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Low- k Dielectrics: Materials and Process Technology. Rebeca C. Diaz EE 518, Penn State Instructor: Dr. J. Ruzyllo April 13, 2006. Outline. Motivation for low- k dielectrics Required properties of low- k dielectrics Proposed materials Most promising materials
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Low-k Dielectrics: Materials and Process Technology Rebeca C. Diaz EE 518, Penn State Instructor: Dr. J. Ruzyllo April 13, 2006
Outline • Motivation for low-k dielectrics • Required properties of low-k dielectrics • Proposed materials • Most promising materials • CVD vs. Spin-on techniques • Conclusion
Why Low-k Dielectrics? • Reduce RC constant without reducing size • R metal interconnect minimized with Cu • C dielectric need low-k
Inorganic/organic Hybrid: MSQ (k = 2.0)2 HOSP (Honeywell) • “Carbon-doped oxide” • High thermal stability • High resistance to cracks • Reactant with stripping chemicals
Organic: PAE (k = 2.6)2 FLARE (Honeywell) and VELOX (Schumacher) • High thermal stability • Low moisture absorption • Good adhesion with metals and SiO2 • Anisotropic but solved by increasing k to 2.8
Organic: Parylene4 • Parylene-N (k = 2.7) • Mechanically stable • High thermal stability • Poor adhesion with Cu • Parylene-F (k = 2.4) • Same properties as Parylene-N • Poor adhesion can lead to corrosion http://www.paryleneinc.com
CYCLOTENE (Dow Chemical) Fluorine based Good temperature stability Low metal adhesion Moisture absorption Currently used in GaAs interlayer dielectric SiLK (Dow Chemical) Phosphorous based High temperature stability Good metal adhesion Low mechanical stability Organic: B-staged polymers (k = 2.6)2
Organic: PTFE (k = 1.9)2 SPEEDFILM • No moisture absorption • Temperature resistant • Good adhesion with metals • Good mechanical stability • Compatible with etching chemistries
Porous Organics and Inorganics • Add closed cells of air to materials that show promising characteristics • Dielectric constants below 2.0 (1) “Low-k Dielectrics.” http://fcs.itc.it/
Disadvantages of Porous Materials2 • Weakens mechanical properties • Lower thermal conductivity • Narrow pore distribution to ensure dielectric constant is homogeneous and isotropic • Pores need to be closed cells to prevent crack propagation and moisture absorption • Need to add silica to seal surface pores
Air Gaps and Bridges (k = 1.0)2 • Low breakdown voltage • Low thermal conductivity • Low strength • Deposition method unknown
CVD k as low as 2.0 Porosity cannot be added Better mechanical stability Better thermal stability Technology in place Less expensive Batch process SOD k as low as 1.9 k below 1.9 by adding porosity More promising low-k materials More uniform deposition Extendable to future technologies Single-wafer process CVD vs. Spin-on Deposition2
Conclusions • Introduction of low-k dielectric is needed in order to continue to downscale technology • Several CVD or Spin-on deposited materials look promising for the near-future generations • Spin-on porous materials appear to be the only option for future generations • Air gaps need more research in order to be considered for future low-k dielectrics
References (1) Fisica Chimica delle Superfici e Interfacce. “Low-k Dielectrics.” <http://fcs.itc.it/MAMeBROCHURE/low-k%20dielectrics.pdf> 31 Mar 2006. (2) Clarke, Michael E. Application Note MAL123: “Introducing Low-k Dielectrics into Semiconductor Processing.” Mykrolis. 2003. <http://www.mykrolis.com/publications.nsf/ docs/MAL123> 31 Mar 2006 (3) Plumber et al. “Back-end Technology.” Silicon VLSI Technology: Fundamentals, Practice and Modeling. Chap. 11. Prentice Hall, NJ, USA. 2000. (4) Nishi, Yoshio and Doering, Robert. “Alternate Interlevel Dielectrics.” Handbook of Semiconductor Manufacturing Technology. Chap. 12. Marcel Dekker, Inc. NY, USA. 2000.