-0.1 µm feature size regime. To evaluate the scaling of resistivity with thickness, we have fabricated a series of Ta/Cu/Ta/SiO2 thin film structures with Cu thickness ranging from 1 µm to 0.02 µm. These test structures revealed a far larger (∼2.3 ×) size effect than that expected from surface scattering. We have also fabricated test structures containing 50-nm-wide Cu lines wrapped in Ta-based liners and embedded in insulating SiO2 using e-beam lithography, high-density plasma etching, ionized PVD Cu deposition, and chemical-mechanical planarization processes. Direct current (16 nA) resistance measurements from these 50-nm-wide Cu lines have also shown a higher- than-expected distribution of resistivity. Cross-sectional TEM and surface AFM observations suggest that the observed extra resistivity increase can be attributed to small grain sizes in ultra- thin Cu films and to Cu/Ta interface roughness. Monte Carlo simulations are used to quantify the extra resistivity resulting from interface roughness.

References

1. The National Technology Roadmap for Semiconductors (Semiconductor Industry Association, San Jose, CA, 1999).Google Scholar

2. Fuchs, K., Proc. Cambridge Phil. Soc. 34, 100 (1938).10.1017/S0305004100019952Google Scholar

3. Lucas, M. S. P., J. Appl. Phys. 36, 1632 (1965).10.1063/1.1703100Google Scholar

4. MacDonald, D. K. C. and Sarginson, K., Proc. Roy. Soc. London A203, 223 (1950).Google Scholar

5. Dingle, R. B., Proc. Roy. Soc. London A201, 545 (1950).Google Scholar

6. Isaeva, R. V., Soviet Phys. JETP Letters English Transl. 4, 209 (1966).Google Scholar

7. Reynolds, F. W. and Stilwell, G. R., Phys. Rev. 88, 418 (1952).10.1103/PhysRev.88.418.2Google Scholar

8. Hsu, Y., Standaert, T. E. F. M., Oehrlein, G. S., Kuan, T. S., Sayre, E., Rose, K., Lee, K. Y., and Rossnagel, S. M., J. Vac. Sci. Technol. B16, 3344 (1998).10.1116/1.590379Google Scholar

9. Mayadas, A. F. and Shatzkes, M., Phys. Rev. B1, 1382 (1970).10.1103/PhysRevB.1.1382Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Qing-Tang Jiang Ming-Hsing Tsai and Havemann, R.H. 2001. Line width dependence of copper resistivity. p. 227.

Havemann, R.H. and Hutchby, J.A. 2001. High-performance interconnects: an integration overview. Proceedings of the IEEE, Vol. 89, Issue. 5, p. 586.

Wen Wu and Maex, K. 2001. Studies on size effect of copper interconnect lines. Vol. 1, Issue. , p. 416.

Qing-Tang Jiang Ming-Hsing Tsai Frank, A. Parihar, V. Nowell, M. Augur, R.A. Havemann, R.H. and Luttmer, J.D. 2001. Annealing impact on damascene Cu resistivity and microstructures. Vol. 1, Issue. , p. 400.

Frank, D.J. 2002. Power-constrained device and technology design for the end of scaling. p. 643.

Barnat, E. V. Wang, P. -I. Nagakura, D. and Lu, T. -M. 2002. Influences of Hydrogen on the Evolution of the Electrical Resistivity Of Ultra-Thin Sputtered Copper Films Measured in Real-Time. MRS Proceedings, Vol. 721, Issue. ,

Engelhardt, M Schindler, G Steinhögl, W and Steinlesberger, G 2002. Challenges of interconnection technology till the end of the roadmap and beyond. Microelectronic Engineering, Vol. 64, Issue. 1-4, p. 3.

Schwantes, Stefan Göttsche, Ralf and Krautschneider, Wolfgang 2003. Impact of parasitic elements on the performance of digital CMOS circuits with Gigabit feature size. Solid-State Electronics, Vol. 47, Issue. 7, p. 1243.

Higashiya, Seiichiro Banger, Kulbinder K Ngo, Silvana C Lim, Poay N Toscano, Paul J and Welch, John T 2003. Synthesis of fluorinated α-sila-β-diketones and their copper(II) complexes. Inorganica Chimica Acta, Vol. 351, Issue. , p. 291.

Steinlesberger, G. Engelhardt, M. Schindler, G. Steinhögl, W. Traving, M. Hönlein, W. and Bertagnolli, E. 2003. Impact of Annealing on the Resistivity of Ultrafine Cu Damascene Interconnects. MRS Proceedings, Vol. 766, Issue. ,

Van Olmen, J. Wu, W. Van Hove, M. Travaly, Y. Brongersma, S.H. Eyckens, B. Maenhoudt, M. Van Aelst, J. Struyf, H. Demuynck, S. Tokei, Z. Vervoort, I. Sijmus, B. Vos, I. Ciofi, I. Stucchi, M. Maex, K. and Iacopi, F. 2003. Integration of Single Damascene 85/85 nm L/S copper trenches in Black Diamond using 193 nm optical lithography with dipole illumination. p. 171.

Steinhoegl, W. Schindler, G. Steinlesberger, G. Traving, M. and Engelhardt, M. 2003. Scaling laws for the resistivity increase of sub-100 nm interconnects. p. 27.

Schindler, G Steinlesberger, G Engelhardt, M and Steinhögl, W 2003. Electrical characterization of copper interconnects with end-of-roadmap feature sizes. Solid-State Electronics, Vol. 47, Issue. 7, p. 1233.

Kim, Choong-Un Park, Jaeyong Michael, Nancy Gillespie, Paul and Augur, Rod 2003. Study of electron-scattering mechanism in nanoscale Cu interconnects. Journal of Electronic Materials, Vol. 32, Issue. 10, p. 982.

Besling, W.F.A. Broekaart, M. Arnal, V. and Torres, J. 2004. Line resistance behaviour in narrow lines patterned by a TiN hard mask spacer for 45 nm node interconnects. Microelectronic Engineering, Vol. 76, Issue. 1-4, p. 167.

Steinhögl, W. Schindler, G. Steinlesberger, G. Traving, M. and Engelhardt, M. 2004. Impact of line edge roughness on the resistivity of nanometer-scale interconnects. Microelectronic Engineering, Vol. 76, Issue. 1-4, p. 126.

Engelhardt, M. Schindler, G. Steinhögl, W. Steinlesberger, G. and Traving, M. 2004. Electrical Behavior of Nano-Scaled Interconnects. MRS Proceedings, Vol. 812, Issue. ,

Engelhardt, N. Schindler, G. Steinhogl, W. Steinlesberger, G. and Traving, M. 2004. Investigation of nano interconnects for an early experimental assessment of future interconnect challenges. p. 113.

Kim, Soo-Hyun Hwang, Eui-Sung Ha, Seung-Chul Pyi, Seung-Ho Sun, Ho-Jung Lee, Joo-Wan Kawk, Nohjung Kim, Jun-Ki Sohn, Hyunchul and Kim, Jinwoong 2005. Characterizations of Pulsed Chemical Vapor Deposited-Tungsten Thin Films for Ultrahigh Aspect Ratio W-Plug Process. Journal of The Electrochemical Society, Vol. 152, Issue. 6, p. C408.

Niskanen, Antti Rahtu, Antti Sajavaara, Timo Arstila, Kai Ritala, Mikko and Leskelä, Markku 2005. Radical-Enhanced Atomic Layer Deposition of Metallic Copper Thin Films. Journal of The Electrochemical Society, Vol. 152, Issue. 1, p. G25.

Download full list

Article contents

Fabrication and Performance Limits of Sub-0.1 µm Cu Interconnects

Abstract

Access options

References

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Fabrication and Performance Limits of Sub-0.1 µm Cu Interconnects

Abstract

Access options

References

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests