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Transcript
Fabrication of MOSFETs
Introduction and Fabrication
Procedure
Amit Degada
Asst. Professor
[email protected]
Introduction
• Integrated circuits: many transistors on one chip.
• Very Large Scale Integration (VLSI): millions of logic
gates + many Mbits of memroy
• Complementary Metal Oxide Semiconductor
– Fast, cheap, low power transistors
• Today: How to build your own simple CMOS chip
– CMOS transistors
– Building logic gates from transistors
– Transistor layout
• Rest of the course: How to build a good CMOS chip
A Brief History
• 1958: First integrated circuit
– Built by Jack Kilby at Texas Instruments with 2
transistors
• 2003
– Intel Pentium 4 mprocessor (55 million transistors)
– 512 Mbit DRAM (> 0.5 billion transistors)
• 53% compound annual growth rate over 45 years
– No other technology has grown so fast so long
• Driven by miniaturization of transistors
– Smaller is cheaper, faster, lower in power!
– Revolutionary effects on society
Annual Sales
• 1018 transistors manufactured in 2003
– 100 million for every human on the planet
– $100B business in 2004
Global Semiconductor Billings
(Billions of US$)
200
150
100
50
0
1982
1984
1986
1988
1990
1992
Year
1994
1996
1998
2000
2002
Invention of the Transistor
• Vacuum tubes ruled in first half of 20th century
Large, expensive, power-hungry, unreliable
• 1947: first point contact transistor
– John Bardeen and Walter Brattain at Bell Labs
Transistor Types
• Bipolar transistors
– npn or pnp silicon structure
– Small current into very thin base layer controls large
currents between emitter and collector
– Base currents limit integration density (power
dissipation issue)
• Metal Oxide Semiconductor Field Effect
Transistors
– nMOS and pMOS MOSFETS
– Voltage applied to insulated gate controls current
between source and drain
– Low power allows very high integration (ideally zero
static power)
MOS Integrated Circuits
• 1970’s processes usually had only nMOS transistors
– Inexpensive, but consume power while idle
Intel 1101 256-bit SRAM
Intel 4004 4-bit mProc
• 1980s-present: CMOS processes for low idle power
Moore’s Law
• 1965: Gordon Moore plotted transistor on each chip
– Fit straight line on semilog scale
– Transistor counts have doubled every 18 months
1,000,000,000
Integration Levels
100,000,000
10,000,000
Transistors
Intel486
1,000,000
Pentium 4
Pentium III
Pentium II
Pentium Pro
Pentium
SSI:
10 gates
MSI:
1000 gates
LSI:
10,000 gates
VLSI:
> 10k gates
Intel386
80286
100,000
8086
10,000
8080
8008
4004
1,000
1970
1975
1980
1985
Year
1990
1995
2000
Corollaries
• Many other factors grow exponentially
– Ex: clock frequency, processor performance
10,000
4004
1,000
8008
Clock Speed (MHz)
8080
8086
100
80286
Intel386
Intel486
10
Pentium
Pentium Pro/II/III
Pentium 4
1
1970
1975
1980
1985
1990
Year
1995
2000
2005
Silicon Lattice
• Transistors are built on a silicon substrate
• Silicon is a Group IV material
• Forms crystal lattice with bonds to four neighbors
Si
Si
Si
Si
Si
Si
Si
Si
Si
Dopants
•
•
•
•
•
Silicon is a semiconductor
Pure silicon has no free carriers and conducts poorly
Adding dopants increases the conductivity
Group V (Arsenic): extra electron (n-type)
Group III (Boron): missing electron, called hole (p-type)
Si
Si
Si
Si
Si
Si
As
Si
Si
B
Si
Si
Si
Si
Si
-
+
+
-
Si
Si
Si
p-n Junctions
• A junction between p-type and n-type semiconductor forms a
diode.
• Current flows only in one direction
p-type
n-type
anode
cathode
nMOS Transistor
• Four terminals: gate, source, drain, body
• Gate – oxide – body stack looks like a capacitor
– Gate and body are conductors
– SiO2 (oxide) is a very good insulator
– Called metal – oxide – semiconductor (MOS) capacitor
Source
Gate
Drain
Polysilicon
SiO2
n+
n+
p
bulk Si
nMOS Operation
• Body is commonly tied to ground (0 V)
• When the gate is at a low voltage:
– P-type body is at low voltage
– Source-body and drain-body diodes are OFF
– No current flows, transistor is OFF
Source
Gate
Drain
Polysilicon
SiO2
0
n+
n+
S
p
bulk Si
D
nMOS Operation Cont.
• When the gate is at a high voltage:
– Positive charge on gate of MOS capacitor
– Negative charge attracted to body
– Inverts a channel under gate to n-type
– Now current can flow through n-type silicon from source
through channel to drain, transistor is ON
Source
Gate
Drain
Polysilicon
SiO2
1
n+
n+
S
p
D
bulk Si
0: Introduction
Slide 15
pMOS Transistor
• Similar, but doping and voltages reversed
– Body tied to high voltage (VDD)
– Gate low: transistor ON
– Gate high: transistor OFF
– Bubble indicates inverted behavior
Source
Gate
Drain
Polysilicon
SiO2
p+
p+
n
bulk Si
Power Supply Voltage
• GND = 0 V
• In 1980’s, VDD = 5V
• VDD has decreased in modern processes due to scaling
– High VDD would damage modern tiny transistors
– Lower VDD saves power (Dynamic power is propotional to
C.VDD2.f.a)
• VDD = 3.3, 2.5, 1.8, 1.5, 1.2, 1.0, …
Transistors as Switches
• We can view MOS transistors as electrically controlled
switches
• Voltage at gate controls path from source to drain
d
nMOS
pMOS
g=0
g=1
d
d
OFF
g
ON
s
s
s
d
d
d
g
OFF
ON
s
s
s
CMOS Inverter
A
VDD
Y
0
1
A
A
Y
Y
GND
CMOS Inverter
A
VDD
Y
0
1
OFF
0
A=1
Y=0
ON
A
Y
GND
CMOS Inverter
A
Y
0
1
1
0
VDD
ON
A=0
Y=1
OFF
A
Y
GND
CMOS NAND Gate
A
B
0
0
0
1
1
0
1
1
Y
Y
A
B
CMOS NAND Gate
A
B
Y
0
0
1
0
1
1
0
1
1
ON
ON
Y=1
A=0
B=0
OFF
OFF
CMOS NAND Gate
A
B
Y
0
0
1
0
1
1
1
0
1
1
OFF
ON
Y=1
A=0
B=1
0: Introduction
OFF
ON
Slide 24
CMOS NAND Gate
A
B
Y
0
0
1
0
1
1
1
0
1
1
1
ON
A=1
B=0
OFF
Y=1
ON
OFF
Introduction and Fabrication
Procedure
Objective of the Lecture
• Design of Logics in CMOS
• Why to Study Fabrication?
• Flow Diagram.
• Fabrication Process Flow:Basic Steps
CMOS NOR Gate
A
B
Y
0
0
1
0
1
0
1
0
0
1
1
0
A
B
Y
3-input NAND Gate
• Y pulls low if ALL inputs are 1
• Y pulls high if ANY input is 0
3-input NAND Gate
• Y pulls low if ALL inputs are 1
• Y pulls high if ANY input is 0
Y
A
B
C
Complementary CMOS
• Complementary CMOS logic gates
– nMOS pull-down network
– pMOS pull-up network
– a.k.a. static CMOS
Pull-up OFF
Pull-up ON
Pull-down OFF Z (float)
1
Pull-down ON
X (crowbar)
0
pMOS
pull-up
network
inputs
output
nMOS
pull-down
network
Series and Parallel
•
•
•
•
a
a
nMOS: 1 = ON
pMOS: 0 = ON
Series: both must be ON
Parallel: either can be ON
0
g1
g2
(a)
(b)
a
g1
g2
(c)
a
g1
g2
b
0
1
b
b
OFF
OFF
OFF
ON
a
a
a
a
0
1
1
1
0
1
b
b
b
b
ON
OFF
OFF
OFF
a
a
a
a
0
0
b
1
b
0
b
1
1
0
g2
a
b
a
g1
a
0
0
b
(d)
a
0
1
1
0
1
1
b
b
b
b
OFF
ON
ON
ON
a
a
a
a
0
0
0
1
1
0
1
1
b
b
b
b
ON
ON
ON
OFF
Conduction Complement
• Complementary CMOS gates always produce 0 or 1
• Ex: NAND gate
– Series nMOS: Y=0 when both inputs are 1
– Thus Y=1 when either input is 0
– Requires parallel pMOS
A
B
• Rule of Conduction Complements
– Pull-up network is complement of pull-down
– Parallel -> series, series -> parallel
Y
Compound Gates
• Compound gates can do any inverting function
• Ex:
Y  A B  C D (AND-AND-OR-INVERT, AOI22)
A
C
A
C
B
D
B
D
(a)
A
(b)
B C
D
(c)
D
A
B
(d)
C
D
A
B
A
B
C
D
Y
A
C
B
D
(e)
C
(f)
Y
Example: O3AI
•
Y  A B C D
Example: O3AI
Y  A B C D
A
B
C
D
Y
D
A
B
C
Objective of the Lecture
• Design of Logics in CMOS
• Why to Study Fabrication?
• Flow Diagram.
• Fabrication Process Flow:Basic Steps
Why to study Fabrication?
• Strong link between Fabrication Process , the circuit design
procedure and the performance of resulting chip
• The circuit designer must have clear understanding of the
roles of various MASKs used in the fabrication procedure and
How this MASKs define various feature of the devices on a
Chip
• To know to create effective design.
• To optimize the circuit with respect to various manufacturing
parameters.
Well
• Requires to build both pMOS and nMOS on single wafer.
• To accommodate both pMOS and nMOS devices, special
regions must be created in which the semiconductor type is
oppossite of the substrate type.
• Also Known as Tubs.
• Twin-tubs
Objective of the Lecture
• Design of Logics in CMOS
• Why to Study Fabrication?
• Flow Diagram.
• Fabrication Process Flow:Basic Steps
Flow Diagram
Create n-Well regions and
Channel Stops region
Grow Field Oxide and
Gate Oxide
Deposite and pattern
Polysilcon Layer
Implant sources, drain regions
and substrate contacts
Create contact Windows,
deposit and pattern metal layer
Objective of the Lecture
• Design of Logics in CMOS
• Why to Study Fabrication?
• Flow Diagram.
• Fabrication Process Flow:Basic Steps
Fabrication Procedure Flow: Basic Steps
• Masks: Each Processing steps in the fabrication procedure requires to
define certain area on the chip. This is known as Masks.
• Chips are specified with set of masks
• Minimum dimensions of masks determine transistor size (and hence
speed, cost, and power)
• Feature size f = distance between source and drain
– Set by minimum width of polysilicon
• Feature size improves 30% every 3 years or so
• Normalize for feature size when describing design rules
• The ICs are viewed as a set of pattern layers of doped Silicon,
Polysilicon, Metal and Insulating Silicon Dioxide.
• A layer mut be Patterned before the next layer of material is applied on
the chip.
Inverter Cross-section
• Typically use p-type substrate for nMOS transistors
• Requires n-well for body of pMOS transistors
A
GND
VDD
Y
SiO2
n+ diffusion
n+
n+
p+
p+
n well
p substrate
nMOS transistor
p+ diffusion
polysilicon
metal1
pMOS transistor
Inverter Cross-section with Well and Substrate taps
•
•
•
•
•
Typically use p-type substrate for nMOS transistors
Requires n-well for body of pMOS transistors
Substrate must be tied to GND and n-well to VDD
Metal to lightly-doped semiconductor forms poor connection
Use heavily doped well and substrate contacts / taps
A
GND
VDD
Y
p+
n+
n+
p+
p+
n well
p substrate
substrate tap
well tap
n+
Inverter Mask Set
• Transistors and wires are defined by masks
• Cross-section taken along dashed line
A
Y
GND
VDD
nMOS transistor
substrate tap
pMOS transistor
well tap
Detailed Mask Views
• Six masks
– n-well
– Polysilicon
– n+ diffusion
– p+ diffusion
– Contact
– Metal
n well
Polysilicon
n+ Diffusion
p+ Diffusion
Contact
Metal
Pattern Preparation
Chrome Pattern
Quartz Substrate
Pellicle
Wafer Preparation
Wafer Preparation
Fabrication Steps
• Start with blank wafer
• Build inverter from the bottom up
• First step will be to form the n-well
– Cover wafer with protective layer of SiO2 (oxide)
– Remove layer where n-well should be built
– Implant or diffuse n dopants into exposed wafer
– Strip off SiO2
p substrate
Oxidation
• Grow SiO2 on top of Si wafer
– 900 – 1200 C with H2O or O2 in oxidation furnace
SiO2
p substrate
Photolithography
Exposure Processes
Photoresist
• Used for lithography .
• Lithography is a process used to transfer a pattern to layer on the chip.
Similar to Printng Process
• Spin on photoresist (about 1 mm thickness)
– Photoresist is a light-sensitive organic polymer
– Possitive Photoresist: Softens where exposed to light
– Negative Photresist: Harden where exposed to light, Not used in
practise generally
Photoresist
SiO2
p substrate
Lithography
• Expose photoresist through n-well mask
• Strip off exposed photoresist
Photoresist
SiO2
p substrate
Etch
Cluster Tool
Configuration
Wafers
Etch
Chambers
Transfer
Chamber
Loadlock
Gas Inlet
RIE Chamber
Die-electric Etch
Plasma Etch
Wafer
Transfer
Chamber
RF Power
Exhaust
Etch
• Etch oxide with hydrofluoric acid (HF)
– Seeps through skin and eats bone; nasty stuff!!!
• Only attacks oxide where resist has been
exposed
Photoresist
SiO2
p substrate
Strip Photoresist
• Strip off remaining photoresist
– Use mixture of acids called piranah etch
• Necessary so resist doesn’t melt in next step
SiO2
p substrate
n-well
• n-well is formed with diffusion or ion implantation
• Diffusion
– Place wafer in furnace with arsenic gas
– Heat until As atoms diffuse into exposed Si
• Ion Implanatation
– Blast wafer with beam of As ions
– Ions blocked by SiO2, only enter exposed Si
SiO2
n well
Ion Implantation
Focus
phosphorus
(-) ions
Beam trap and
gate plate
Neutral beam and
beam path gated
photoresist mask
field oxide
n-w ell
p- epi
p-channel transistor
p+ substrate
Neutral beam trap
and beam gate
Y - axis
scanner
X - axis
scanner
Wafer in wafer
process chamber
Strip Oxide
• Strip off the remaining oxide using HF
• Back to bare wafer with n-well
• Subsequent steps involve similar series of steps
n well
p substrate
Polysilicon
• Deposit very thin layer of gate oxide
– < 20 Å (6-7 atomic layers)
• Chemical Vapor Deposition (CVD) of silicon layer
– Place wafer in furnace with Silane gas (SiH4)
– Forms many small crystals called polysilicon
– Heavily doped to be good conductor
Polysilicon
Thin gate oxide
n well
p substrate
Polysilicon Patterning
• Use same lithography process to pattern polysilicon
Polysilicon
Polysilicon
Thin gate oxide
n well
p substrate
Self-Aligned Process
• Use oxide and masking to expose where n+ dopants should be
diffused or implanted
• N-diffusion forms nMOS source, drain, and n-well contact
n well
p substrate
N-diffusion
• Pattern oxide and form n+ regions
• Self-aligned process where gate blocks diffusion
• Polysilicon is better than metal for self-aligned gates because
it doesn’t melt during later processing
n+ Diffusion
n well
p substrate
N-diffusion cont.
• Historically dopants were diffused
• Usually ion implantation today
• But regions are still called diffusion
n+
n+
n+
n well
p substrate
N-diffusion cont.
• Strip off oxide to complete patterning step
n+
n+
n+
n well
p substrate
P-Diffusion
• Similar set of steps form p+ diffusion regions for pMOS source
and drain and substrate contact
p+ Diffusion
p+
n+
n+
p+
p+
n well
p substrate
n+
Contacts
• Now we need to wire together the devices
• Cover chip with thick field oxide
• Etch oxide where contact cuts are needed
Contact
Thick field oxide
p+
n+
n+
p+
p+
n well
p substrate
n+
Metalization
• Sputter on aluminum over whole wafer
• Pattern to remove excess metal, leaving wires
Metal
Metal
Thick field oxide
p+
n+
n+
p+
p+
n well
p substrate
n+
Testing
Defective IC
Individual integrated circuits are
tested to distinguish good die
from bad ones.
Die Cut and Assembly
Good chips are attached
to a lead frame package.
Die Attach and Wire Bonding
lead frame
gold wire
bonding pad
connecting pin
Final Test
Chips are electrically
tested under varying
environmental conditions.
Device Isolation Techniques
• The MOS transistors need to be electrically isolated during fabrication.
• Isolation is necessary to prevent unwanted conduction paths between
devices and to avoid creation of inversion layer outside channel sepration
region and to reduce leackage currents
•Active area is created, which is surronded by a relatively thick oxide barrier
called the field oxide.
•Ethced field oxide isolation. ( Grow Silicon Oxide and Etched away u
Necessary).
Disadvantage: Thickness of the field oxide leads to large Oxide steps at
the boundry of Active and isolated regions.
This leads to the cracking of layer (Hence Chip Failure) when metal/ Poly is
deposited in next steps
Local Oxidation of Silicon (LOCOS)
•Based on the Principal of selectively Growing the oxide rahter than
etching.
•Selectice Growth is achieved by shielding the Active area with Silicon
Nitride (Si3N4)
•First Thin oxide is grown followed by deposition and patterning of
Silicon Nitride (Si3N4)
Local Oxidation of Silicon (LOCOS)
Exposed area form the isolation region and doped with P Kind of
impurities
P
Local Oxidation of Silicon (LOCOS)
Thick oxide is grown in next step where the area is not covered by
Si3N4.
Birds Beak Region.
Local Oxidation of Silicon (LOCOS)
Etching of Si3N4 and thin Oxide.
Most Popular Techniques.
Later Some techniques are developed to control Bird’s Beak Region.
Summary
•
•
•
•
•
MOS Transistors are stack of gate, oxide, silicon
Can be viewed as electrically controlled switches
Build logic gates out of switches
Draw masks to specify layout of transistors
Now you know everything necessary to start designing
schematics and layout for a simple chip!
References
1.
2.
3.
4.
5.
6.
7.
8.
CMOS Process Flow in Wafer Fab, Semiconductor Manufacturing Technology, DRAFT, Austin
Community College, January 2, 1997.
Semiconductor Processing with MKS Instruments, Inc.
Worthington, Eric. “New CMP architecture addresses key process issues,” Solid State
Technology, January 1996.
Leskonic, Sharon. “Overview of CMP Processing,” SEMATECH Presentation, 1996.
Gwozdz, Peter. “Semiconductor Processing Technology” SEMI, 1997.
CVD Tungsten, Novellus Sales Brochure, 7/96.
Fullman Company website. “Fullman Company - The Semiconductor Manufacturing
Process,” http://www.fullman.com/semiconductors/index.html, 1997.
Barrett, Craig R. “From Sand to Silicon: Manufacturing an Integrated Circuit,” Scientific
American Special Issue: The Solid State Century, January 22, 1998.
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