Semiconductor Manufacturing Technology · CMOS Process Flow •Overview of Areas in a Wafer Fab...
Transcript of Semiconductor Manufacturing Technology · CMOS Process Flow •Overview of Areas in a Wafer Fab...
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Introduction To
Semiconductor
Manufacturing Technology
T. S. Chao
Dept. of Electrophysics
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CMOS Process Flow
• Overview of Areas in a Wafer Fab
– Diffusion (oxidation, deposition and doping)
– Photolithography
– Etch
– Ion Implant
– Thin Films
– Polish
• CMOS Manufacturing Steps
• Parametric Testing
• 6~8 weeks involve 350-step
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Model of Typical Wafer Flow in a Sub-Micron CMOS IC Fab
Test/Sort Implant
Diffusion Etch
Polish
Photo Completed Wafer
Unpatterned Wafer
Wafer Start
Thin Films
Wafer Fabrication (front-end)
6 major production areas
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Clean: Types of Contamination
and The Problems They Cause
• Particles
• Metallic Impurities
• Organic Contamination
• Native Oxides
• Electrostatic Discharge
• Contamination often leads to a defective chip. Killer defects are those causes
of failure where the chip on the wafer fails during electrical test.
• It is estimated that 80% of all chip failure are due to killer defects from
contamination.
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Wafer Wet-Cleaning Chemicals
Contaminant Name
Chemical Mixture Description
(all Cleans are followed by a DI
Water Rinse)
Chemicals
Particles
Piranha
(SPM)
Sulfuric acid/hydrogen
peroxide/DI water H2SO4/H2O2/H2O
SC-1
(APM)
Ammonium hydroxide/hydrogen
peroxide/DI water NH4OH/H2O2/H2O
Organics SC-1
(APM)
Ammonium hydroxide/hydrogen
peroxide/DI water NH4OH/H2O2/H2O
Metallics
(not Cu)
SC-2
(HPM)
Hydrochloric acid/hydrogen
peroxide/DI water HCl/H2O2/H2O
Piranha
(SPM)
Sulfuric acid/hydrogen
peroxide/DI water H2SO4/H2O2
DHF Hydrofluoric acid/water solution
(will not remove copper) HF/H2O
Native Oxides
DHF Hydrofluoric acid/water solution
(will not remove copper) HF/H2O
BHF Buffered hydrofluoric acid NH4F/HF/H2O
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Typical Wafer Wet-Cleaning Sequence
Cleaning Step What it Cleans
H2SO4/H2O2 (piranha) Organics & metals
UPW rinse (ultrapure water) Rinse
HF/H2O (dilute HF) Native oxides
UPW rinse Rinse
NH4OH/H2O2/H2O (SC-1) Particles
UPW rinse Rinse
HF/H2O Native oxides
UPW rinse Rinse
HCl/H2O2/H2O (SC-2) Metals
UPW rinse Rinse
HF/H2O Native oxides
UPW rinse Rinse
Drying Dry
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Diffusion: Simplified Schematic of High-Temperature Furnace
Gas flow
controller
Temperature
controller
Pressure
controller
Heater 1
Heater 2
Heater 3
Exhaust
Process gas
Quartz tube
Three-zone Heating Elements
Temperature- setting voltages
Thermocouple measurements
Can do : oxidation, diffusion, deposition, anneals, and alloy
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Dry Oxidation Time (Minutes)
Oxi
de
thic
knes
s (m
m)
(100) Silicon
Time (minutes)
10 104 102 103 0.01
0.1
1.0
10.0
Si (solid) + O2 (gas) SiO2 (solid)
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Wet Oxygen Oxidation
HCl N2 O2 H2
Gas panel Furnace
Burn box
Scrubber
Exhaust
• H2+O2 H2O
• Si (solid) + 2H2O SiO2 (solid) + 2H2
• The fast growth rate in wet atmosphere is due to
the faster diffusion and higher solubility of water
vapor than oxygen in silicon dioxide
• Hydrogen molecules produced in the reaction are
trapped in oxide, less dense, using heating
(annealing) to improve.
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Negative Lithography
Ultraviolet light
Island
• Areas exposed to light become crosslinked and resist the developer chemical.
Resulting pattern after the resist is developed.
Window
Exposed area of photoresist
Shadow on photoresist
Chrome island on glass mask
Silicon substrate
Photoresist Oxide
Photoresist
Oxide
Silicon substrate
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Positive Lithography
photoresist
silicon substrate
oxide oxide
silicon substrate
photoresist
Ultraviolet light
Island
Areas exposed to light are dissolved.
Resulting pattern after the resist is developed.
Shadow on photoresist
Exposed area of photoresist
Chrome island on glass mask
Window
Silicon substrate
Photoresist Oxide
Photoresist
Oxide
Silicon substrate
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Eight Steps of Photolithography
8) Develop inspect 5) Post-exposure bake
6) Develop 7) Hard bake
UV Light
Mask
4) Alignment and Exposure
Resist
2) Spin coat 3) Soft bake 1) Vapor prime
HMDS
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Photolithography Bay in a Sub-micron Wafer Fab
• It is to photograph the image of a circuit pattern onto the photoresist that coats the
wafer surface.
• Yellow fluorescent does not affect photoresist, but sensitive to UV
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Load Station Vapor Prime
Soft Bake
Cool Plate
Cool Plate
Hard Bake
Transfer Station Resist Coat
Develop-Rinse
Edge-Bead Removal
Wafer Transfer System Wafer Cassettes
Wafer Stepper (Alignment/Exposure System)
Simplified Schematic of a Photolithography Processing Module
Note: wafers flow from photolithography into only two other areas: etch and ion implant
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Etch: Dissociation
• Electron collides with a molecule, it can
break the chemical bond and generate free
radicals:
e + AB A + B + e
• Free radicals have at least one unpaired
electron and are chemically very reactive.
• Increasing chemical reaction rate
• Very important for both etch and CVD.
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Simplified Schematic of Dry Plasma Etcher
e-
e-
R +
Glow discharge (plasma)
Gas distribution baffle High-frequency energy
Flow of byproducts and process gases
Anode electrode
Electromagnetic field
Free electron
Ion sheath
Chamber wall
Positive ion
Etchant gas entering gas inlet
RF coax cable
Photon
Wafer
Cathode electrode
Radical chemical
Vacuum line
Exhaust to vacuum pump
Vacuum gauge
e-
• The etch process creates a permanent pattern on the wafer in areas not protected by
the photoresist pattern
• Including: dry etching, wet etching and photoresist stripper
• After dry etching: photoresist stripper + wet cleaning
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Wet Chemical Isotropic Etch
Isotropic etch - etches in all directions at the same rate
Substrate
Film
Resist
• Etch profile refers to the shape of the sidewall of the etched
feature
• Isotropic etch profile leads to a undercutting, results in an
undesirable loss of the linewidth
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Anisotropic Etch with Vertical Etch Profile
Anisotropic etch - etches in only one direction
Resist
Substrate
Film
• The rate of etching is on only one direction perpendicular to the wafer surface
• There is very little lateral etching activity
• This leaves vertical sidewalls, permitting a higher packing density of etched
features on the chip
• With smaller geometries, the etch profiles have higher aspect ratios
• It is difficult to get etchant chemicals in and reaction by-products out of the
high-aspect ratio openings
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Implantation: Common Dopants Used in Semiconductor Manufacturing
Acceptor Dopant
Group IIIA
(P-Type)
Semiconductor
Group IVA
Donor Dopant
Group VA
(N-Type)
ElementAtomic
NumberElement
Atomic
NumberElement
Atomic
Number
Boron (B) 5 Carbon 6 Nitrogen 7
Aluminum 13 Silicon (Si) 14 Phosphorus (P) 15
Gallium 31 Germanium 32 Arsenic (As) 33
Indium 49 Tin 50 Antimony 51
• Doping is the introduction of a dopant into the crystal structure of a
semiconductor material to modify its electronic properties
• Dopants are referred to as impurities
• Two techniques: thermal diffusion and ion implantation (dominant)
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General Schematic of an Ion Implanter
Ion source
Analyzing magnet
Acceleration column Ion beam
Plasma
Process chamber
Extraction assembly
Scanning disk
• Ion source: positive charge
• Extraction assembly: extract ions
• Mass Analyzer: form a beam of the desired dopant ions
• Acceleration column: to attain a high velocity
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Annealing of Silicon Crystal
Repaired Si lattice structure and
activated dopant-silicon bonds
b) Si lattice after annealing a) Damaged Si lattice during implant
Ion Beam
• Using Furnace or RTA, hot-wall furnace using high temperature causes extensive
dopant diffusion and is undesirable
• RTA minimizes a phenomenon known as transient enhanced diffusion, to achieve
acceptable junction depth control in shallow implants (~150°C/sec)
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Thin Film Metallization Bay
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Simple Parallel Plate DC Diode Sputtering System
Exhaust
e- e-
e-
DC diode sputterer
Substrate
1) Electric fields create Ar+ ions.
2) High-energy Ar+ ions collide with metal target.
3) Metallic atoms are dislodged from target.
Anode (+)
Cathode (-)
Argon atoms
Electric field
Metal target
Plasma
5) Metal deposits on substrate
6) Excess matter is removed from chamber by a vacuum pump.
4) Metal atoms migrate toward substrate.
Gas delivery
+
+ + +
+
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Simplified Schematics of CVD Processing System
Capacitive-coupled RF input
Susceptor
Heat lamps
Wafer
Gas inlet
Exhaust
Chemical vapor deposition
Process chamber
CVD cluster tool
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Schematic of CVD Transport and Reaction 8 Steps
CVD Reactor
Substrate
Continuous film
8) By-product removal
1) Mass transport of reactants
By-products 2) Film precursor
reactions
3) Diffusion of gas molecules
4) Adsorption of precursors
5) Precursor diffusion into substrate
6) Surface reactions
7) Desorption of byproducts
Exhaust
Gas delivery
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CVD Reaction
• Take place on wafer surface: heterogeneous reaction
(surface catalyzed).
• Homogeneous reaction: above surface (gas reaction),
which is poor adhesion, low-density with high defects
• SiH4 SiH2 +H2 ( SiH2 is precursor, it is pyrolysis)
• CVD reaction steps are sequential, the slowest step defines
the bottleneck
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LPCVD Reaction Chamber for Deposition of Oxides, Nitrides, or Polysilicon
Three-zone heating element
Spike thermocouples (external, control)
Pressure gauge
Exhaust to vacuum pump
Gas inlet
Profile thermocouples
(internal)
• Limited by surface reaction, flow condition is not important
• Films are uniformly deposited on a large number of wafer surface as
long as the temperature is tightly controlled
• Conformal film coverage on the wafer
• Low growth rate than APCVD and need routine maintenance
• In-situ clean, using ClF3 or NF3
• 3SiCl2H2 + 4NH3 Si3N4 + 6HCl + 6H2
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Polish Bay in a Sub-micron Wafer Fab • Chemical mechanical planarization (CMP) process is to planarize the top
surface of the wafer by lowering the high topography to be level with the lower
surface area of the wafer
• It combines chemical etching and mechanical abrading to remove layer
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Schematic of Chemical Mechanical Planarization (CMP)
Wafer
Wafer carrier
Rotating platen
Polishing slurry
Slurry dispenser
Polishing pad
Downforce
Step height: etchback ~ 7000Å vs. CMP ~ 50Å
• CMP achieves wafer planarity by removing high features on the surface
more quickly relative to the low feature (high pressure by Preston’s eq.)
• Both metal and dielectric layers can be removed
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VDD = + 3.0 V
Open gate (no charge)
Lamp
(no conduction)
Source Drain
p-type silicon substrate
n+ n+
Gate
VGG = + 0.7 V
S1
Biasing Circuit for an NMOS Transistor
Figure 3.16
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NMOS Transistor in Conduction Mode
S1
IDS
VDD = + 3.0 V
Positive charge
Lamp
e-
e-
e-
+ + + + + + + + + + + + + + + + + + Source Drain
p-type silicon substrate
Gate
n+ n+
Holes
VGG = + 0.7 V
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VDD = -3.0 V
Open gate (no charge)
Lamp
(no conduction)
Source
Gate
Drain
p+ p+
n-type silicon substrate
VGG = - 0.7 V
S1
Biasing Circuit for a P-Channel MOSFET
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IDS
VDD = - 3.0 V
Lamp
e-
e-
e-
Gate
Source Drain - - - - - - - - - - - - - - - - - - - - - - - -
n-type silicon substrate Electrons
p+ p+
Negative charge VGG = - 0.7 V
S1
PMOS Transistor in Conduction Mode
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S
G
Input
D
+ VDD
D
S
G
Output
pMOSFET
nMOSFET
- VSS
Schematic of a CMOS Inverter
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-VSS +VDD S D D S
G G
p+ p+
p-well n+ n+
n-type silicon substrate
n+ p+
pMOSFET nMOSFET
Field oxide
Interlayer Oxide
Metal
Cross-section of CMOS Inverter
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1. Twin-well Implants
2. Shallow Trench Isolation
3. Gate Structure
4. Lightly Doped Drain Implants
5. Sidewall Spacer
6. Source/Drain Implants
7. Contact Formation
8. Local Interconnect
9. Interlayer Dielectric to Via-1
10. First Metal Layer
11. Second ILD to Via-2
12. Second Metal Layer to Via-3
13. Metal-3 to Pad Etch
14. Parametric Testing
CMOS Manufacturing Steps
Passivation layer Bonding pad metal
p+ Silicon substrate
LI oxide
n-well p-well
ILD-1
ILD-2
ILD-3
ILD-4
ILD-5
M-1
M-2
M-3
M-4
Poly gate
p- Epitaxial layer
p+
ILD-6
n+ 2
1
7
11
13
14
12
10
Via 9
LI metal 8
3
p+
5
p+ n+ n+ STI 6 4
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n-well Formation
3
1
2
Photo
Implant
Diffusion
4
Polish
Etch
5
Thin Films
~5 um
(Dia = 200 mm, ~2 mm thick)
Photoresist
Phosphorus implant
3
1
2
p+ Silicon substrate
p- Epitaxial layer
Oxide
5
n-well4
• Epitaxial layer : improved quality and fewer defect
• In step 2, initial oxide (15 nm) : (1) protects epi layer
from contamination, (2) prevents excessive damage to
ion/implantation, (3) control the depth of the dopant
during implantation
• In step 5, anneal: (1) drive-in, (2) repair damage, (3)
activation
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Mask # 1 : N-well formation
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p-well Formation
Thin Films
3
1
2
Photo
Implant
Diffusion
Polish
Etch
p+ Silicon substrate
Boron implant
Photoresist1
p- Epitaxial layer
Oxide
3n-well 2 p-well
• 2nd mask, this mask is the direct opposite of the n-well implant mask
• Boron is 1/3 the mass of P, so 1/3 energy is used.
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Mask # 2 : P-well formation
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STI Trench Etch
STI: shallow trench isolation
• Barrier oxide: a new oxide
• Nitride: (1) protect active region, (2) stop layer during CMP
• 3rd mask
• STI etching
Thin Films
1 2
Photo
Polish
Etch
Implant
Diffusion
3 4
+Ions
Selective etching opens isolation regions in the epi layer.
p+ Silicon substrate
p- Epitaxial layer
n-well p-well
3 Photoresist
2 Nitride 4
1 Oxide
STI trench
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Mask # 3: Shallow Trench Isolation formation
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STI Oxide Fill
• Liner oxide to improve the interface between the silicon and
trench CVD oxide
• CVD oxide deposition or spin-on-glass (SOG)
1
2
Diffusion
Polish
Etch Photo
Implant
Thin Films
p-well
Trench fill by chemical vapor deposition
1
Liner oxide
p+ Silicon substrate
p- Epitaxial layer
n-well
2
Nitride
Trench CVD oxide
Oxide
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STI Formation
1. Trench oxide polish (CMP): nitride as the CMP stop layer
since nitride is harder than oxide
2. Nitride strip: hot phosphoric acid
3. Anti-punch-through and Vth adjustment ion implantation
Thin Films
1
2
Diffusion Etch Photo
Implant
Polish
p-well
1
2
Planarization by chemical-mechanical polishing
STI oxide after polish
Liner oxide
p+ Silicon substrate
p- Epitaxial layer
n-well
Nitride strip
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Poly Gate Structure Process
• Oxide thickness 1.5 ~ 5.0 nm is thermal grown
• Poly-Si ~ 300 nm is doped and deposited in LPCVD using SiH4
• Need Antireflective coating (ARC), very critical
• The most critical etching step in dry etching
Thin Films
1 2
Diffusion Etch Photo
Implant
Polish
3 4
p+ Silicon substrate
Gate oxide 1
2
p- Epitaxial layer
n-well p-well
Polysilicon deposition Poly gate etch 4
3 Photoresist
ARC
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Mask # 4 :Poly-Si gate formation
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n- LDD Implant
• LDD: lightly doped drain to reduce S/D leakage
• Large mass implant (BF2, instead of B, As instead of P) and
amorphous surface helps maintain a shallow junction
• 5th mask
Thin Films
1
2
Diffusion Etch Photo
Implant
Polish
p+ Silicon substrate
p- Epitaxial layer
n-well p-well n- n- n-
1 Photoresist mask
Arsenic n- LDD implant 2
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Mask # 5: N- LDD formation
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p- LDD Implant
• 6th mask
• In modern device, high doped drain is used to reduce series
resistance. It called S/D extension
1
2
Diffusion Etch Photo
Implant
Polish Thin Films
p+ Silicon substrate
p- Epitaxial layer
n-well p-well
Photoresist Mask 1
p- p-
Photoresist mask 1
n- n-
2 BF p- LDD implant 2
p- n-
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Mask # 6: P- LDD formation
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Side Wall Spacer Formation
• Spacer is used to prevent higher S/D implant from penetrating
too close to the channel, cover LDD.
• CVD oxide + etch back by anisotropic plasma etching
1
2
Diffusion Etch Photo
Implant
Polish Thin Films
+Ions
p+ Silicon substrate
p- Epitaxial layer
n-well p-well p- p-
1 Spacer oxide Side wall spacer
2 Spacer etchback by anisotropic plasma etcher
p- n- n- n-
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n+ Source/Drain Implant
• Energy is high than LDD I/I, the junction is deep
• 7th mask
Thin Films
1
2
Diffusion Etch Photo
Implant
Polish
p+ Silicon substrate
p- Epitaxial layer
n-well p-well n+
Arsenic n+ S/D implant 2
Photoresist mask 1
n+ n+
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Mask # 7: N+ Source/Drain formation
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p+ Source/Drain Implant
• 8th mask
• Using rapid thermal anneal (RTA) to prevent dopant
spreading and to control diffusion of dopant
1
2
Diffusion Etch Photo
Polish Thin Films
Implant
3
Boron p+ S/D implant 2
p+ Silicon substrate
p- Epitaxial layer
n-well p-well
Photoresist Mask 1 1 Photoresist mask
n+ p+ p+ n+ n+ p+
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Mask # 8 : P+ Source/Drain formation
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Contact Formation
• Titanium (Ti) is a good choice for metal contact due to low
resistivity and good adhesion
• No mask needed, called self-align
• Using Ar to sputtering metal
• Anneal to form TiSi2, tisilicide
• Chemical etching to remove unreact Ti, leaving TiSi2, called
selective etching
Thin Films
1 2
Diffusion Etch Photo
Implant
Polish 3 2 Tisilicide contact formation (anneal) Titanium etch 3
Titanium depostion 1
n+ p+ n-well p+ n+ p-well n+ p+
p- Epitaxial layer
p+ Silicon substrate
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LI Oxide as a Dielectric for Inlaid LI Metal (Damascene)
LI metal
LI oxide
LI: local interconnection
• Damascene: a name doped of year ago from a practice that began
thousands ago by artist in Damascus, Syria
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LI Oxide Dielectric Formation
• Nitride: protect active region
• Doped oxide
• Oxide polish
• 9th mask
1 Nitride CVD
p-well n-well
p- Epitaxial layer
p+ Silicon substrate
LI oxide
2 Doped oxide CVD
4 LI oxide etch Oxide polish 3
Diffusion Etch Photo
Implant
Polish
3
4
2
1
Thin Films
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Mask # 9: Local Interconnection formation
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LI Metal Formation
• Ti/TiN is used: Ti for adhesion and TiN for diffusion barrier
• Tungsten (W) is preferred over Aluminum (Al) for LI metal
due to its ability to fill holes without leaving voids
Thin Films
Diffusion Photo
Implant
3 2 1 4
Etch
Polish
n-well
LI tungsten polish Tungsten deposition
Ti/TiN deposition 2
3 4
LI oxide
Ti deposition
1 p-well
p- Epitaxial layer
p+ Silicon substrate
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Via-1 Formation
• Interlayer dielectric (ILD): insulator between metal (800nm)
• Via: electrical pathway from one metal layer to adjacent metal layer
• 10th mask
Diffusion Etch Photo
Implant
Polish
3
2
1 Thin Films
Oxide polish ILD-1 oxide etch (Via-1 formation) 2 3
LI oxide
ILD-1 oxide deposition
1
ILD-1
p-well n-well
p- Epitaxial layer
p+ Silicon substrate
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Mask # 10: Via-1 formation
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Plug-1 Formation
• Ti layer as a glue layer to hold W
• TiN layer as the diffusion barrier
• Tungsten (W) as the via
• CMP W-polish
Thin Films
Diffusion Photo
Implant
3 2 1 4
Etch
Polish
Tungsten deposition
Ti/TiN deposition 2
3
1
n-well
p- Epitaxial layer
p+ Silicon substrate
Ti dep.
Tungsten polish (Plug-1) 4
LI oxide
ILD-1
p-well
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SEM Micrographs of Polysilicon, Tungsten LI and Tungsten Plugs
Micrograph courtesy of Integrated Circuit Engineering
Polysilicon Tungsten LI
Tungsten plug
Mag. 17,000 X
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Metal-1 Interconnect Formation
• Metal stack: Ti/Al (or Cu)/TiN is used
• Al(99%) + Cu (1%) is used to improve reliability
• 11th mask
2 3 4 1
TiN deposition
Al + Cu (1%) deposition
Ti Deposition
LI oxide
ILD-1
Metal-1 etch
p-well n-well
p- Epitaxial layer
p+ Silicon substrate
Photo Etch Diffusion
Implant
4
1 3 2
Polish Thin Films
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Mask # 11: Metal-1 formation
Common drain or output to next stage
P+ Source to Vdd N+ Source to ground
Common gate for input
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SEM Micrographs of First Metal Layer over First Set of Tungsten Vias
Micrograph courtesy of Integrated Circuit Engineering
TiN metal cap
Mag. 17,000 X Tungsten plug
Metal 1, Al
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Via-2 Formation
• Gap fill: fill the gap between metal
• Oxide deposition
• Oxide polish
• 12th mask
4
p+ Silicon substrate
p- Epitaxial layer
n-well p-well
LI oxide
ILD-1
Oxide polish
ILD-2 gap fill 1
3 2
ILD-2 oxide deposition
ILD-2 oxide etch (Via-2 formation)
Photo Etch
Polish
Diffusion
Implant
4
2 3 1
Thin Films
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Mask # 12: Via-2 formation
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Plug-2 Formation
• Ti/TiN/W
• CMP W polish
LI oxide
Tungsten deposition (Plug-2)
Ti/TiN deposition 2
3
Ti deposition 1
ILD-1
ILD-2
p+ Silicon substrate
p- Epitaxial layer
n-well p-well
Tungsten polish 4
Thin Films
Diffusion Photo
Implant
3 2 1 4
Etch
Polish
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Metal-2 Interconnect Formation
• Metal 2: Ti/Al/TiN
• ILD-3 gap filling
• ILD-3
• ILD-polish
• Via-3 etch and via deposition, Ti/TiN/W
p+ Silicon substrate
p- Epitaxial layer
n-well p-well
Gap fill
3 Via-3/Plug-3 formation Metal-2 deposition to etch
ILD-3 oxide polish
2
1 4
LI oxide
ILD-1
ILD-2
ILD-3
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Mask # 13: Metal-2 formation
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Mask # 14: Via-3 formation
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Mask # 15: Metal-3 formation
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CMOS layout (mask 1 to mask 12)
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Full 0.18 mm CMOS Cross Section
• Passivation layer of
nitride is used to
protect from
moisture, scratched,
and contamination
• ILD-6 : oxide
Passivation layer Bonding pad metal
p+ Silicon substrate
LI oxide
STI
n-well p-well
ILD-1
ILD-2
ILD-3
ILD-4
ILD-5
M-1
M-2
M-3
M-4
Poly gate
p- Epitaxial layer
p+ n+
ILD-6
LI metal
Via
p+ p+ n+ n+
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SEM Micrograph of Cross-section of AMD Microprocessor
Micrograph courtesy of Integrated Circuit Engineering
Mag. 18,250 X
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Wafer Electrical Test using a Micromanipulator Prober (Parametric Testing)
Photo courtesy of Advanced Micro Devices
• After metal-1 etch,
wafer is tested, and
after passivation test
again
• Automatically test on
wafer, sort good die (X-
Y position, previous
marked with an red ink)
• Before package, wafer
is backgrind to a
thinner thickness for
easier slice and heat
dissipation