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Physical Vapor Deposition

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Physical Vapor Deposition PVD Physical methods produce the atoms that deposit on the substrate Evaporation Sputtering Sometimes called vacuum deposition because the ... – PowerPoint PPT presentation

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Title: Physical Vapor Deposition


1
Physical Vapor Deposition
2
PVD
  • Physical methods produce the atoms that deposit
    on the substrate
  • Evaporation
  • Sputtering
  • Sometimes called vacuum deposition because the
    process is usually done in an evacuated chamber
  • PVD is used for metals.
  • Dielectrics can be deposited using specialized
    equipment

3
Evaporation
  • Rely on thermal energy supplied to the crucible
    or boat to evaporate atoms
  • Evaporated atoms travel through the evacuated
    space between the source and the sample and stick
    to the sample
  • Few, if any, chemical reactions occur due to low
    pressure
  • Can force a reaction by flowing a gas near the
    crucible
  • Surface reactions usually occur very rapidly and
    there is very little rearrangement of the surface
    atoms after sticking
  • Thickness uniformity and shadowing by surface
    topography, and step coverage are issues

4
Evaporation
5
http//www.ee.byu.edu/cleanroom/metal.parts/vaporp
ressure.jpg
6
Mean Free Path
  • 63 of molecules undergo a collision in a
    distance less than l and 0.6 travel more than 5
    l.
  • where do is the diameter of the evaporatant and n
    is the concentration of gas molecules in the
    chamber

7
Evaporation
  • The vacuum is usually lt 10-5 torr
  • 4x10-6 torr, l 18 inches
  • The source heater can be
  • Resistance (W, Mo, Ta filament)
  • Contaminants in filament systems are Na or K
    because they are used in the production of W
  • E-beam (graphite or W crucible)
  • E-beam is often cleaner although S is a common
    contaminant in graphite
  • Top surface of metal is melted during evaporation
    so there is little contamination from the
    crucible
  • More materials can be evaporated (high
    melting-point materials)
  • A downside of e-beam is that X-rays are produced
    when the electron beam hits the Al melt
  • These X-rays can create trapped charges in the
    gate oxide
  • This damage must be removed by annealing

8
Thermal Evaporation
http//www.lesker.com/newweb/Deposition_Sources/Th
ermalEvaporationSources_Resistive.cfm
9
E-beam Evaporation
http//www.fen.bilkent.edu.tr/aykutlu/msn551/evap
oration.pdf
10
PVD
  • At sufficiently low pressure and reasonable
    distances between source and wafer, evaporant
    travel in straight line to the wafer
  • Step coverage is close to zero
  • If the source is small, we can treat it as a
    point source
  • If the source emission is isotropic, it is easy
    to compute the distribution of atoms at the
    surface of the wafer

11
PVD
12
PVD
  • For a source that emits only upwards, ? 2?
  • The number of atoms that hit the area Ak of the
    surface is
  • The deposition velocity is the above expression
    divided by the density (N) of the material

13
Evaporation
  • Pe is the equilibrium vapor pressure of the melt
    (torr)
  • m is the gram-molecular mass
  • T is the temperature (K)
  • As is area of source
  • The vapor pressure depends strongly on the
    temperature (Claussius-Clapeyron equation)
  • In order to have a reasonable evaporation rate
    (0.1-1 ?m/min), the vapor pressure must be about
    1-10 mtorr

14
PVD
15
PVD
  • The velocity can be normalized to the velocity at
    the center of the wafer

16
PVD
  • Corrections can be applied if the source is a
    small, finite area
  • If we now move the center of the wafer from the
    perpendicular position, but tile it with respect
    to the source, an extra term must be added

17
(No Transcript)
18
Planetaries
  • Wafer holders that rotate wafer position during
    deposition to increase film thickness uniformity
    across wafer and from one wafer to another.
  • Wobbling wafer holders increase step coverage

19
PVD
  • Nonuniformity of evaporatant can occur when
    angular emission of evaporant is narrower than
    the ideal source
  • Crucible geometry
  • Melt depth to melt area ratio
  • Density of gas atoms over the surface of the melt

20
Evaporation
  • Evaporating alloys is difficult Because of the
    differing vapor pressures.
  • Composition of the deposited material may very
    different from that of the target material
  • The problem can be overcome by
  • Using multiple e-beams on multiple sources
  • This technique causes difficulties in sample
    uniformity because of the spacing of the sources
  • Evaporating source to completion (until no
    material is left)
  • Dangerous to do in e-beam system

21
Evaporation
  • Compounds are also hard to evaporate because the
    molecular species may be different from the
    compound composition
  • Energy provided may be used to dissociate
    compound.
  • When evaporating SiO2, SiO is deposited.
    Evaporation in a reactive environment (flowing O2
    gas near crucible during deposition) helps
    reconstitute oxide.

22
Evaporation
  • Advantages
  • Little damage to the wafer
  • Deposited films are usually very pure
  • Limited step coverage
  • Disadvantages
  • Materials with low vapor pressures ae very
    difficult to evaporated
  • Refractory metals
  • High temperature dielectrics
  • No in situ precleaning
  • Limited step coverage
  • Film adhesion can be problematic

23
Step-coverage
  • Evaporation technique is very directional due to
    the large mean free paths of gas molecules at low
    pressure.
  • Shadowing of patterns and poor step coverage can
    occur when depositing thin films.
  • Rotation of the planetary substrate holder can
    minimize these effects.
  • Heating substrate can promote atom mobility,
    improve step coverage and adhesion.
  • Shadow masking and lift-off are processes where
    poor step coverage is desirable.

24
Other PVD Techniques
  • Other deposition techniques include
  • Sputter deposition (DC, RF, and reactive)
  • Bias sputtering
  • Magnetron sputtering
  • Collimated and ionized sputter deposition
  • Hot sputter deposition

25
Sputtering
  • Sputter deposition is done in a vacuum chamber
    (10mTorr) as follows
  • Plasma is generated by applying an RF signal
    producing energetic ions.
  • Target is bombarded by these ions (usually Ar).
  • Ions knock the atoms from the target.
  • Sputtered atoms are transported to the substrate
    where deposition occurs.

26
Sputtering
  • Wide variety of materials can be deposited
    because material is put into the vapor phase by a
    mechanical rather than a chemical or thermal
    process (including alloys and insulators).
  • Excellent step coverage of the sharp topologies
    because of a higher chamber pressure, causing
    large number of scattering events as target
    material travels towards wafers.
  • Film stress can be controlled to some degree by
    the chamber pressure and RF power.

http//www.knovel.com
27
Deposition conditions
  • Temperature Room to higher
  • Pressure 100mtorr
  • compromise between increasing number of Ar ions
    and increasing scattering of Ar ions with neutral
    Ar atoms
  • Power
  • Heating of target material
  • Low temperature metals can melt from temperature
    rise caused by energy transfer from Ar ions

28
Sputter sources
  • Magnetron
  • Magnetic field traps freed electron near target
  • Move in helical pattern, causing large number of
    scattering events with Ar gas creating high
    density of ionized Ar
  • Ion beam
  • Plasma of ions generated away from target and
    then accelerated toward start by electric field
  • Reactive sputtering
  • Gas used in plasma reacts with target material to
    form compond that is deposited on wafer
  • Ion-assisted deposition
  • Wafer is biased so that some Ar ion impact its
    surface, density the deposited film. May sputter
    material off of wafer prior to deposition for
    in-situ cleaning.

29
Sputtering
  • Advantages
  • Large-size targets, simplifying the deposition of
    thins with uniform thickness over large wafers
  • Film thickness is easily controlled by fixing the
    operating parameters and simply adjusting the
    deposition time
  • Control of the alloy composition, step coverage,
    grain structure is easier obtained through
    evaporation
  • Sputter-cleaning of the substrate in vacuum prior
    to film deposition
  • Device damage from X-rays generated by electron
    beam evaporation is avoided.
  • Disadvantages
  • High capital expenses are required
  • Rates of deposition of some materials (such as
    SiO2) are relatively low
  • Some materials such as organic solids are easily
    degraded by ionic bombardment
  • Greater probability to introduce impurities in
    the substrate because the former operates under a
    higher pressure 

30
Salicide
http//www.research.ibm.com/journal/rd/444/jordans
weet.html
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