the abc’s of cmp for dwb and soi · camp conference presentation august 9, 2010 the abc’s of...
TRANSCRIPT
Robert L. Rhoades, Ph.D.
CAMP Conference Presentation
August 9, 2010
The ABC’s of CMP for DWB and SOI
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Introduction
Direct Wafer Bonding (DWB) Background
CMP for DWB
Silicon-On-Insulator (SOI) Background
CMP for SOI
Summary
Outline
2
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DWB Background
• DWB requires surfaces that are …
– Flat or negative topography (no bumps or mesas)
– Very smooth
– Extremely clean
• CMP is a logical choice for surface preparation
– Good starting points in CMOS (ILD, STI, Cu, etc.)
– Many materials can be polished as long as the
slurry/pad/process are properly optimized
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Direct Wafer Bonding
• Direct Wafer Bonding (DWB)– Surface prep is key
– CMP adapted to the materials being bonded
– Cleaning steps are critical to ultimate DWB success
– Anneal is usually necessary to strengthen bonds
CMP / Clean
Activation
RT Bond
Anneal
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Guideposts for DWB
• Surface Roughness (Ra)< 0.5 nm 0.5 – 1.0 nm > 2.0 nm
Good …… Usually ok ….. Poor
• Flatness or topography– No “bumps” sticking up from surface
– Indents or cavities ok (preferably sharp corners)
• Surface cleanliness– Must be very clean and particle free
– NO hydrocarbons allowed on surface
• Materials– Strongest bond is generally same-same material
– Most common are oxide-oxide and Si-Si
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Types of Si DWB
Sourc
e: K
im a
nd N
aja
fi, Univ
ers
ity of M
ichig
an, 2
007
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DWB Example #1
• Included 3 types of substrates
– Silicon wafers with grown thermal oxide layers
– Silicon wafers with deposited oxide films
– Borofloat 33 glass (clear)
• Initial work performed on bare substrates and
blanket film wafers to understand materials
independent of pattern effects
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CMP – Thermal Oxide
0
1000
2000
3000
4000
5000
6000
7000
0 20 40 60 80 100 120 140
Polish Time (seconds)
Th
erm
al O
xid
e R
em
ov
ed
(A
ng
)
Removed (low pressure)
Removed (med pressure)
Test Inputs
• Thermal oxide films
• IPEC 472 polisher
• Klebosol silica slurry
• IC1000 on Suba IV pad stack
• Diamond pad conditioner
• OnTrak DSS with PVA brushes
• NH4OH(2%) cleaning chemistry
Outcome• Two pressures screened
• Linear function of polish time
• Surface roughness excellent at
all settings (Ra <1 nm)
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CMP – Borofloat 33 Glass
0
1000
2000
3000
4000
5000
6000
7000
8000
9000
10000
0 20 40 60 80 100 120 140
Polish Time (seconds)
Bo
rofl
oa
t 3
3 R
em
ov
ed
(A
ng
)
Removed (low pressure)
Removed (med pressure)
Test Inputs
• Substrates of Borofloat 33
• IPEC 472 polisher
• Klebosol silica slurry
• IC1000 on Suba IV pad stack
• Diamond pad conditioner
• OnTrak DSS with PVA brushes
• NH4OH(2%) cleaning chemistry
Outcome• Same two pressures screened
• Removal rate ~50% faster than
same process on thermal oxide
• Multiple wafers per data point
shows excellent repeatability
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CMP on Cavity Wafers
0
500
1000
1500
2000
2500
0 50 100 150 200 250
CMP Index (Pressure * Table Speed)
Re
mo
va
l R
ate
(A
ng
/min
)
Test Inputs
• Cavities patterned in Si wafers
then coated with oxide
• IPEC 472 polisher
• Klebosol silica slurry
• IC1000 on Suba IV pad stack
• Diamond pad conditioner
• OnTrak DSS with PVA brushes
• NH4OH(2%) cleaning chemistry
Outcome• Range of processes studied for
impact on cavity edges
• Relatively linear response
across range of CMP index
(confirms Prestonian behavior)
• High pressure settings showed
more edge rounding
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Sealed Cavity
Excellent bond – no evidence of separation along interface
Cavities were fabricated using
optimized CMP processes on both surfaces
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DWB Example #2
• Devices fabricated on primary wafer (200 mm)
then encased in thick TEOS layer
• CMP used to planarize TEOS layer
• Prime Si wafer used as bonding pair
• Extreme thinning performed after DWB anneal
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DWB Example #2
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• Image taken by Surface Acoustic
Microscope
• White spots = small voids
• Scribe lines barely visible due to
density variation in bottom wafer
• Initial bond made at room temp
• Bond is stronger after annealing
> Kept below 400 deg C to avoid
damage to underlying metals
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3D Packaging Apps
Source: Yole Development 2007
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SOI Background
• SOI = Silicon On Insulator
• Benefits of SOI vs bulk Si wafers
– Better Performance (esp. below 90nm device nodes)• Reduced junction capacitance Faster speeds
• Higher signal to noise ratio for RF &analog
– Lower Power• Reduced Vdd
– Better Yield & Reliability• Enhanced isolation between transistors
• Reduced sensitivity to EM interference
• Much less sensitive to ionizing radiation (aka “rad hardened”)
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SIMOX SOI flow
• Separation by Implantation of Oxygen
• Single wafer sequence
• Three key steps
– Oxygen implantation
– High temperature anneal
– Optional “Kiss” polish
• Thickness and depth of buried oxide
(BOX) layer are linked
• Top layer residual damage more of a
problem than with Smart-Cut processSource: http://www.stomee.com
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Smart-Cut SOI flow
• Developed at CEA-Leti
• Six key steps
– Thermal oxidation
– Hydrogen implantation
– Direct wafer bonding
– Splitting
– Annealing
– Touch or “Kiss” polishing
• Very flexible for thickness of
buried oxide & top Si layers
• H+ damage easier to annealSource: “SOI Technology” by Vishwas Jaju, 2004
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SOI Surface Finish
• Top Si surface finish requirement can vary
– Fabrication technique
– Technology for intended device (power, 45nm, etc.)
– Thickness of active Si layer and BOX layer are both factors in the spread of the implant depth of the ions
• Generally not possible to achieve best SOI results with standard Si prime wafer final polishing processes
– Removal rate is too high for accurate thickness control
– Very low removal amounts do not achieve lowest Ra
– Optimized CMP polish is preferred
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Polishing Comparison
Comparison Substrate Polishing CMP
Focus of the Process Improve TTV, flatness, Ra Planarize, reduce defects
Mounting Style Rigid Compressible or flexible
Impact on TTV Reduction Almost none
Typical Amount Removed µm to 10's of µm 0.1 µm to a few µm
Removal Rate >1 µm/min (stock) wide range
Uniformity outgoing TTV is primary <10% of thin film removed
Surface Finish (Ra) 0.1 - 0.4 nm Ra wide range, typical <1 nm
Defect Level Required Low and being reduced Low and being reduced
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Prime Si Polisher
Rigid platen
Polishing Pad
Wafer
Slu
rry
Rotating carrier shaft
Rigid backing plate No gimbal
Silicon Wafer Polisher
Uneven pressure across wafer face
Differential material removal from thick areas
Designed to improve TTV
Standard Single-Sided
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CMP Polisher
Rigid platen
Polishing Pad
Standard CMP Polisher
Wafer
Slu
rry
Rotating carrier shaft
Baseplate Gimbal mount
Compressible film
or membrane
Uniform pressure across wafer face
Designed for uniform film removal
Very little impact on TTV
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Typical Consumables
Typical Consumable Substrate Polishing CMP
Primary Pad Double-impregnated felt Structured polyurethane
Pad ConditioningDiamond or other styles
Used after multiple runs
Diamond conditioning disk
Continuous or every wafer
Stock SlurryHigh pH, silica abrasive
Low solids (<2%)
pH and abrasive vary by mtrl
High solids (>10%)
Slurry usage detailsHigh dilution (1:20 or 1:40)
Recirculation possible
Much smaller dilution (if any)
Single pass usage preferred
Finishing Pad Coated porous felt Wide variation by material
Final SlurryMildly alkaline, silica abrasive
Low solids (<2%)Often not required
Post-Polish Cleaner Megasonic cleaning line Double-sided scrubber
Cleaning ChemistryTypical SC1/SC2 with some
proprietary refinementsCustom by material
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SOI Examples
Parameter Typical Range Example #1 Example #2
Incoming Ra 15 – 70 Ang 26 Ang 41 Ang
Si Removal 500 Ang – 2.0 µm 550 Ang 0.85 µm
Final Ra 1.5 – 4.0 Ang 3.29 Ang 1.93 Ang
Ultrathin layer.
Target was extremely
low removal.
More typical values.
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SOI Example
• Before CMP
• Ra = 3.88 nm (38.8 Ang)
• After CMP (removed <600A)
• Ra = 0.33 nm (3.29 Ang)
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SOI CMP Optimized
• Before CMP
• Ra = 3.71 nm (37.1 Ang)
• After CMP
• Si removed = 704 Ang
• Ra = 0.12 nm (1.20 Ang)
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SOI CMP Repeatability
• Optimized CMP process
for SOI top Si layer after
splitting and annealing
• Avg Ra = 1.48 Ang
• Avg Si removal = 871 Ang
• Avg defects < 100 / wafer
• Device ready surface finish
comparable to prime Si
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0.0
0.5
1.0
1.5
2.0
2.5
3.0
3 4 6 12 13 14 15 16 17 18 19 20 21 22 23 24 25
Ra
(A
ng
)
Wafer Slot
SOI Post Polish Roughness by AFM
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Summary
• Direct wafer bonding
– Bond strength is improved when both surfaces are polished and
properly cleaned.
– Roughness is key with Ra <1nm preferred
– Surfaces with etched cavities can be bonded for niche apps
• SOI CMP
– Final surface must be similar to prime Si for Ra and defects
– Substrate polishing methods are generally too aggressive
– Key differences in pads, slurries, and equipment design
– Optimized CMP can achieve results with <800Ang removal
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Acknowledgements
• Many thanks to the following:
– Terry Pfau, Paul Lenkersdorfer, Donna Grannis of Entrepix
– Customers who gave permission to use images and data
• For additional information, please contact:
Robert L. Rhoades
Entrepix, Inc.
Chief Technology Officer
+1.602.426.8668
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