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New Generation of Virtual Substrates

New Generation of Virtual Substrates. T. Grasby Dept. of Physics, University of Warwick. Device Layer. Si template (i.e. wafer). Si wafer. Straining Silicon with a Virtual Substrate. unstrained silicon. strained silicon (biaxial tensile). SiGe x(z). z. New template

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New Generation of Virtual Substrates

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  1. New Generation of Virtual Substrates T. Grasby Dept. of Physics, University of Warwick

  2. Device Layer Si template (i.e. wafer) Si wafer Straining Silicon with a Virtual Substrate unstrained silicon strained silicon (biaxial tensile) SiGex(z) z New template (virtual substrate)

  3. Why Global Strain? • Non, Non • Uniaxial process-induced strain more effective, more flexible • Riddled with defects • Expensive to produce

  4. Why Global Strain? • GLOBAL STRAIN FOR EVER • Enables high (biaxial) stress levels ~ 0.9 GPa per 10% Ge concentration (y) • Comparably high uniaxial strain via patterning • Hybrid strain regime – global + process induced top-up • Platform for n-sSi/p-SiGe dual channel CMOS devices • Contender for 32-22nm node FDSOI • Needed for R&D on strained Ge devices • Route to Si-Ge-GaAs integration?

  5. Big Questions  is the quality there? is there a route to production?

  6. First Generation VS (linear Ge grade) – Quality Issues Ge conc(y) ~ 20% - good for nMOS performance → threading (field) dislocation density (TDD) ≥ 105 cm-2 → pile-up densities (PUD) ~ 0.1 – 10 cm-1 → surface roughness ~ 1 – 3 nm  involve CMP

  7. Linear Grading – State of the Art RMS Field TDD TDD (cm-2) RMS roughness (nm) Pile-up TDD Germanium composition (%) From Y. Bogumilowiczet al., LETI and IQE

  8. Linear Grading – State of the Art RMS Field TDD TDD (cm-2) RMS roughness (nm) Pile-up TDD Germanium composition (%) From Y. Bogumilowicz et al., LETI and IQE

  9. Terrace Grading 20% Linear grade Ge Concentration 10% 0 8 2 4 6 Thickness (mm)

  10. UK SiGe:C Epitaxy Centre SS-MBE MBE - V90S-ANT LP-CVD - ASM Epsilon 2000E ...from Lab to Fab GS-MBE/-CVD mode

  11. Terrace Grading – development work (SS-MBE) 30% - 3 tier

  12. Terrace Graded - TEM 60% 6 Tier

  13. LG 30% ≈105 cm-2 TDD Pile-up ≈1 cm-1

  14. Defect reveal in 104 cm-2 range TDD ≈ 4 x 104 cm-2

  15. Defect Reveal in 103 cm-2 range LG 15%, 850ºC Pseudo Pile-up EPD = 6x103

  16. Hardly an etch pit in sight! Pile-up < 0.1cm-1 TD TDD ≈ 3x103 cm-2 PUD = 0

  17. LG 40% TDD ≈ 106 cm-2 Pile-up ≈ 5cm-1

  18. TG 40% TDD ≈ 3x105 cm-2 Pile- up = 0?

  19. Terrace Grading – Elimination of Pile-ups?SiPHER Analysis TG (3 tier) up to 30% (SS-MBE) Photoluminescence image Surface image 6x6 mm area Pile-up density:≤ 0.1 cm-1 Measurements taken by Accent Optical Technologies near wafer centres

  20. Terrace Grading – Elimination of Pile-ups?SiPHER Analysis 3 tier up to 30% (SS-MBE) TG LG Photoluminescence image Photoluminescence image Surface image 2x2 mm area Pile-up density: 3.5 - 6 cm-1 6x6 mm area Pile-up density:≤ 0.1 cm-1 Measurements taken by Accent Optical Technologies near wafer centres

  21. How does Terrace Grading do it? LG LG

  22. What can Terrace Grading do? LG LG Terrace Grading ≡ Virtual CMP TG TG

  23. 30% Terrace Graded Properties(MBE growth) High T growth (850  790C) 3.5x105 2x105

  24. 30% Terrace Graded Properties(MBE growth) High T growth + anneal + anneal 3.5x105 2x105  5x103  3x105

  25. 30% Terrace Graded Properties(MBE growth) Low T growth 800 700C TG Low T + anneal 3.5x105 2x105 3x103  5x103  3x105 0 1.9

  26. ≈103 cm-2 TDD Pile-up < 0.1cm-1 30% TG TD TDD ≈ 3x103 cm-2 PUD = 0

  27. Terrace Grading – (SS-MBE)TDD for y  50%High T growth - 850790C

  28. Transfer to CVD • TG virtual substrates up to y = 0.2 grown on ASM Epsilon 2000E™ RP-CVD reactor using SiH4, SiCl2H2 and GeH4 precursors. • Optimisation work - growth temperatures, growth rates, strain gradients, no. of terraces, terrace widths, throughput, etc

  29. Terrace Grading Properties (CVD) y→0.2 4 tiers

  30. Terrace Grading Properties (CVD) y→0.2 Reciprocal space maps (000 and 220) of 2 tier TG 20% sample taken with XRD AFM images showing 10x10μm area and 2x2μm area TD Typical etch pit image of TG sample capped with 10nm of strained silicon. TDD ~ 105

  31. Pile-Up Free Photoluminescence image Surface image 6x6 mm area Pile-up density: 0 TG (2 tier) up to 17% (LPCVD) Measurements taken by Accent Optical Technologies

  32. Terrace Graded Props (CVD) y = 0.2

  33. Terrace Graded Props (CVD) y = 0.2 1.1x105

  34. Terrace Graded Props (CVD) y = 0.2 1.1x105

  35. Misfits at the sSi/VS interface MD TD

  36. Misfits at the sSi/VS interface MD TD …….but tsSi = 10nm which is < tc (17nm)

  37. EPD Reveal in VS with sSi layer Chemical etchant TD Strained silicon MD TD Virtual substrate Additional etch pit Etched surface  100% increase in EPD

  38. Terrace Grading – basic studies (y→0.2)(with sSi layer)…CVD y 0.2 0.1 0.0 6 8 2 4 Thickness (μm) TDD (cm-2) Relaxation of upper terrace (%) Number of terraces

  39. 50% terrace graded (for sSi) TDD = 3x105 cm-2 PUD = 0

  40. 80% terrace graded (for sGe) TDD = 3x105 cm-2 PUD = 0

  41. Terrace graded VSs – smoother! CMP LG data from LETI ….and no CMP

  42. The Future • Terrace grading • Heralds a new generation in VS quality: • eliminates pile-up • low TDD • potential to avoid CMP • route to production√ • Current work • Examining new designs which directly manage the relaxation process: • → thinner virtual substrates • → TDD and PUD → zero • → smooth enough for wafer bonding • And finally • Still a lot of parameter space to be explored • – and if you thought Si-Ge relaxation was fully understood ..….……

  43. THINK AGAIN!

  44. Linkage with SiNANO • Many VS-based sSi layers supplied to WP1 and WP2 partners for device processing • VSs characterised by partners • VS-based sGe layers supplied to partner for device processing • VS-based sSiGe and sGe layers to be supplied to Jeulich for OI bonding trials • VS work enabled a presence on PULLNANO project

  45. END

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