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1Professor N Cheung, U.C. Berkeley
Lecture 21EE143 F05
Basic Structure of CMOS Inverter
2Professor N Cheung, U.C. Berkeley
Lecture 21EE143 F05
The MOSISCMOS Process
MOSIS is a foundry service that providesstandard CMOS fabrication
P-well CMOS
3Professor N Cheung, U.C. Berkeley
Lecture 21EE143 F05
Pattern mask openingFor p-well implant
Shallow implantation of boron
Diffusion drive-inTo form p-well in oxidizing ambient
Remove masking oxide
4Professor N Cheung, U.C. Berkeley
Lecture 21EE143 F05
Pad oxide growth and CVD Si3N4.Pattern field oxide regions
Blanket implant of Boron for p channel stop inside p-well
Protect p-well regions with photoresist.Implant Ph to form n channel stop outside p-well regions
LOCOS Oxidation
Thermal oxidation of gate SiO2
5Professor N Cheung, U.C. Berkeley
Lecture 21EE143 F05
Pattern poly-Si gates
Protect ALL n-channel transistors with photoresist.
Boron implantation to form source/drain of p-channel transistors and contacts to p-well
CVD poly-Si !!
6Professor N Cheung, U.C. Berkeley
Lecture 21EE143 F05
Protect ALL p-channeltransistors with photoresist.
CVD SiO2(Low-temperature oxide)
Pattern and etch contact openings to source/drain, well contact, and substrate contact.
Arsenic implantation to form source/drain of n-channel transistors and contacts to n-substrate
7Professor N Cheung, U.C. Berkeley
Lecture 21EE143 F05
Metal 1 deposition
Pattern and etch Metal 1 interconnects
CVD SiO2
8Professor N Cheung, U.C. Berkeley
Lecture 21EE143 F05
Pattern and etch contact openings to Metal 1.
Metal 2 deposition.
Pattern, and etch Metal 2 interconnects.
9Professor N Cheung, U.C. Berkeley
Lecture 21EE143 F05
3D view of a CMOS inverter after contact etch.
10Professor N Cheung, U.C. Berkeley
Lecture 21EE143 F05
Well Engineering
P-tub
N-tub
Twin Tub
11Professor N Cheung, U.C. Berkeley
Lecture 21EE143 F05
Twin Well CMOS Process Flow
12Professor N Cheung, U.C. Berkeley
Lecture 21EE143 F05
C(x)
x
Conventional well (depth and profilecontrolled by diffusion drive-in)
Retrograde well (depth and profilecontrolled by implantation energy and dose)
Retrograde Well
- formed by high energy (>200keV) implantation
13Professor N Cheung, U.C. Berkeley
Lecture 21EE143 F05
1) Very low thermal budget for well formation(no need for diffusion drive-in)
2) Retrograde Well is formed AFTER field oxidation⇒ small lateral diffusion and localized high conc under FOX
Conventional vs Retrograde Well
14Professor N Cheung, U.C. Berkeley
Lecture 21EE143 F05
Example: Formation of Channel Stop and Retrograde Wellin a single step
Channel stop Retrograde well
15Professor N Cheung, U.C. Berkeley
Lecture 21EE143 F05
Multiple Implants for Well Engineering
16Professor N Cheung, U.C. Berkeley
Lecture 21EE143 F05
Basic Silicon-on-Insulator (SOI) CMOS Process Flow
17Professor N Cheung, U.C. Berkeley
Lecture 21EE143 F05
SOI Process Flow (continued)
18Professor N Cheung, U.C. Berkeley
Lecture 21EE143 F05
Smallest featureprintable bylithography
SiO2
CVD oxide CVD oxide
n+ n+ n+ n+
poly-Si gate
Thermal gate oxide
Oxide spacer
AngledImplantn+ pocket
NormalS/D implant
TiSi2
Self-Aligned Channel V-gate by Optical Lithography(SALVO) Process
* Sub-50nm channels
19Professor N Cheung, U.C. Berkeley
Lecture 21EE143 F05
or
SALVO Process Flow
Chang et al, IEDM 2000
See HW#9 Problem