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The Characteristics and Simulations of Si/SiGe Heterojunction at Strained-Si Devices

The Characteristics and Simulations of Si/SiGe Heterojunction at Strained-Si Devices. 指導教授:劉致為 博士 學生:魏潔瑩 台灣大學電子工程學研究所. Outline. Introduction Introduction to Si-based Heterostructure Device Fabrication Simulation and Result Discussion Conclusion. Technology Scaling.

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The Characteristics and Simulations of Si/SiGe Heterojunction at Strained-Si Devices

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  1. The Characteristics and Simulations of Si/SiGe Heterojunction at Strained-Si Devices 指導教授:劉致為 博士 學生:魏潔瑩 台灣大學電子工程學研究所

  2. Outline • Introduction • Introduction to Si-based Heterostructure • Device Fabrication • Simulation and Result Discussion • Conclusion

  3. Technology Scaling • New technology generation introduced every 3 or 2 years. (0.18um, 0.13um, 90nm,.… ) • Scaling improves cost and performance-- leading to new applications and growth. How much more scaling is left? • Question:

  4. Gate Cg Oxide Drain Source Cd Smaller FET Needs Thinner Gate Oxides The conduction channel must be controlled by the gate, not by The drain. As L is reduced, drain-to-channel capacitance increases. Therefore, gate-to-channel capacitance must also be raised, i.e., oxide must be thinner. 1975: 100nm, 2003: 1.2nm. How much thinner can it get? L Ref [1]

  5. 12Å Gate Oxide -- 3 SiO2 molecules thick Ref [1]

  6. SiO2 Jg reduction > 6 orders High-k Dielectric 1.5 2.0 2.5 Effect Oxide Thickness (nm) High-k Dielectrics Reduce Gate Leakage 1.E+02 1.E+00 1.E-02 High-k Dielectric Gate Jg (A/cm2) 1.E-04 1.E-06 1.E-08 1.0 Ref [1]

  7. I mobility x charge = mobility x ( V-Vt ) / Tox • In order to reduce power use, V is reduced and Vt and Tox are kept large. Unfortunately, I drops. • Large I is needed to keep circuit speed high. • What is needed : high mobility material

  8. Outline • Introduction • Introduction to Si-based Heterostructure • Device Fabrication • Simulation and Result Discussion • Conclusion

  9. Lattice Structure and Heterostructures Ref [2]

  10. 20nm Strained Si Tensile strain can Strained Si increase silicon electron Relaxed SiGe holes mobilities. Si Ge 1 - x x Need strained silicon film Graded SiGe Region with low defect density at low cost. Si Substrate Si Strained Silicon Transistor Ref [1]

  11. The Effect of Strain on Si Conduction Band Ref [2]

  12. Band Alignment between Si and Si0.7Ge0.3 1% Ge = 6meV for CB and VB Ref [3]

  13. Effective Mobility of Strained-Si 65% enhancement at 1.0 MV/cm μ= eτ/ m* τ= scattering time constant m*=effective mass Ref [4]

  14. Outline • Introduction • Introduction to Si-based Heterostructure • Device Fabrication • Simulation and Result Discussion • Conclusion

  15. The Structure of the surface-channel Strained-Si n-MOSFET • 0.8 μm design rule • 100 mm-wafer line • ~1 μm graded SiGe buffer layer • ~1 μm uniform relaxed Si0.8Ge0.2 • 12-24nm strained layer thickness • are grown by UHV/CVD • 20 nm LTO as gate oxide • Dit = 1E11 cm-2eV-1 Ref [5]

  16. Outline • Introduction • Introduction to Si-based Heterostructure • Device Fabrication • Simulation and Result Discussion • Conclusion

  17. Parameters • χSS = 4.05 + 0.6x • Eg,SS = 1.12 - 0.4x • εr, SS = 11.8 • χSiGe = 4.05 • Eg,SiGe = 1.12 - 0.4x • εr, SiGe = 11.8 + 4.2x x : Ge content, χ: affinity, Eg : bandgap energy, SS : strained-Si Simulator: ISE TCAD 8.5 DESSIS

  18. Structure and Band Diagram of Strained-Si/SiGe/Si MOS Capacitor

  19. Simulated Band Diagrams for Different Gate Biases

  20. Measured and Simulated Quasi Static C-V Characteristics

  21. Measured NMOS Capacitor C-V with Different Strained-Si Thickness

  22. Simulated NMOS Capacitor C-V with Different Strained-Si Thickness

  23. Simulated NMOS Capacitor C-V as A Function of Ge Content

  24. Simulated Energy Band Diagram for Different Ge Content in PMOS Capacitor

  25. Hole Density Ratio in Strained-Si

  26. Asymmetric Strain

  27. Simulated Current Enhancement in Asymmetric Strain

  28. Outline • Introduction • Introduction to Si-based Heterostructure • Device Fabrication • Simulation and Result Discussion • Conclusion

  29. Conclusion • Due to Fermi level pinning effect, the C-V characteristics in NMOS capacitor exhibits a more obvious plateau than in PMOS capacitor. • Less Ge content and larger strained layer thickness must be chosen to sustain enough great inversion hole density ratios in strained-Si pMOSFET.

  30. Since more strain and thinner strained layer are taken to keep mobility enhancement, the compromise must be made. • Modeling of hole confinement on the C-V characteristics in strained-Si must be investigated.

  31. Reference [1] Chenming Hu, IEDMS 2002 presentation. [2] Kern Rim, Ph. D. dissertation 1999. [3] J. J. Welser, Ph. D. dissertation 1994. [4] M. H. Lee et al., “Comprehensive Low-Freguency and RF Noise Characteristics in Strained-Si NMOSFETs”, IEDM 2003. [5] C. C. Lee et al., ”The effects of mobility and saturation velocity on deep submicron strained Si NMOSFETs,” IDEMS, 2002.

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