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Unit 3 Crystal Growth and Wafer Preparation

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Material preparation is the beginning of the process in making an IC chip. ... antimony and melted at 1400 in a quartz crucible surrounded by an inert gas ... – PowerPoint PPT presentation

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Title: Unit 3 Crystal Growth and Wafer Preparation


1
Unit 3 Crystal Growth and Wafer Preparation
2
Material Preparation
  • Material preparation is the beginning of the
    process in making an IC chip .
  • The goal for this part of the process is to grow
    the ingot that will be sliced up into wafers.
  • The wafer is a round solid silicon disc that will
    have all of the processing performed on it.

3
Step 1 Obtaining the Sand
  • The sand used to grow the wafers has to be a very
    clean and good form of silicon.
  • For this reason not just any sand scraped off the
    beach will do.
  • Most of the sand used for these processes is
    shipped from the beaches of Australia.

4
Step 2 Preparing the Molten Silicon Bath
  • The sand is taken and put into a pot where it is
    heated to about 1600 degrees C where it melts.
  • The molten sand will become the source that will
    ultimately produce the raw poly-crystalline
    silicon.

5
Raw Polysilicon
  • Raw polycrystalline silicon produced by mixing
    refined trichlorosilane with hydrogen gas in a
    reaction furnace.
  • The poly-crystalline silicon is allowed to grow
    on the surface of electrically heated tantalum
    hollow metal wicks

6
Polysilicon Ingots
  • The polycrystalline silicon tubes refined by
    dissolving in hydrofluoric acid producing
    polysilicon ingots.
  • Polycrystalline silicon has randomly oriented
    crystallites, electrical characteristics not
    ready for device fabrication.
  • Must be transformed into single crystal silicon
    using crystal pulling

7
Step 3 Making the Ingot
  • A pure silicon seed crystal is now placed into
    the molten sand bath.
  • This crystal will be pulled out slowly as it is
    rotated.
  • The result is a pure silicon tube that is called
    an ingot

8
Creating the Single Crystalline Ingot
  • Crushed high-purity polycrystalline silicon is
    doped with elements like arsenic, boron,
    phosphorous or antimony and melted at 1400 in a
    quartz crucible surrounded by an inert gas
    atmosphere of high-purity argon.
  • The melt is cooled to a precise temperature, then
    a "seed" of single crystal silicon is placed into
    the melt and slowly rotated as it is "pulled"
    out.

9
Creating the Single Crystalline Ingot (cont.)
  • The surface tension between the seed and the
    molten silicon causes a small amount of the
    liquid to rise with the seed and cool into a
    single crystalline ingot with the same
    orientation as the seed.
  • The ingot diameter is determined by a combination
    of temperature and extraction speed

10
Examples of completed ingots
11
Ingot Sizes
  • Most ingots produced today are 150mm (6") and
    200mm (8") diameter,
  • For the most current technology 300mm (12") and
    400mm (16") diameter ingots are being developed.

12
Ingot Characterization
  • Single Crystal Silicon ingots are characterized
    by the orientation of their silicon crystals.
    Before the ingot is cut into wafers, one or two
    "flats" are ground into the diameter of the ingot
    to mark this orientation.

13
Different flats for orientation
  • Each of the wafers is given either a notch or a
    flat edge
  • This will be used in orienting the wafer into the
    exact position for later procedures.

14
lt100gt Lattice Orientation
  • This lattice orientation is used for MOS
    (metaloxide semiconductor), Bi-CMOS, GaAs types
    of chips.

15
Lattice Orientation
  • The lattice orientation refers to the organized
    pattern of the silicon crystals in the wafer and
    their orientation to the surface.
  • The orientation is obtained based on the
    orientation of the crystal that is placed into
    the molten silicon bath.
  • The different orientations have different
    benefits and are used in different types of
    chips.

16
lt111gt Lattice Orientation
  • This orientation is used for Bipolar types of
    chips

17
Step 4 Preparing the Wafers
  • The ingot is ground into the correct diameter for
    the wafers.
  • Then it is sliced into very thin wafers.
  • This is usually done with a diamond saw.

18
Some wafers in storage trays
19
Wafer Lapping
  • The sliced wafers are mechanically lapped using a
    counter-rotating lapping machine and aluminum
    oxide slurry. This flattens the wafer surfaces,
    makes them parallel and reduces mechanical
    defects like saw markings

20
Wafer Lapping Machine
21
Wafer Etching
  • After lapping, wafers are etched in a solution of
    nitric acid/ acetic acid or sodium hydroxide to
    remove microscopic cracks or surface damage
    created by the lapping process.
  • The acid or caustic solution is removed by a
    series of high-purity RO/DI water baths

22
Wafer polishing
  • Next, the wafers are polished in a series of
    combination chemical and mechanical polish
    processes called CMP
  • The wafers are held in a hard ceramic chuck using
    either wax bond or vacuum and buffed with a
    slurry of silica powder, RO/DI water and sodium
    hydroxide

23
Wafer Cleaning
  • Most wafer manufacturers use a 3-step process
    which starts with an SC1 solution (ammonia,
    hydrogen peroxide and RO/DI water) to remove
    organic impurities and particles from the wafer
    surface.
  • Next, natural oxides and metal impurities are
    removed with hydrofluoric acid.
  • Finally, the SC2 solution, (hydrochloric acid and
    hydrogen peroxide), causes super clean new
    natural oxides to grow on the surface.

24
Growth of Epitaxial Silicon
  • The purpose of EPI growth is to create a layer
    with different, usually lower, concentration of
    electrically active dopant on the substrate. For
    example, an n-type layer on a p-type wafer.
  • This layer is of a much better quality then the
    slightly damaged or unclean layer of silicon in
    the wafer
  • It is called the Epitaxial layer - where the
    actual processing will be done.

25
An Epitaxial reactor.
26
Epitaxial Reactors
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