Film Deposition in VLSI
description
Transcript of Film Deposition in VLSI
FILM DEPOSITIONFILM DEPOSITION
Epitaxial growth
Growth of single crystal semiconductor Growth of single crystal semiconductor layer over a single crystal semiconductor layer over a single crystal semiconductor substrate.substrate.
Two types:Two types:Homoepitaxy.Homoepitaxy.Heteroepitaxy.Heteroepitaxy.
Substrate wafer acts as the seed.Substrate wafer acts as the seed. Common techniques:Common techniques:
CVDCVD MBEMBE
CVDCVD
Chemical Vapour DepositionChemical Vapour Deposition Method: chemical reaction between Method: chemical reaction between
gaseous compounds.gaseous compounds. In cases gas sources are not available, a
carrier gas such as H2 or N2 is bubbled through the liquid that carries vapors to chamber
Also known as vapour-phase epitaxy.Also known as vapour-phase epitaxy. Two variations:Two variations:
APCVDAPCVD LPCVD.LPCVD.
Example of CVD used in fabrication
Dielectrics: HfO2, SiO2, TiO2Gate electrode: polysiliconMetal interconnects: CopperDiffusion Barriers: TiN, TaNContact plugs: Tungsten (W)Silicides
Steps involved in CVDSteps involved in CVD
Transportation of reactants to substrate.Transportation of reactants to substrate. Reactor adsorptionReactor adsorption Chemical reaction followed by epitaxial growth.Chemical reaction followed by epitaxial growth. Desorption of gaseous products.Desorption of gaseous products. Transportation of reaction products from reaction Transportation of reaction products from reaction
chamber.chamber.
Analyzing CVDAnalyzing CVD Although CVD process is quite
complicated, we can analyze by just considering two important steps: Diffusion of reactants across
boundary layer (Flux J1) Reaction at surface (Flux J2)
Similar to Deal Grove (…recall oxidation!) we can analyze the process at equilibrium J1 = HG(CG – CS) where HG is the
mass transfer coefficient J2 = Ks CS where Ks is the surface
reaction rate
In steady state, J1 = J2 If kS << hG , then we have the surface
reaction controlled case If hG << kS, then we have the mass transfer,
or gas phase diffusion, controlled case
Silicon CVDSilicon CVD
Main sources:Main sources:Silicon tetrachlorideSilicon tetrachlorideDichlorosilaneDichlorosilaneTrichlorosilaneTrichlorosilaneSilaneSilane
Commonly uses SiClCommonly uses SiCl44high temp. process.high temp. process. Others used because of lower temperature.Others used because of lower temperature.
SiClSiCl4 4 + 2H+ 2H22 Si (solid) + 4HCl (gas) Si (solid) + 4HCl (gas)Accompanying reaction:Accompanying reaction:
SiClSiCl4 4 + Si (solid) + Si (solid) 2SiCl2SiCl2 2 (gas)(gas)
Gallium Arsenide CVDGallium Arsenide CVD
Similar to Si CVD process.Similar to Si CVD process.Ga and As dissociates at high Ga and As dissociates at high
temperature.temperature.Use AsUse As44 and GaCl and GaCl33 for both for both
components.components.
Metal Organic CVDMetal Organic CVD
For elements:For elements: That do not form stable hydrides and halides.That do not form stable hydrides and halides. That form stable metal-organic compounds.That form stable metal-organic compounds.
Extensively for heteroepitaxial growth.Extensively for heteroepitaxial growth. Major problems with MOCVD has been
carbon contamination and particulates which are detrimental to electrical characteristics (especially for hot-wall reactors); the hazards of the reactor gases is also significant
MBEMBE Evaporation of Si (or any other
semiconductor) and desired dopants under very high vacuum (10-8 Torr) and low Temp (4000 - 8000C) . Predominantly used for III-V
semiconductors Atoms or molecules are directed to
heated substrate in ultra high vacuum (UHV)
By utilizing very low growth rates (≈ 1μm/hour) can tailor doping profiles and composition on a monolayer scale.
AdvantagesLow deposition tempPrecise control of layer thickness and doping
profile (excellent uniformity)Versatile (used for fabricating heterostructures,
quantum wells, etc) In-situ cleaning and characterization
High temp. baking to decompose native oxygen.Low energy ion beam of inert gas to sputter impurity.
Disadvantage:Expensive (UHV), very slow deposition
Lattice matched Lattice matched epitaxy: epitaxy: homoepitaxy.homoepitaxy.
Two cases of Two cases of heteroepitaxy:heteroepitaxy: Lattice matched.Lattice matched. Strained-layer.Strained-layer.
Defects in epitaxial layersDefects in epitaxial layers
Defects from substratesDefects from substratesDefects from interface.Defects from interface.Precipitates or dislocation loops.Precipitates or dislocation loops.Misoriented areas of an epitaxial film Misoriented areas of an epitaxial film
(low angle grain boundary)(low angle grain boundary)Edge dislocationEdge dislocation
In heteroepitaxy of two lattice-mismatched In heteroepitaxy of two lattice-mismatched semiconductor.semiconductor.
Step CoverageStep Coverage
Relates surface topography of Relates surface topography of deposited film to various steps on deposited film to various steps on substrate.substrate.Conformal step coverage (ideal)Conformal step coverage (ideal)Non-conformal step coverage.Non-conformal step coverage.
Dielectric DepositionDielectric Deposition
APCVD, LPCVD, PECVDAPCVD, LPCVD, PECVDPECVD: plasma enhanced reaction.PECVD: plasma enhanced reaction.Energetic ion bombardment.Energetic ion bombardment.High density plasma helps to High density plasma helps to
improve electrical and mechanical improve electrical and mechanical properties.properties.
SiOSiO22
Quality not upto that grown by thermal Quality not upto that grown by thermal oxidation.oxidation.
Insulator for multilevel metalization, Insulator for multilevel metalization, masking ion implantation and diffusion.masking ion implantation and diffusion.
Low temperature process: film is formed Low temperature process: film is formed by reacting silane, dopants and oxygen.by reacting silane, dopants and oxygen. Suitable for deposition over Al.Suitable for deposition over Al.
Intermediate temperature process: Intermediate temperature process: decomposition of TEOS.decomposition of TEOS.
At higher temperatures, deposited oxide At higher temperatures, deposited oxide film will be structurally similar to that film will be structurally similar to that grown by thermal oxidation.grown by thermal oxidation.
SiSi33NN44
Simple thermal nitridation: slow growth Simple thermal nitridation: slow growth rate, high growth temperature.rate, high growth temperature.
Two methods for deposition:Two methods for deposition:Intermediate temperature LPCVDIntermediate temperature LPCVD
High density stoichiometric film.High density stoichiometric film.Application: device passivation, mask for Application: device passivation, mask for
selective oxidation of Si.selective oxidation of Si.Low temperature plasma assisted CVD.Low temperature plasma assisted CVD.
Lower density non-stoichiometric film.Lower density non-stoichiometric film.Application: final passivation layer.Application: final passivation layer.
Metallization - PVDMetallization - PVD
Ti, Al, Cu, TiN, TaNTi, Al, Cu, TiN, TaNMethods:Methods:
EvaporationEvaporationE-beam evaporationE-beam evaporationPlasma spray deposition Plasma spray deposition Sputtering.Sputtering.
Evaporation:Evaporation:Source heated in an evacuated chamber.Source heated in an evacuated chamber.
PVD - E-beam evaporationPVD - E-beam evaporation Target material is Target material is
bombarded with an electron bombarded with an electron beam given off by a charged beam given off by a charged tungsten filament under tungsten filament under high vacuum. high vacuum.
The electron beam causes The electron beam causes atoms from the target to atoms from the target to transform into the gaseous transform into the gaseous phase. phase.
They precipitate into solid They precipitate into solid form, coating everything in form, coating everything in the vacuum chamber (within the vacuum chamber (within line of sight) with a thin line of sight) with a thin layer of the anode material.layer of the anode material.
PVD - Ion beam sputteringPVD - Ion beam sputtering Ion current and energy adjusted.Ion current and energy adjusted.Other sputtering techniques:Other sputtering techniques:
Magnetron sputteringMagnetron sputteringLong-throw sputteringLong-throw sputteringReactive sputteringReactive sputtering
Metallization - CVDMetallization - CVD
Conformal coating.Conformal coating.High throughput.High throughput.LPCVD: conformal step coverage LPCVD: conformal step coverage
over wide range with lower electrical over wide range with lower electrical resistivity.resistivity.
Application: refractory metal Application: refractory metal deposition.deposition.
CVD TungstenCVD Tungsten
W: as contact plug and as first-level metal.W: as contact plug and as first-level metal. Source gas: tungsten hexafluoride (WFSource gas: tungsten hexafluoride (WF66))
Can be reduced by Si, HCan be reduced by Si, H22 or SiH or SiH44
WFWF66 + 3H + 3H22 W + 6HF W + 6HF ---- rapid process, ---- rapid process, conformal conformal coverage coverage
2WF2WF66 + 3Si + 3Si 2W + 3SiF 2W + 3SiF44
2WF2WF66 + 3SiH + 3SiH44 2W + 3SiF 2W + 3SiF44 + 6H + 6H22 ---- high ---- high deposition deposition
rate, high densityrate, high density
W CVDW CVD SiH SiH44 reduction followed by H reduction followed by H22 reductionreduction
CVD TiNCVD TiN
Diffusion barrier.Diffusion barrier.Can be deposited by sputtering and Can be deposited by sputtering and
CVD.CVD.CVD provides better step coverageCVD provides better step coverageSource : TiClSource : TiCl44
6TiCl6TiCl44 + 8NH + 8NH33 6TiN + 24HCl + N 6TiN + 24HCl + N22
2TiCl2TiCl44 + N + N2 2 + 4H+ 4H22 2TiN + 8HCl 2TiN + 8HCl
2TiCl2TiCl4 4 + 2NH+ 2NH33 + H + H22 2TiN + 8HCl 2TiN + 8HCl
TiN-W usage
Aluminum MetallizationAluminum Metallization
Aluminum was most popular choice till late 90’sHas low resistivity (2.7μohm-cm)Good adhesion to SiO2Simple deposition (PVD usually)Dry or Wet etch possible
Aluminum MetallizationAluminum Metallization
Can be deposited by PVD or CVD.Can be deposited by PVD or CVD.Problems associated: Junction Problems associated: Junction
Spiking, Electro-migration, Spiking, Electro-migration, Low melting point..
Spiking due to eutectic Spiking due to eutectic characteristicscharacteristics
Spikes can short junctions or cause Spikes can short junctions or cause excess leakageexcess leakage
Electro-migrationElectro-migration
Transport of material caused by the gradual movement of the ions in a conductor due to the momentum transfer between conducting electrons and diffusing metal atoms
leads to the eventual loss of one or more connections and intermittent failure
Copper
Advantages with Copper (Cu)Lower resistivity than Al (1.7) which leads to
reduction in delaysHigher melting point (~1080C) than AlHigher electro migration resistance than
Aluminum Disadvantages / Challenges
Highly reactive or corrosiveDifficult to etchDeposition challengesPoor adhesion to dielectricsHigh diffusivity in Si
Solutions to problems with Cu.
Fast diffusion of Cu into Si and SiO2 Poor oxidation/corrosion resistance Poor adhesion to SiO2
Diffusion Barrier / Adhesion Promoter
Difficulty of applying conventional etching technique
Use CMP Damascene process
Damascene Process
Pattern dielectric Deposit Cu in the
trenches CMP to remove
excess Cu.
Dual Damascene
In this process two layers of inter-metal dielectric are deposited sequentially and after patterning and etching through two layers, Cu is deposited and this is followed by CMP
CMP Global planarization. Surface moved against pad containing
slurry. Slurry: thick suspension of solids in liquidParticles in slurry mechanically
abrade the wafer surface and remove materials
Loosened material are either dissolved or swept away.