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Basic IC Fabrication 2
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1
Inverter fabrication
3
2
Basic CMOS Process Flow
Starting Point: Pure silicon wafer (heavily-doped) with a lightly-doped epitaxial (epi) layer.
An epi layer is used to provide a cleaner layer for device formation and to prevent “latch-up” of CMOS transistors.
Silicon Substrate P+
~2 microns
~725 microns
Silicon Epi Layer P-
3
Basic CMOS Process Flow - Shallow Trench Formation
Grow Pad Oxide: A very thin (~200A) layer of silicon dioxide (SiO2) is grown on the surface by reacting silicon and oxygen at high temperatures. This will serve as a stress relief layer between the silicon and the subsequent nitride layer.
Silicon Substrate P+
Silicon Epi Layer P-
Pad Oxide
4
Basic CMOS Process Flow - Shallow Trench Formation
Deposit Silicon Nitride: A layer (~2500A) of silicon nitride (Si3N4) is deposited using Chemical Vapor Deposition. This will serve as a polish stop layer during trench formation.
Silicon Substrate P+
Silicon Epi Layer P-
Silicon Nitride
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Basic CMOS Process Flow - Shallow Trench Formation
Pattern Photoresist for Definition of Trenches: One of the most critical patterning steps in the process. 0.5 - 1.0 microns of resist is spun, exposed, and developed.
Silicon Substrate P+
Silicon Epi Layer P-
Silicon Nitride
Photoresist
6
Basic CMOS Process Flow - Shallow Trench Formation
Etch Nitride and Pad Oxide: A reactive ion etch (RIE) utilizing fluorine chemistry is used.
Silicon Substrate P+
Silicon Epi Layer P-
Silicon Nitride
Photoresist
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Basic CMOS Process Flow - Shallow Trench Formation
Etch Trenches in Silicon: A reactive ion etch (RIE) utilizing fluorine chemistry is used. Defines transistor active areas.
Silicon Substrate P+
Silicon Epi Layer P-
Silicon Nitride
Photoresist
Transistor Active Areas
Isolation Trenches
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Basic CMOS Process Flow - Shallow Trench Formation
Remove Photoresist: An oxygen plasma is used to burn off the resist layer.
Silicon Substrate P+
Silicon Epi Layer P-
Silicon Nitride
Transistor Active Areas
Isolation Trenches
9
Basic CMOS Process Flow - Shallow Trench Formation
Fill Trenches with Oxide: A CVD oxide layer is deposited to conformally fill the trenches. The oxide will prevent “cross-talk” between the transistors in the circuit.
Silicon Substrate P+
Silicon Epi Layer P-
Silicon Nitride
Future PMOS Transistor
Silicon Dioxide
Future NMOS Transistor
No current can flow through here!
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Basic CMOS Process Flow - Shallow Trench Formation
Polish Trench Oxide: The surface oxide is removed using a Chemical Mechanical Polish (CMP). The CMP process is designed to stop on silicon nitride.
Silicon Substrate P+
Silicon Epi Layer P-
Silicon Nitride
Future PMOS Transistor Future NMOS Transistor
No current can flow through here!
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Basic CMOS Process Flow - Shallow Trench Formation
Remove Silicon Nitride: A wet etch in hot phosphoric acid (H3PO4) is used, completing formation of Shallow Trench Isolation (STI).
Silicon Substrate P+
Silicon Epi Layer P-
Future PMOS Transistor Future NMOS Transistor
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Basic CMOS Process Flow - Well Formation
Pattern Photoresist for N-Well Formation: A non-critical masking layer, utilizing thicker resist to block the implant.
Silicon Substrate P+
Silicon Epi Layer P-
Future PMOS Transistor Future NMOS Transistor
Photoresist
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Basic CMOS Process Flow - Well Formation
Implant N-Well: A deep (high-energy) implant of phosphorous ions creates a localized N-type region for the PMOS transistor.
Silicon Substrate P+
Silicon Epi Layer P-
Future NMOS Transistor
Photoresist
N- Well
Phosphorous (-) Ions
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Basic CMOS Process Flow - Well Formation
Strip N-Well Photoresist:
Silicon Substrate P+
Silicon Epi Layer P-
Future NMOS TransistorN- Well
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Photoresist
Basic CMOS Process Flow - Well Formation
Pattern Photoresist for P-Well Formation: A non-critical masking layer, utilizing thicker resist to block the implant.
Silicon Substrate P+
Silicon Epi Layer P-
Future NMOS TransistorN- Well
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Basic CMOS Process Flow - Well Formation
Implant P-Well: A deep (high-energy) implant of boron ions creates a localized P-type region for the NMOS transistor.
Silicon Substrate P+
Silicon Epi Layer P-
Photoresist
N- Well
Boron (+) Ions
P- Well
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Basic CMOS Process Flow - Well Formation
Strip P-Well Photoresist:
Silicon Substrate P+
Silicon Epi Layer P-
N- Well P- Well
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Basic CMOS Process Flow - Well Formation
Anneal Well Implants: This step repairs damage to the silicon surface caused by the implants and electrically activates the dopants. It also drives the dopants somewhat deeper, but Rapid Thermal Processing is used to minimize dopant spreading.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
19
Basic CMOS Process Flow - Gate Formation
Grow Sacrificial Oxide: A thin (~250A) oxide layer is grown to capture defects in the silicon surface.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
Sacrificial Oxide
20
Basic CMOS Process Flow - Gate Formation
Remove Sacrificial Oxide: Sac ox is immediately removed in a wet HF solution, leaving behind a clean silicon surface.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
21
Basic CMOS Process Flow - Gate Formation
Grow Gate Oxide: This is the most critical step in the process! A very thin (20-100A) oxide layer is grown that will serve as the gate dielectric for both transistors. It must be extremely clean, and grown to a very precise thickness (+/- 1A).
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
22
Basic CMOS Process Flow - Gate Formation
Deposit Polysilicon: Polycrystalline silicon is deposited using Chemical Vapor Deposition to a thickness of 1500-3000 angstroms.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
Polysilicon
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Basic CMOS Process Flow - Gate Formation
Pattern Photoresist to Define Gate Electrodes:
This is the most critical patterning step in the process! Precise sizing of the poly gate length is a first-order determinant of transistor switching speed. The highest-technology patterning systems are used (i.e. DUV) along with thinner-than-normal photoresist due to the critical nature of the layer.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
PhotoresistChannel Length
Polysilicon
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Basic CMOS Process Flow - Gate Formation
Etch Polysilicon and Strip Resist: Reactive Ion Etching using fluorine chemistry is used. The completes the formation of the “gate stack.”
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
Gate Oxide
Poly Gate Electrode
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Basic CMOS Process Flow - Gate FormationOxidize Polysilicon: A thin layer of oxide is grown on top of the polysilicon to act as a buffer between the poly and the subsequent silicon nitride layer.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
Gate Oxide
Poly Gate Electrode
Poly Re-oxidation
26
Basic CMOS Process Flow - Source/Drain Formation
Pattern Photoresist for NMOS Transistor Tip Implant:
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
Photoresist
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Basic CMOS Process Flow - Source/Drain FormationNMOS Transistor Tip Implant: A very shallow (low energy) and low dose implant of arsenic ions begins the formation of the NMOS transistor source and drain. The “tip” will serve to reduce hot electron effects near the gate region.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
Photoresist
Arsenic (-) Ions
N Tip
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Basic CMOS Process Flow - Source/Drain Formation
Strip Photoresist:
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N Tip
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Basic CMOS Process Flow - Source/Drain Formation
Pattern Photoresist for PMOS Transistor Tip Implant:
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
Photoresist
N Tip
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Basic CMOS Process Flow - Source/Drain Formation
PMOS Transistor Tip Implant: A very shallow (low energy) and low dose implant of BF2 ions begins the formation of the PMOS transistor source and drain. The “tip” will serve to reduce hot electron effects near the gate region.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
Photoresist
BF2 (+) Ions
N TipP Tip
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Basic CMOS Process Flow - Source/Drain Formation
Strip Photoresist:
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N TipP Tip
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Basic CMOS Process Flow - Source/Drain Formation
Deposit Silicon Nitride Layer: Using Chemical Vapor Deposition, thickness 1200-1800A.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
Silicon Nitride
Thinner Here
Thicker Here
N TipP Tip
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Basic CMOS Process Flow - Source/Drain FormationEtch Nitride to Form Spacer Sidewalls: Using a carefully controlled RIE etch, the thin nitride is removed from the horizontal surfaces, but the sidewalls remain. These sidewalls will precisely position the implants that form the transistor sources and drains.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
Spacer Sidewall
N TipP Tip
34
Basic CMOS Process Flow - Source/Drain Formation
Pattern Photoresist for NMOS Transistor Source/Drain Implant:
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
Photoresist
N TipP Tip
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Basic CMOS Process Flow - Source/Drain FormationNMOS Transistor Source/Drain Implant: A shallow and high-dose implant of arsenic ions completes the formation of the heavily-doped NMOS transistor source and drain. The spacer shadows the implant near the gate region.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
Photoresist
Arsenic (-) Ions
N+ Source N+ DrainP Tip
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Basic CMOS Process Flow - Source/Drain Formation
Strip Photoresist:
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP Tip
37
Basic CMOS Process Flow - Source/Drain FormationPattern Photoresist for PMOS Transistor Source/Drain Implant:
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ Drain
Photoresist
P Tip
38
Basic CMOS Process Flow - Source/Drain FormationPMOS Transistor Source/Drain Implant: A shallow and high-dose implant of BF2 ions completes the formation of the heavily-doped PMOS transistor source and drain. The spacer shadows the implant near the gate region.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
BF2 (+) Ions
Photoresist
N+ Source N+ DrainP+ DrainP+ Source
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Basic CMOS Process Flow - Source/Drain Formation
Strip Photoresist and Anneal Implants: Use Rapid Thermal Annealing to virtually eliminate dopant migration in the shallow source and drains. The electronic devices are now completely formed. All that remains is to connect them together.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ DrainP+ Source
Lightly Doped “Tips”
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Basic CMOS Process Flow - Salicide Formation
Strip Surface Oxides: A quick dip in HF to expose bare silicon in the source, gate, and drain areas.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
41
Basic CMOS Process Flow - Salicide Formation
Deposit Titanium: Use a sputterer to deposit a thin (200-400A) layer of titanium across the entire wafer surface.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ DrainTitanium
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Basic CMOS Process Flow - Salicide Formation
Titanium Silicide Formation: Rapid Thermal Processing in nitrogen at 800 Degrees C causes the titanium to react with silicon, forming titanium silicide, where the two are in contact. In other areas, the titanium is unchanged. This process perfectly aligns the silicide to the exposed silicon, and is called Self-Aligned Silicide, or Salicide.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
Titanium SilicideUnreacted Titanium
43
Basic CMOS Process Flow - Salicide Formation
Titanium Etch: The unreacted titanium is removed using a wet etch in NH4OH + H2O2. The titanium silicide remains. TiSi2 provides an ohmic contact between silicon and metal.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
Titanium Silicide
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Basic CMOS Process Flow - 1st Interconnect LayerDeposit BPSG: Silicon dioxide doped with small amounts of boron and phosphorous to enable film reflow and to getter contaminants. Deposited using Chemical Vapor Deposition. Approximate thickness is 1 micron. This layer will electrically insulate the devices from the 1st metal layer.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG
45
Basic CMOS Process Flow - 1st Interconnect Layer
Polish BPSG: Use Chemical Mechanical Polishing to achieve a flat surface on the BPSG layer. If not removed, the bumps on the surface from the underlying topography would cause a problem for the subsequent photolithography steps and degrade metal step coverage.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG
46
Basic CMOS Process Flow - 1st Interconnect Layer
Pattern Photoresist to Define Contacts: Contacts are openings in the BPSG layer enabling electrical access to the devices below. This is a critical photolithography step.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG
Photoresist
47
Basic CMOS Process Flow - 1st Interconnect Layer
Contact Etch: A carefully designed RIE etch using fluorine chemistry to achieve vertical sidewalls.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG
Photoresist
48
Strip Photoresist:
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG
Basic CMOS Process Flow - 1st Interconnect Layer
49
Basic CMOS Process Flow - 1st Interconnect Layer
Titanium Nitride Deposition: A sputterer is used to deposit TiN to a thickness of about 200A. This layer will help the subsequent tungsten layer to adhere to the oxide.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG
Titanium Nitride
50
Basic CMOS Process Flow - 1st Interconnect LayerTungsten Deposition: Tungsten is chosen because it deposits conformally (via CVD) and can fill the contact holes. The thickness must be at least half of the diameter of the contact.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG
Titanium Nitride
Tungsten
51
Basic CMOS Process Flow - 1st Interconnect Layer
Polish Tungsten: CMP is used to remove the surface tungsten. The remaining tungsten forms “plugs”. The surface titanium nitride is also removed.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG W Contact Plug
52
Deposit Metal1 Layer: Each interconnect layer is actually a sandwich of different layers. A sample is shown below. The films are deposited by sputtering.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG W Contact Plug
Metal1
Ti (200A) - electromigration shuntTiN (500A) - diffusion barrier
AlCu (5000A) - main conductor
TiN (500A) - antireflective coating
Basic CMOS Process Flow - 1st Interconnect Layer
53
Pattern Photoresist for Metal1 Interconnects:
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG W Contact Plug
Metal1
Photoresist
Basic CMOS Process Flow - 1st Interconnect Layer
54
Etch Metal1: An RIE etch utilizing chlorine chemistry. Multiple etch steps are required due to the multiple different metal layers.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG W Contact Plug
Metal1
Photoresist
Basic CMOS Process Flow - 1st Interconnect Layer
55
Strip Photoresist: First interconnect layer is completed.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG W Contact Plug
Metal1
Basic CMOS Process Flow - 1st Interconnect Layer
56
Basic CMOS Process Flow - 2nd through Nth (as many as 8) Interconnect Layer
Deposit IMD1: Undoped silicon dioxide is deposited using successive CVD depositions and etches to achieve filling between metal lines. Approximate thickness is 1 micron. This layer will electrically insulate the metal layers from one another.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG W Contact Plug
Metal1
IMD1
57
Basic CMOS Process Flow - 2nd through Nth interconnect Layer
Polish IMD1: Use Chemical Mechanical Polishing to achieve a flat surface on the IMD layer. If not removed, the bumps on the surface from the underlying topography would cause a problem for the subsequent photolithography steps and degrade metal step coverage.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG W Contact Plug
Metal1
IMD1
58
Pattern Photoresist to Define Vias: Vias are contact openings in the IMD layers enabling electrical access between metal layers.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG W Contact Plug
Metal1
IMD1
Photoresist
Basic CMOS Process Flow - 2nd through Nth interconnect Layer
59
Via Etch: A carefully designed RIE etch using fluorine chemistry to achieve vertical sidewalls.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG W Contact Plug
Metal1
IMD1
Photoresist
Basic CMOS Process Flow - 2nd through Nth interconnect Layer
60
Strip Photoresist:
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG W Contact Plug
Metal1
IMD1
Basic CMOS Process Flow - 2nd through Nth interconnect Layer
61
Tungsten
Deposit Titanium Nitride and Tungsten: Same as for the first interconnect layer.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG W Contact Plug
Metal1
IMD1
Basic CMOS Process Flow - 2nd through Nth interconnect Layer
62
Polish Tungsten:
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG W Contact Plug
Metal1
IMD1 W Via Plug
Basic CMOS Process Flow - 2nd through Nth interconnect Layer
63
Deposit Metal2: Subsequent metal stacks will be similar to Metal1 but tend to increase in thickness and width as their runs are longer and they carry more current.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG W Contact Plug
Metal1
IMD1 W Via Plug
Metal2
Basic CMOS Process Flow - 2nd through Nth interconnect Layer
64
Pattern Photoresist for Metal2 Interconnects:
Adjacent metal layers are patterned perpendicular to each other to minimize inductive coupling between layers (not shown in cross-sectional diagram).
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG W Contact Plug
Metal1
IMD1 W Via Plug
Metal2
Photoresist
Basic CMOS Process Flow - 2nd through Nth interconnect Layer
65
Etch Metal2: An RIE etch utilizing chlorine chemistry. Multiple etch steps are required due to the multiple different metal layers.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG W Contact Plug
Metal1
IMD1 W Via Plug
Metal2
Photoresist
Basic CMOS Process Flow - 2nd through Nth interconnect Layer
66
Strip Photoresist: 2nd interconnect layer is completed.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG W Contact Plug
Metal1
IMD1 W Via Plug
Metal2
Basic CMOS Process Flow - 2nd through Nth interconnect Layer
67
Basic CMOS Process Flow - PassivationDeposit Passivation Layer: There are many types of passivation (silicon nitride, silicon oxynitride, polyimide, and others). Its purpose is to protect the completed circuit from scratches, contamination, and moisture.
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG W Contact Plug
Metal1
IMD1 W Via Plug
Metal2
Passivation
68
Silicon Substrate P+
Silicon Epi Layer P-P- WellN- Well
N+ Source N+ DrainP+ Source P+ Drain
BPSG W Contact Plug
Metal1
IMD1 W Via Plug
Metal2
Passivation Bond Pad
Poly Gate
Gate Oxide
Silicide Spacer
Basic CMOS Process Flow - PassivationPattern Passivation Layer: Polyimide passivation is photo-definable. Other passivation layers require a patterned photoresist layer followed by an etch step. Bond pad openings allow electrical access to the chip.
69
Basic CMOS Process Flow
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