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Impact of Nanotopography on STI CMP in Future Technologies D. Boning and B. Lee, MIT N. Poduje, ADE Corp. J. Valley, ADE Phase-Shift W. Baylies, Baytech Group. Outline. Review: Nanotopography Interaction with CMP Experiments demonstrate oxide thinning over nanotopography

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  1. Impact of Nanotopography on STI CMP in Future TechnologiesD. Boning and B. Lee, MITN. Poduje, ADE Corp.J. Valley, ADE Phase-ShiftW. Baylies, Baytech Group

  2. Outline • Review: Nanotopography Interaction with CMP • Experiments demonstrate oxide thinning over nanotopography • What impact does nanotopography have on STI as we scale from 130 nm to 100 nm and beyond? • Approach: • Simulate CMP of STI stacks over nanotopography • Yield Problem #1: failure to clear oxide • Yield Problem #2: excessive nitride thinning • Conclusions: • Nanotopography requirements can be based on STIyield impact • Can generate yield problem maps given a measured nanotopography map Boning et al., Nanotopography/STI CMP

  3. 100 nm -100 nm Review: Nanotopography • Nanometer height variations occurring on millimeter lateral length scales in virgin silicon wafers SSP wafer, Diameter Scan (Filtered Data) using NanoMapperTM 100 80 60 40 20 0 -20 -40 -60 -80 -100 WAFER HEIGHT (nm) Nanotopography Length Boning et al., Nanotopography/STI CMP

  4. Initial oxide surface after conformal deposition Oxide Thickness Deviation Final oxide surface, assuming uniform CMP removal CMP Actual Final Surface, after CMP removal Remaining Oxide mm distances Silicon with initial nanotopography feature Problem: Oxide Thickness Deviation (or Oxide Thinning) During CMP Boning et al., Nanotopography/STI CMP

  5. Nanotopography & Oxide Thinning NanoMapper nanotopography filtered wafer height map Acumap inverted oxide thickness with zero mean High / Thin Low / Thick SSP Wafer Data @ 20mm EE Boning et al., Nanotopography/STI CMP

  6. Fail to clear oxide Nitride Oxide Excessive nitride removal Si Before CMP After CMP Impact of Nanotopography in STI CMP? • Previous experiments on blanket oxide over nanotopography show oxide thinning in CMP • But… STI processes involve CMP of a multilayer oxide/nitride/oxide stack Boning et al., Nanotopography/STI CMP

  7. Approach: Simulate Effect of Nanotopography on CMP of STI Stack • “Ideal” result: • Complete removal of oxide • No removal of nitride oxide nitride silicon STI stack over nanotopography: post-CMP STI stack over nanotopography: pre-CMP Boning et al., Nanotopography/STI CMP

  8. Simulation Details • Start with measured nanotopography data • Epi single-side polished substrate; use 20 mm EE • Simulate CMP of STI stack on blanket wafer • Perform 3D contact wear simulation – find local pressures based on bending of elastic pad around surface • Consider 130 nm technology node: • 300 nm oxide / 100 nm nitride / 10 nm pad oxide • CMP process: • Nominal pad stiffness: E = 147 MPa • 5:1 oxide:nitride polish rate selectivity • Consider Two Cases: • Problem #1: Failure to clear • Problem #2: Excessive nitride polish Boning et al., Nanotopography/STI CMP

  9. Problem #1: Failure to Clear Oxide • Polish time is determined by initial clearing (initial endpoint) plus overpolish time • Polish to initial clear: 84 seconds for this wafer/stack • Assume fixed overpolish time: 14 seconds • Examine regions where oxide remains • These result in device failure Initial clearing or “Endpoint” is detected when top points begin to clear Failure to Clear Oxide oxide nitride silicon STI stack: pre-CMP Post-CMP with too little overpolish Boning et al., Nanotopography/STI CMP

  10. Note visual correlation with initial nanotopography “low spots” Simulated Result: Oxide Clearing Map Initial Nanotopography 3% of wafer does not clear Å Blue indicates uncleared areas Initial Nanotopography Boning et al., Nanotopography/STI CMP

  11. NitrideThinning Remaining nitride oxide nitride silicon STI stack: pre-CMP STI stack: post-CMP Problem #2: Excessive Nitride Loss • Failure to clear - causes incomplete transistor formation • Alternative: Increase overpolish time to ensure complete clearing of oxide in all nanotopography valleys everywhere on wafer • Nanotopography thus forces additional overpolish time! • In addition to overpolish due to wafer level or chip pattern effects • Resulting problem: excessive nitride loss - causes transistor performance degradation Boning et al., Nanotopography/STI CMP

  12. Simulation Details • Extend CMP over-polish time until oxide has just finished clearing everywhere • Plots: • Initial nanotopography • Total amount removed (oxide and nitride) • Nitride thinning • Potential device failure points • Assume a 20% nitride film thickness loss budget Boning et al., Nanotopography/STI CMP

  13. Initial Nanotopography Total AmountRemoved Å Å E= 147 MPa Boning et al., Nanotopography/STI CMP

  14. InitialNanotopography TotalRemoved Zoom on TotalRemoved Boning et al., Nanotopography/STI CMP

  15. Thinning of Nitride Layer (Under Oxide) Initial Nanotopography Nitride Thinning Å Å E= 147 MPa Boning et al., Nanotopography/STI CMP

  16. Nitride Thinning – Device Failure Map Initial Nanotopography Potential Failure Locations Å 4.5% Area Failure Initial Nanotopography Red indicates excessive nitride thinning– greater than 20 nm (10%) budget E= 147 MPa Boning et al., Nanotopography/STI CMP

  17. Effects of Pad Stiffness • The pad stiffness may affect the amount of nitride thinning • Stiffer pads result in more thinning in certain regions on the wafer • Less stiff pads result in less thinning • Trend in STI CMP is toward stiffer pads in order to reduce within-die variation due to pattern densities • This trend may conflict with nanotopography! Boning et al., Nanotopography/STI CMP

  18. Comparison: Nitride Thinning & Failure Areas Soft PadE = 70 MPa Medium PadE = 147 MPa Stiff PadE = 200 MPa Å Failure Areas 0.4% 4.5% 8.1% Boning et al., Nanotopography/STI CMP

  19. Future Generations • As technology scales, film thicknesses will also decrease • Nitride thinning budget for STI processes will also decrease • Examine 130 nm to 100 nm transition • Conservative Scaling Assumption: • nitride film thickness shrinks to 90 nm (from 100 nm) • thinning budget of 20% or 18 nm (from 20 nm) Boning et al., Nanotopography/STI CMP

  20. Excessive Nitride Thinning – Device Failure Comparison Soft Pad Medium Pad Stiff Pad 130 nm (20 nm Nthin) 4.5% 0.4% 8.1% Failure Area% 36.81% 34.75% 28.37% 100 nm (18 Nthin) Boning et al., Nanotopography/STI CMP

  21. Soft Pad Medium Pad Stiff Pad 0.2% 3.6% 6.6% Modified Nanotopography Requirement • Given nitride thinning spec (18 nm), how much must we scale nanotopography to achieve same % failure area? • Example: Scale nanotopography by 90%, adjust polish time • Conjecture for future nanotopography requirements: • Need to scale nanotopography height at same rate as nitride thickness • May need to improve nanotopography height or spatial characteristics more aggressively if STI CMP moves to stiffer pads Boning et al., Nanotopography/STI CMP

  22. Conclusions • Nanotopography can interact with CMP to cause device yield concerns in the STI process • Yield concerns can be predicted and yield impact maps produced from nanotopography maps: • Problem #1: failure to clear oxide • Problem #2: excessive nitride thinning • Degree of impact depends on pad stiffness • Future technology scaling will require • Continued tightening of nanotopography specs • Full wafer measurement and analysis of nanotopography • Future work: STI stack simulation on patterned wafers with nanotopography Boning et al., Nanotopography/STI CMP

  23. References • D. Boning, B. Lee, N. Poduje, J. Valley, and W. Baylies, “Modeling and Mapping of Nanotopography Interactions with CMP,” MRS Spring Meeting, April 2002. • B. Lee, D. S. Boning, W. Baylies, N. Poduje, P. Hester, Y. Xia, J. Valley, C. Koliopoulos, D. Hetherington, H. Sun, and M. Lacy, “Wafer Nanotopography Effects on CMP: Experimental Validation of Modeling Methods,” MRS Spring Meeting, April 2001. • D. Boning, B. Lee, W. Baylies, N. Poduje, P. Hester, J. Valley, C. Koliopoulos and D. Hetherington, “Characterization and Modeling of Nanotopography Effects on CMP,” International CMP Symposium 2000, Tokyo, Japan, Dec. 4, 2000. • R. Schmolke, R. Deters, P. Thieme, R. Pech, H. Schwenk, and G. Diakourakis, “On the Impact of Nanotopography of Silicon Wafers on Post-Chemical Mechanical Polished Oxide Layers,” J. Electrochem. Soc., vol. 149, no.4, pp. G257-G265, 2002. • B. Lee, T. Gan, D. S. Boning, P. Hester, N. Poduje, and W. Baylies, “Nanotopography Effects on Chemical Mechanical Polishing for Shallow Trench Isolation,” Advanced Semiconductor Manufacturing Conference, Sept. 2000. • O. G. Chekina and L. M. Keer, “Wear-Contact Problems and Modeling of Chemical Mechanical Polishing,” J. Electrochem. Soc., vol. 145, no. 6, pp. 2100-2106, June 1998. • T. Yoshida, “Three-Dimensional Chemical Mechanical Polishing Process Model by BEM,” Proc. ECS Conf., Oct. 1999. Boning et al., Nanotopography/STI CMP

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