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CMOS Processing. VLSI Digital Systems Design. Si Purification. Chemical purification of Si Zone refined Induction furnace Si ingot melted in localized zone Molten zone moved from one end to the other Impurities more soluble in melt than in solid Impurities swept to one end of ingot
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CMOS Processing VLSI Digital Systems Design cmpe222_03process_ppt.ppt
Si Purification • Chemical purification of Si • Zone refined • Induction furnace • Si ingot melted in localized zone • Molten zone moved from one end to the other • Impurities more soluble in melt than in solid • Impurities swept to one end of ingot • Pure Si = intrinsic Si (impurities < 1:109) cmpe222_03process_ppt.ppt
Czochralski Technique forSingle-Crystal Ingot Growth, Melt • Remelt pure Si • Si melting point = 1412 C • Quartz crucible with graphite liner • RF induction heats graphite • Dip small Si seed crystal into melt • Seed determines crystal orientation cmpe222_03process_ppt.ppt
Czochralski Technique forSingle-Crystal Ingot Growth, Freeze • Withdraw seed slowly while rotating • Withdrawal and rotational rates determine ingot diameter • 30-180 mm/hour • Largest current wafers = 300 mm • Si crystal structure = diamond cmpe222_03process_ppt.ppt
Single-Crystal Ingot to Wafer • Diamond saw cuts grown crystal into slices = wafers • 0.25-1.00 mm thick • Polish one side of wafer to mirror finish cmpe222_03process_ppt.ppt
Oxidation Converts Si to SiO2 • Wet oxidation • Oxidizing atmosphere contains water vapor • 900-1000 C • Rapid • Dry oxidation • Oxidizing atmosphere pure oxygen • 1200 C • Volume of SiO2 = 2 x volume of Si • SiO2 layer grows above Si surface approximately as far as it extends below Si surface cmpe222_03process_ppt.ppt
Dopants • Si is semiconductor:Rconductor < RintrinsicSi < Rinsulator • Dopants = impurity atoms • Can vary conductivity by orders of magnitude • Dopant atom displaces 14Si atom in crystal • Each 14Si atom shares 4 electronswith its 4 neighbors in the crystal lattice,to form chemical bond • Group (column) IV-A of Periodic Table cmpe222_03process_ppt.ppt
Donor Atoms Provide Electrons • Group V-A of Periodic Table • Phosphorus, 15P, and Arsenic, 33As • 5 electrons in outer shell, 1 more than needed • Excess electron not held in bond is free to drift • If concentration of donors > acceptors,n-type Si cmpe222_03process_ppt.ppt
Acceptor Atoms Remove Electrons from Nearby Atoms • Group III-A of Periodic Table • Boron, 5B • 3 electrons in outer shell, 1 less than needed • Incomplete bond,accepting electron from nearby atom • Movement of electron is effective flow of positive current in opposite direction • If concentration of acceptors > donors,p-type Si cmpe222_03process_ppt.ppt
Epitaxy • Greek for “arranged upon” or “upon-ordered” • Grow single-crystal layeron single-crystal substrate • Homoepitaxy • Layer and substrate are same material • Heteroepitaxy • Layer and substrate differ • Elevate temperature of Si wafer surface • Subject surface to source of dopant cmpe222_03process_ppt.ppt
Deposition and Ion Implantation • Deposition • Evaporate dopant onto Si wafer surface • Thermal cycle • Drives dopant from Si wafer surface into the bulk • Ion Implantation • Energize dopant atoms • When they hit Si wafer surface,they travel below the surface cmpe222_03process_ppt.ppt
Diffusion • At temperature > 800 C • Dopant diffuses from area of high concentration to area of low • After applying dopant, keep temperature as low as possible in subsequent process steps cmpe222_03process_ppt.ppt
Common Dopant Mask Materials • Photoresist • Polysilicon (gate conductor) • SiO2 = Silicon dioxide (gate insulator) • SiN = Silicon nitride cmpe222_03process_ppt.ppt
Selective Diffusion Process • Apply dopant mask materialto Si wafer surface • Dopant mask pattern includes windows • Apply dopant source • Remove dopant mask material cmpe222_03process_ppt.ppt
Positive Resist Example • Apply SiO2 • Apply photoresist • PR = acid resistant coating • Pass UV light through reticle • Polymerizes PR • Remove polymerized areas with organic solvent • Developer solution • Etch exposed SiO2 areas cmpe222_03process_ppt.ppt
Lithography Pattern Storage, Technique 1 • Mask • Two methods for making • Electron beam exposure • Laser beam scanning • Parallel processing cmpe222_03process_ppt.ppt
Lithography Pattern Storage, Technique 2 • Direct Write • Two writing schemes • Raster scan • Vector scan • Pro • No mask expense • No mask delay • Able to change pattern from die to die • Con • Slow • Expensive cmpe222_03process_ppt.ppt
Lithography Pattern Transmission • Four types of radiation to convey pattern to resist • Light • Visible • Ultraviolet • Ion • X-ray (does not apply to direct write) • Electron cmpe222_03process_ppt.ppt
Lithographic Printing • Contact printing • Proximity printing • Projection printing • Refraction projection printing • Reflection projection printing • Catadioptric projection printing cmpe222_03process_ppt.ppt
Contact and Proximity Printing • Contact printing • 0.05 atm < pressure < 0.30 atm • Proximity printing • 20 μm < mask-wafer separation < 50 μm • Pro • Low cost • Mask lasts longer because no contact • Con • Inferior resolution cmpe222_03process_ppt.ppt
Projection Printing • Projection printing • Higher resolution than proximity printing • Numerical Aperture • It was once believed that a high NAis always better. • If NA too low, can't achieve resolution • If NA too high, can't achieve depth of field • DOF = lambda/(2 NA2) cmpe222_03process_ppt.ppt
Refraction Projection Printing • High resolution • To transmit deep UV, optical components are • Fused silica • Crystalline fluorides • Lenses are fused silica • Chromatic • Source bandwidth must be narrow • KrF laser cmpe222_03process_ppt.ppt
Reflection and Catadioptric Projection Printing • Reflection projection printing • Polychromatic, larger spectral bandwidth • Catadioptric projection printing • Combines reflecting and refracting components • Larger spectral bandwidth • More than one optical axis • Aligning optical elements can be very difficult cmpe222_03process_ppt.ppt
Minimum Channel Lengthand Gate Insulator ThicknessImprove Performance • Ids = Beta(Vgs – Vt)2 / 2 • Beta = MOS transistor gain factor = ( (mu)(epsilon) / tox )( W / L ) • mu = channel carrier mobility • epsilon = gate insulator permittivity (SiO2) • tox = gate insulator thickness • W / L = channel dimensions cmpe222_03process_ppt.ppt
Silicon Gate Process, Steps 1 & 2 • Initial patterning SiO2 layer • Called field oxide • Thick layer • Isolates individual transistors • Thin SiO2 layer • Called gate oxide • Also called thinox • 10 nm < thin oxide < 30 nm cmpe222_03process_ppt.ppt
Silicon Gate Process, Step 3 • Polysilicon layer • Polycrystalline = not single crystal • Formed when Si deposited • Has high R when undoped • Used as high-R resistor in static memory • Used as • Short interconnect • Gate electrode • Most important:allows precise definition of source and drain electrodes • Deposited undoped on gate insulator • Then doped at same time as source and drain regions cmpe222_03process_ppt.ppt
Silicon Gate Process, Steps 4 & 5 • Exposed thin oxide, not covered by poly,etched away • Wafer exposed to dopant sourceby deposition or ion-implantation • Forms n-type region in p-type substrateor vice versa • Source and drain created in shadow of gate • Si gate process called self-aligned process • Polysilicon doped, reducing its R cmpe222_03process_ppt.ppt
Silicon Gate Process, Final Steps • SiO2 layer • Contact holes etched • Metal (Al, Cu) evaporated • Interconnect etched • Repeat for further interconnect layers cmpe222_03process_ppt.ppt
Parasitic MOS transistors • Formed from • Diffusion regions of unrelated transistors • Act as parasitic source and drain • Thick (tfox) field oxide between transistorsoverrun by metal or poly interconnect • Act as parasitic gate insulator and • parasitic gate electrode • Raise threshold voltage of parasitic transistor • Make tfox thick enough • Add “channel-stop” diffusion between transistors cmpe222_03process_ppt.ppt
Four Main CMOS Processes • n-well process • p-well process • Twin-tub process • Silicon on insulator cmpe222_03process_ppt.ppt
n-well Process, n-Well Mask A • Mask A defines n-well • Also called n-tub • Ion implantation produces shallower wells than deposition • Deeper diffusion also spreads further laterally • Shallower diffusion better for more closely-spaced structures cmpe222_03process_ppt.ppt
n-well Process, Active Mask B, Page 1 • Mask B defines thin oxide • Called active mask, since includes • Area of gate electrode • Area of source and drain • Also called thinox • thin-oxide • island • mesa cmpe222_03process_ppt.ppt
n-well Process, Active Mask B, Page 2 • Thin layer of SiO2 grown • Covered with SiN = Silicon Nitride • Relative permittivity of SiO2 = 3.9 • Relative permittivity of Si3N4 = 7.5 • Relative permittivity of comb. = 6.0 • Used as mask for steps forchannel-stop mask C andfield oxide step D cmpe222_03process_ppt.ppt
n-well Process, Channel-Stop Mask C • Channel-stop implant • Raises threshold voltage of parasitic transistors • Uses p-well mask= complement of n-well Mask A • Where no nMOS, dope p-substrate to be p+ cmpe222_03process_ppt.ppt
n-well Process, Field Oxide Step D • Thick layer of SiO2 grown • Grows where no SiN • Grows where no mask B = no active mask • Called LOCOS = LOCal Oxidation of Silicon cmpe222_03process_ppt.ppt
n-well Process, Bird‘s Beak • Just as dopant diffuses laterally as well as vertically: • Field oxide also grows laterally,underneath SiN • Tapering shape called bird’s beak • Causes active area to be smaller • Reduces W • Some techniques limit this effect • SWAMI = SideWAll Masked Isolation cmpe222_03process_ppt.ppt
n-well Process, Planarity • Field oxide higher than gate oxide • Conductor thins or breaks • Problem called step coverage • To fix,pre-etch field oxide areasby 0.5 field oxide depth cmpe222_03process_ppt.ppt
n-well Process, Vt Adjust,After Field Oxide Step D • Threshold voltage adjust • Optional • Uses n-well mask A • 0.5 v < Vtn < 0.7 v • -2.0 v < Vtp < -1.5 v • Add a negatively charged layer at Si-SiO2 • Lowers channel • Called “buried channel” device cmpe222_03process_ppt.ppt
n-well Process, Poly Mask E • Mask E defines polysilicon • Poly gate electrodeacts as mask for source & drain regions • Called self-aligned cmpe222_03process_ppt.ppt
n-well Process, n+ Mask F • n+ mask defines active areas to be doped n+ • If in p-substrate,n+ becomes nMOS transistor • If in n-well,n+ becomes ohmic contact to n-well • Also called select mask cmpe222_03process_ppt.ppt
n-well Process, LDD Step G • LDD = Lightly Doped Drain • Shallow n-LDD implant • Grow spacer oxide over poly gate • Second, heavier n+ implant • Spaced from edge of poly gate • Remove spacer oxide from poly gate • More resistant to hot-electron effects cmpe222_03process_ppt.ppt
n-well Process, p+ Mask H • p+ diffusion • Uses complement of n+ mask • p+ mask defines active areas to be doped p+ • If in n-well,p+ becomes pMOS transistor • If in p-substrate,p+ becomes ohmic contact to p-substrate cmpe222_03process_ppt.ppt
n-well Process, SiO2,After p+ Mask H • Entire chip covered with SiO2 • No need for LDD for pMOS • pMOS less susceptible to to hot-electron effectsthan nMOS • LDD = Lightly Doped Drain cmpe222_03process_ppt.ppt
n-well Process, Contact Mask I • Defines contact cuts in SiO2 layer • Allows metal to contact • Diffusion regions • Poly gates cmpe222_03process_ppt.ppt
n-well Process, Metal Mask J • Wire it up! • n-well Process, Passivation Step • Protects chip from contaminants • Which can modify circuit behavior • Etch openings to bond pads for IOs cmpe222_03process_ppt.ppt
p-Well Process • Transistor in native substratehas better characteristics • p-well process has better pMOS thann-well process • nMOS have better gain (beta) than pMOS cmpe222_03process_ppt.ppt
Twin-Tub Process • Separately optimized wells • Balanced performance nMOS & pMOS • Start with epitaxial layer • Protects against latchup • Form n-well and p-well tubs cmpe222_03process_ppt.ppt
Silicon-on-Insulator Process • Uses n-islands and p-islands of siliconon an insulator • Sapphire • SiO2 • No n-wells, no p-wells cmpe222_03process_ppt.ppt
SOI Process Advantages • No n-wells, no p-wells • Transistors can be closer together • Higher density • Lower parasitic substrate capacitance • Faster operation • No latchup • No body effect • Enhanced radiation tolerance cmpe222_03process_ppt.ppt