Post on 26-Dec-2015
CMOS Fabrication Details
• CMOS transistors are fabricated on silicon wafer
• Lithography process similar to printing press
• On each step, different materials are deposited or etched
• Easiest to understand by viewing both top and cross-section of wafer in a simplified manufacturing process
Inverter Cross-section
• Typically use p-type substrate for nMOS transistors
• Requires n-well for body of pMOS transistors
n+
p substrate
p+
n well
A
YGND VDD
n+ p+
SiO2
n+ diffusion
p+ diffusion
polysilicon
metal1
nMOS transistor pMOS transistor
• Substrate must be tied to GND and n-well to VDD
• Metal to lightly-doped semiconductor forms poor connection called Shottky Diode
• Use heavily doped well and substrate contacts / taps
n+
p substrate
p+
n well
A
YGND VDD
n+p+
substrate tap well tap
n+ p+
Well and Substrate Taps
Inverter Mask Set
• Transistors and wires are defined by masks
• Cross-section taken along dashed line
GND VDD
Y
A
substrate tap well tapnMOS transistor pMOS transistor
Detailed Mask Views
• Six masks– n-well– Polysilicon– n+ diffusion– p+ diffusion– Contact– Metal
Metal
Polysilicon
Contact
n+ Diffusion
p+ Diffusion
n well
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
p substrate
SiO2
Photoresist
• Spin on photoresist– Photoresist is a light-sensitive organic polymer– Softens where exposed to light
p substrate
SiO2
Photoresist
Lithography
• Expose photoresist through n-well mask
• Strip off exposed photoresist
p substrate
SiO2
Photoresist
Etch
• Etch oxide with hydrofluoric acid (HF)– Seeps through skin and eats bone; nasty stuff!!!
• Only attacks oxide where resist has been exposed
p substrate
SiO2
Photoresist
Strip Photoresist
• Strip off remaining photoresist– Use mixture of acids called piranah etch
• Necessary so resist doesn’t melt in next step
p substrate
SiO2
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
n well
SiO2
Strip Oxide
• Strip off the remaining oxide using HF
• Back to bare wafer with n-well
• Subsequent steps involve similar series of steps
p substraten well
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
Thin gate oxidePolysilicon
p substraten well
Polysilicon Patterning
• Use same lithography process to pattern polysilicon
p substrate
Thin gate oxidePolysilicon
n well
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
p substraten well
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
p substraten well
N-diffusion cont.
• Historically dopants were diffused
• Usually ion implantation today
• But regions are still called diffusion
n wellp substrate
n+n+ n+
N-diffusion cont.
• Strip off oxide to complete patterning step
n wellp substrate
n+n+ n+
P-Diffusion
• Similar set of steps form p+ diffusion regions for pMOS source and drain and substrate contact
p substraten well
n+n+ n+p+p+p+
Contacts
• Now we need to wire together the devices
• Cover chip with thick field oxide
• Etch oxide where contact cuts are needed
p substrate
Thick field oxide
n well
n+n+ n+p+p+p+
Contact
Metallization
• Sputter on aluminum over whole wafer
• Pattern to remove excess metal, leaving wires
p substrate
Metal
Thick field oxide
n well
n+n+ n+p+p+p+
Metal
Design Rules
Stick Diagrams
• VLSI design aims to translate circuit concepts onto silicon
• stick diagrams are a means of capturing topography and layer information - simple diagrams
• Stick diagrams convey layer information through colour codes (or monochrome encoding
• Used by CAD packages, including Microwind
Design Rules
• Allow translation of circuits (usually in stick diagram or symbolic form) into actual geometry in silicon
• Interface between circuit designer and fabrication engineer
• Compromise– designer - tighter, smaller– fabricator - controllable, reproducable
Lambda Based Design Rules
• Design rules based on single parameter, λ• Simple for the designer• Wide acceptance• Provide feature size independent way of setting
out mask• If design rules are obeyed, masks will produce
working circuits• Minimum feature size is defined as 2 λ• Used to preserve topological features on a chip• Prevents shorting, opens, contacts from slipping
out of area to be contacted
Design Rules - The Reality
• Manufacturing processes have inherent limitations in accuracy and repeatability
• Design rules specify geometry of masks that provide reasonable yield
• Design rules are determined by experience
Problems - Manufacturing
• Photoresist shrinking / tearing
• Variations in material deposition
• Variations in temperature
• Variations in oxide thickness
• Impurities
• Variations between lots
• Variations across the wafer
Problems - Manufacturing
• Variations in threshold voltage– oxide thickness– ion implantation– poly variations
• Diffusion - changes in doping (variation in R, C)• Poly, metal variations in height and width -> variation in
R, C• Shorts and opens• Via may not be cut all the way through• Undersize via has too much resistance• Oversize via may short
Meta Design Rules
• Basic reasons for design rules
• Rules that generate design rules
• Under worst case misalignment and maximum edge movement of any feature, no serious performance degradation should occur
Advantages of Generalised Design Rules
• Ease of learning because they are scalable, portable, durable
• Longlevity of designs that are simple, abstract and minimal clutter
• Increased designer efficiency
• Automatic translation to final layout
Basic Interconnects
• Wiring-Up of chip devices takes place through various conductors produced during processing
• Today, interconnects constitute the main source of delay in MOS circuits
• We will examine:– Sheet Resistance – Resistance / Unit Area– Area Capacitance– Delay Units– CMOS Inverter Delay– Rise and Fall Time Estimation
Sheet Resistance
• Resistance of a square slab of material
• RAB = ρL/A t
• => R = ρL/t*W
• Let L = W (square slab)
• => RAB = ρ/t = Rs ohm / square
B
A
tL
w
RAB = ZRshZ = L/W
Typical sheet resistance values for materials
are very well characterised
Layer Rs (Ohm / Sq
Aluminium 0.03
N Diffusion 10 – 50
Silicide 2 – 4
Polysilicon 15 - 100
N-transistor Channel 104
P-transistor Channel 2.5 x 104
Typical Sheet Resistances for 5µm Technology
N-type Minimum Feature Device
Polysilicon
N - diffusion
W
L
2λ
2λ
R = 1sq x Rs = Rs = 104 Ώ
Area Capacitance of Layers
• Conducting layers are separated from each other by insulators (typically SiO2)
• This may constitute a parallel plate capacitor, C = є0єox A / D (farads)
• D = thickness of oxide, A = area,
• єox = 4 F/µm2
• Area capacitance given in pF/µm2
Capacitance
• Standard unit for a technology node is the gate - channel capacitance of the minimum sized transistor (2λ x 2λ), given as Cg�
• This is a ‘technology specific’ value
Delay Unit
• For a feature size square gate, τ = Rs x Cg�
• i.e for 5µm technology, τ = 104 ohm/sq x 0.01pF = 0.1ns
• Because of effects of parasitics which we have not considered in our model, delay is typically of the order of 0.2 - 0.3 ns
• Note that τ is very similar to channel transit time τsd
Simplified Design Rules
Inverter Layout
• Transistor dimensions specified as Width / Length– Minimum size is 4 / 2sometimes called 1 unit– In f = 0.6 m process, this is 1.2 m wide, 0.6 m long