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Advancing Strained Silicon. A O’Neill , S Olsen, University of Newcastle P-E Hellstrom, M Ostling, KTH K Lyutovich, E Kasper, University of Stuttgart. Scope. First investigation of thin VS MOSFETs 10x reduction in virtual substrate thickness Reduced self-heating Reduced growth time
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Advancing Strained Silicon A O’Neill, S Olsen, University of Newcastle P-E Hellstrom, M Ostling, KTH K Lyutovich, E Kasper, University of Stuttgart
Scope • First investigation of thin VS MOSFETs • 10x reduction in virtual substrate thickness • Reduced self-heating • Reduced growth time • Compare thin with thick VS MOSFET
SiNANO collaboration • WP1 • Stuttgart • KTH • Newcastle
Strained Si Material Growth ID IL growth T (°C) Processed wafers A1669 550 A1670 575 T1 A1671 600 A1672 625 A1673 650 T2 A1674 675 Si control
Processing • Device isolation: deposited oxide • Gate oxide: 2.8 nm • Poly-Si: 150 nm • Spacer formation: TEOS/Si3N4 • Source/Drain implants: As + 950 °C RTA • Silicide: 20 nm NiSi • Isolation: 200 nm low temperature oxide • Metalisation: TiW (120 nm) and Al (500 nm)
nMOSFET • no cross-hatching or dislocation pile-ups
Wafer yield T2 T1 Si control • 53.4% 89.7% 65.5% • yield not determined by material quality (yield on Si control is only 65%) Lg = 10 mm
T2 T1 Si control Short-channel performance Lg = 0.35 mm Vg-Vt = 1,2,3 V • High performance strained Si MOSFETs • Only small self-heating, despite high Id • High knee voltage for T2 devices
Series resistance: silicide Rsh (ohm/sq) T2 T1 Si control Minimum 49 10 7 Maximum 99 11 7 Median 69 10 8 • RshSi < RshT1 < RshT2 • Same trend for NiSi on gate => primarily a process issue
Series resistance: contacts Rc (ohms) T2 T1 Si control Minimum 42 14 3.8 Maximum 7700 979 15.6 Median 3090 126 8.6 • RcSi << RcT1 << RcT2 • Problems with Al-TiW-NiSi source/drain contacts for strained Si wafers
FIB investigation of contacts T1 smooth contact, no overetch T2 rough contact, much overetch (~160 nm) • Overetch of vias resulting in contact to SiGe virtual substrate (caused by thin silicide layer reducing etch selectivity?)
Impact of Rs on short channel performance Lg = 0.35 mm 400 400 T2 T2 T1 350 350 T1 Si control 300 300 Si control = 1.0 V (mS/mm) = 1.0 V (mS/mm) 250 250 200 maximum transconductance 200 maximum transconductance 150 150 d d at V at V 100 100 max 50 max 50 m g m g 0 0 0 20 40 60 80 100 1 10 100 1000 10000 source/drain sheet resistance R (ohms/sq) contact resistance R (ohms) sh C High Rsh and Rc degradegmmax
30 25 20 15 maximum transconductance d 10 at V 5 max m g 0 1 10 100 1000 10000 contact resistance R (ohms) c Impact of Rs on long channel performance Lg = 10 mm 30 25 = 1.0 V (mS/mm) 20 = 1.0 V (mS/mm) 15 maximum transconductance d 10 at V T2 T2 T1 5 T1 max Si-control Si-control m g 0 0 20 40 60 80 100 source/drain sheet resistance R (ohm/sq) sh Little impact of high Rsh and Rc on long channel performance => concentrate analysis on large geometry devices
Device performance: Ioff dependence on material Lg = 10 mm T2 Vd = 0.1 V Vd = 1.0 V Vd = 0.1 V T2 T1 T1 • Ioff(T2) > Ioff(T1) > Ioff(Si) • Only T2 wafer exhibits large cross-wafer variation in Ioff
Cross-wafer variation: Ioff T2 T1 Si control Vd = 0.1 V, Lg = 10 mm
Sub-threshold summary Lg = 10 mm, Vd = 0.1 V
Device performance: Ioff dependence on Vd T2 T2 T1 T1 Lg = 10 mm • Both SSi wafers exhibit large dependence of Ioff on Vd • Electrical measurements confirm Ioff dominated by substrate current
Origin of leakage: n+/p junction n=1.45 recombination sites xj ~120 nm intermediate SiGe layer
Origin of leakage: defects T2 T1 100 mm 100 mm Etch pit density: 2.2x106 cm-2 Etch pit density: 9x105 cm-2 • Reverse processing on best-performing devices (gate regions) • Schimmel etch consisting of CrO3/HF • Increased defect density on material grown at T2
C-V characteristics Low T High T Si control • No difference in EOT between wafers (~ 3 nm) • C-V measurements carried out on 50 mm x 100 mm MOS capacitors
Gate oxide quality best 10 mm die best 0.35 mm die 1.E+13 1.E+13 Median Median Best Best ) -1 ) eV -1 eV -2 1.E+12 1.E+12 -2 (cm (cm it D it D 1.E+11 1.E+11 T1 T2 Si Control T1 T2 Si Control • Regardless of gate length: • No impact of SiGe virtual substrate on Dit • No correlation between gmmax and Dit!
Surface roughness • AFM measurements carried on 20 mm x 20 mm scan areas • No clear impact of growth T on surface roughness T2 T1
Analysis by Raman Spectroscopy l = 514.5 nm Si-Si bond in Si substrate Si-Si bond in Si channel Si-Si bond in SiGe VS IL growth T = 675 degC • Raman spectra provide information on Ge composition, channel thickness, virtual substrate thickness and channel strain. • Shift in peak for Si-Si in SiGe indicates fluctuation in VS Ge composition • Spectra may also be influenced by defectivity
Ge-strain correlation T1 T2 • As-grown channel stress follows VS Ge composition • Processed channel strain measurements in progress
Drain current enhancements T2 T1 Si T1 T2 L=W=10um ~ Uniform enhancements in Ion with Vd suggest little self-heating
Device performance: gm Lg = 10 mm T2 T1 Si Vd = 0.1 V
Cross-wafer variation: gm 30 T2 T1 25 Si 20 15 Count 10 5 0 7 9 11 13 15 17 19 21 23 25 Maximum transconductance gm (mS/mm) Vd = 1.0 V, Lg = 10 mm
Impact of gate length on gmmax T1 T2 Si T1 T2 Si Vd = 0.1 V Vd = 1.0 V • Expected increases in gmmax at smaller Lg observed
T1 Impact of gate length on gmmax Reduced enhancements for high Vd – self heating?
T1 Impact of gate length on gmmax Olsen et al, J Appl Phys (2005) Reduced enhancements for high Vd – self heating? Greater impact of self heating for thick virtual substrate
T1 Impact of gate length on gmmax Olsen et al, IEEE Trans ED (2003) Reduced enhancements for high Vd – self heating? Greater impact of self heating for thick virtual substrate Same increase in enhancement for low Vd for thick virtual substrate (x=0.15)
Cut-off frequency vs. gate length W = 5 μm Vd = 1.2 V ~100 % enhancement in cut-off frequency for strained devices
Cut-off frequency vs. gate length W = 5 μm Vd = 1.2 V Lg = 1 μm Vd = 1.2 V ~100 % enhancement in cut-off frequency for strained devices gate width increases cut-off frequency de-embedded pads (not circuit model)
Summary • First thin virtual substrate MOSFETs • Enhanced performance • reduced self heating (cf thick VS) • RF performance demonstrated