U.S. patent application number 12/147871 was filed with the patent office on 2008-10-23 for susceptor designs for silicon carbide thin films.
This patent application is currently assigned to CREE, INC.. Invention is credited to Calvin Carter, Hua-Shuang Kong, Joseph Sumakeris.
Application Number | 20080257262 12/147871 |
Document ID | / |
Family ID | 25238547 |
Filed Date | 2008-10-23 |
United States Patent
Application |
20080257262 |
Kind Code |
A1 |
Kong; Hua-Shuang ; et
al. |
October 23, 2008 |
Susceptor Designs for Silicon Carbide Thin Films
Abstract
A susceptor is disclosed for minimizing or eliminating thermal
gradients that affect a substrate wafer during epitaxial growth.
The susceptor includes a first susceptor portion including a
surface for receiving a semiconductor substrate wafer thereon, and
a second susceptor portion facing the substrate receiving surface
and spaced from the substrate-receiving surface. The spacing is
sufficiently large to permit the flow of gases therebetween for
epitaxial growth on a substrate on the surface, while small enough
for the second susceptor portion to heat the exposed face of a
substrate to substantially the same temperature as the first
susceptor portion heats the face of a substrate that is in direct
contact with the substrate-receiving surface.
Inventors: |
Kong; Hua-Shuang; (Cary,
NC) ; Carter; Calvin; (Durham, NC) ;
Sumakeris; Joseph; (Cary, NC) |
Correspondence
Address: |
SUMMA, ALLAN & ADDITON, P.A.
11610 NORTH COMMUNITY HOUSE ROAD, SUITE 200
CHARLOTTE
NC
28277
US
|
Assignee: |
CREE, INC.
Durham
NC
|
Family ID: |
25238547 |
Appl. No.: |
12/147871 |
Filed: |
June 27, 2008 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
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09715576 |
Nov 17, 2000 |
|
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12147871 |
|
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|
08823365 |
Mar 24, 1997 |
6217662 |
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09715576 |
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Current U.S.
Class: |
118/723I ;
118/725 |
Current CPC
Class: |
C23C 16/4582 20130101;
C30B 25/12 20130101 |
Class at
Publication: |
118/723.I ;
118/725 |
International
Class: |
C23C 16/48 20060101
C23C016/48; C23C 16/02 20060101 C23C016/02 |
Claims
1. A susceptor for minimizing or eliminating thermal gradients
across a substrate wafer, said susceptor comprising: a first
susceptor portion formed of a material that is thermally responsive
to electromagnetic radiation and having a top surface for receiving
a semiconductor substrate wafer thereon; and a second susceptor
portion parallel to and spaced apart from said wafer-receiving
surface of said first susceptor portion and formed of a material
that is thermally responsive to electromagnetic radiation, said
spacing being sufficiently large to permit the flow of gases
therebetween for epitaxial growth on a substrate wafer on said
surface, while small enough for said second susceptor portion to
heat the exposed face of a substrate wafer to substantially the
same temperature as said first suseeptor portion heats the face of
a substrate wafer that is in direct contact with said
substrate-receiving surface.
2. The susceptor according to claim 1, wherein said first and
second susceptor portions are horizontally oriented.
3. The susceptor according to claim 1, wherein said first and
second susceptor portions are formed of the same material and are
responsive to the same frequencies of electromagnetic
radiation.
4. The susceptor according to claim 1, wherein said first and
second susceptor portions are thermally responsive to radio
frequency electromagnetic radiation.
5. The susceptor according to claim 1, wherein said first susceptor
portion is formed of graphite coated with silicon carbide,
6. The susceptor according to claim 1, wherein said second
susceptor portion is formed of graphite coated with silicon
carbide.
7. The susceptor according to claim 1, wherein said top surface of
said first susceptor portion includes a plurality of wafer
pockets.
8. A susceptor for minimizing or eliminating thermal gradients
across a substrate wafer, said susceptor comprising horizontally
oriented first and second susceptor portions, wherein: said first
susceptor portion is formed of graphite coated with silicon carbide
that is thermally responsive to electromagnetic radiation and has a
top surface including a plurality of wafer pockets for receiving a
plurality of semiconductor substrate wafers; and said second
susceptor portion is parallel to and spaced above said
wafer-receiving surface of said first susceptor portion and is
formed of graphite coated with silicon carbide that is thermally
responsive to electromagnetic radiation, said spacing being
sufficiently large to permit the flow of gases therebetween for
epitaxial growth on a substrate wafer on said surface, while small
enough for said second susceptor portion to heat the exposed face
of a substrate wafer to substantially the same temperature as said
first susceptor portion heats the face of a substrate wafer that is
in direct contact with said substrate-receiving surface.
9. A chemical vapor deposition system comprising: a reaction
vessel; a gas supply system in fluid communication with said
reaction vessel; a source of electromagnetic radiation; and a
susceptor within said reaction vessel and comprising a first
susceptor portion formed of a material that is thermally responsive
to selected frequencies of electromagnetic radiation and having a
top surface for receiving semiconductor substrate wafers thereon;
and a second susceptor portion parallel to and spaced apart from
said wafer-receiving surface of said first susceptor portion and
formed of a material that is thermally responsive to selected
frequencies of electromagnetic radiation, said spacing being
sufficiently large to permit the flow of gases therebetween for
epitaxial growth on a substrate wafer on said surface, while small
enough for said second susceptor portion to radiantly and directly
heat the exposed face of a substrate wafer to substantially the
same temperature as said first susceptor portion heats the face of
a substrate wafer that is in direct contact with said
substrate-receiving surface to thereby minimize or substantially
eliminate radial and axial temperature gradients across a substrate
wafer.
10. The system according to claim 9, wherein said first and second
susceptor portions are horizontally oriented.
11. The system according to claim 9, wherein said first and second
susceptor portions are formed of the same material and are
responsive to the same frequencies of electromagnetic
radiation.
12. The system according to claim 9, wherein said first and second
susceptor portions are thermally responsive to radio frequency
electromagnetic radiation.
13. The system according to claim 9, wherein said first susceptor
portion is formed of graphite coated with silicon carbide.
14. The system according to claim 9, wherein said second suseeptor
portion is formed of graphite coated with silicon carbide.
15. The system according to claim 9, wherein said top surface of
said first susceptor portion includes a plurality of wafer
pockets.
16. The system according to claim 9, wherein said source of
electromagnetic radiation is inside said reaction vessel.
17. The system according to claim 9, wherein said reaction vessel
is formed of a material substantially transparent to
electromagnetic radiation.
18. The system according to claim 17, wherein said reaction vessel
is made of quartz.
19. The system according to claim 9, wherein said reaction vessel
is made of stainless steel.
20. The system of claim 9, wherein said gas supply system comprises
an injector oriented substantially perpendicular to surface for
receiving semiconductor substrate wafers thereon of said first
susceptor portion.
21. A chemical vapor deposition system comprising: a reaction
vessel formed of a material substantially transparent to
electromagnetic radiation; a gas supply system in fluid
communication with said reaction vessel; a source of
electromagnetic radiation; and a susceptor within said reaction
vessel and comprising a first susceptor portion formed of graphite
coated with silicon carbide that is thermally responsive to
selected frequencies of electromagnetic radiation and having a top
surface including a plurality of wafer pockets for receiving a
plurality of semiconductor substrate wafers; and a second susceptor
portion parallel to and spaced apart from said wafer-receiving
surface of said first susceptor portion and formed of graphite
coated with silicon carbide that is thermally responsive to
selected frequencies of electromagnetic radiation, said spacing
being sufficiently large to permit the flow of gases therebetween
for epitaxial growth on a substrate wafer on said surface, while
small enough for said second susceptor portion to radiantly and
directly heat the exposed face of a substrate wafer to
substantially the same temperature as said first susceptor portion
heats the face of a substrate wafer that is in direct contact with
said substrate-receiving surface to thereby minimize or
substantially eliminate radial and axial temperature gradients
across a substrate wafer.
Description
CROSS REFERENCE TO RELATED APPLICATIONS
[0001] This application is a continuation of commonly assigned
copending U.S. application Ser. No. 09/715,576, filed Nov. 17,
2000, which is a continuation of U.S. application Ser. No.
08/823,365, filed Mar. 24, 1997, now U.S. Pat. No. 6,217,662, the
entire disclosure of each of which is hereby incorporated by
reference in their entirety.
FIELD OF THE INVENTION
[0002] The present invention relates to semiconductor manufacturing
processes, and in particular relates to an improved susceptor
design for epitaxial growth on silicon carbide substrates.
BACKGROUND OF THE INVENTION
[0003] The present invention relates to the production of epitaxial
layers of semiconductor materials on silicon carbide substrates.
Silicon carbide offers a number of advantageous physical and
electronic characteristics for semiconductor performance and
devices. These include a wide bandgap, high thermal conductivity,
high saturated electron drift velocity, high electron mobility,
superior mechanical strength, and radiation hardness.
[0004] As is the case with other semiconductor materials such as
silicon, one of the basic steps in the manufacture of a number of
silicon-carbide based devices includes the growth of thin single
crystal layers of semiconductor material on silicon carbide
substrates. The technique is referred to as "epitaxy," a term that
describes crystal growth by chemical reaction used to form, on the
surface of another crystal, thin layers of semiconductor materials
with defined lattice structures. In many cases, the lattice
structure of the epitaxial layers (or "epilayers") are either
identical, similar, or otherwise related to the lattice structure
of the substrate. Thus, epitaxial growth of either silicon carbide
epitaxial layers on silicon carbide substrates or of other
semiconductor materials on silicon carbide substrates, is a
fundamental technique for manufacturing devices based on silicon
carbide.
[0005] Silicon carbide is, however, a difficult material to work
with because it can crystallize in over 150 polytypes, some of
which are separated from one another by very small thermodynamic
differences. Furthermore, because of silicon carbide's high melting
point (over 2700.degree.), many processes for working silicon
carbide, s including epitaxial film deposition, often need to be
carried out at much higher temperature than analogous reactions in
other semiconductor materials.
[0006] Some basic reviews of semiconductor manufacturing technology
can be found for example in Sze, Physics of Semiconductor Devices,
2d Ed. (1981), Section 2.2, pages 64-73; or in Dorf, The Electrical
Engineering Handbook, CRC Press, (1993) at Chapter 21"Semiconductor
Manufacturing," pages 475-489; and particularly in Sherman,
Chemical Vapor Deposition for Microelectronics: Principles,
Technologies and Applications, (1987), ISBN 0-8155-11136-1. The
techniques and apparatus discussed herein can be categorized as
chemical vapor deposition (CVD) or vapor phase epitaxy (VPE) in
which reactant gases are exposed to an energy source (e.g. heat,
plasma, light) to stimulate a chemical reaction, the product of
which grows on the substrate.
[0007] There are several basic techniques for CVD epitaxial growth,
the two most common of which are the hot (heated) wall reactor and
cold wall reactor processes. A hot wall system is somewhat
analogous to a conventional oven in that the substrate, the
epitaxial growth precursor materials, and the surrounding container
are all raised to the reaction temperature. The technique offers
certain advantages and disadvantages.
[0008] The second common conventional technique is the use of a
"cold wall" reactor. In such systems, the substrate to be used for
epitaxial growth is placed on a platform within a container
(typically formed of quartz or stainless steel). In many systems,
the substrate is disk-shaped and referred to as a "wafer." The
substrate platform is made of a material that will absorb, and
thermally respond to, electromagnetic radiations.
[0009] As is known to those familiar with such devices and
techniques, the susceptor's response to electromagnetic radiation
is an inductive process in which alternating frequency
electromagnetic radiation applied to the susceptor generates an
induced (inductive) current in the susceptor. The susceptor
converts some of the energy from this inductive current into heat.
In many systems, the electromagnetic radiation is selected in the
radio frequency (RF) range because materials such as glass and
quartz are transparent to such frequencies and are unaffected by
them. Thus, the electromagnetic radiation passes through the
container and is absorbed by the susceptor which responds by
becoming heated, along with the wafer, to the temperatures required
to carry out the epitaxial growth. Because the container walls are
unaffected by the electromagnetic energy, they remain "cold" (at
least in comparison to the susceptor and the substrate), thus
encouraging the chemical reaction to take place on the
substrate.
[0010] A thorough discussion of the growth of silicon carbide
epitaxial layers on silicon carbide substrates is set forth for
example in U.S. Pat. Nos. 4,912,063 to Davis et al. and 4,912,064
to Kong et al., the contents of both of which are incorporated
entirely herein by reference.
[0011] The use of a cold wall reactor to carry out epitaxial
growth, although satisfactory in many respects, raises other
problems. In particular, because a semiconductor wafer rests on a
susceptor, the wafer side in contact with the susceptor will become
warmer than the remainder of the substrate. This causes a thermal
gradient in the axial direction through the wafer. In turn, the
difference in thermal expansion within the wafer caused by the
axial gradient tends to cause the peripheral edges (typically the
circumference because most wafers are disc-shaped) to curl away
from, and lose contact with, the susceptor. As the edges lose
contact with the susceptor, their temperature becomes lower than
the more central portions of the wafer, thus producing a radial
temperature gradient in the substrate wafer in addition to the
axial one.
[0012] These temperature gradients, and the resulting physical
effects, have corresponding negative affects on the characteristics
of the substrate and the epitaxial layers upon it. For example, if
the edges are placed in extreme tension, they have been observed to
crack and fail catastrophically. Even if catastrophic failure is
avoided, the epitaxial layers tend to contain defects. At silicon
carbide CVD growth temperatures (e.g. 1300.degree.-1800.degree.
C.), and using larger wafers (i.e. two inches or larger), wafer
bending becomes a significant problem. For example, FIG. 3 herein
plots the values of wafer deflection (H) at various axial
temperature gradients as a function of the wafer diameters.
[0013] Furthermore, because wafers have a finite thickness, the
heat applied by the suseeptor tends to generate another temperature
gradient along the central axis of the wafer. Such axial gradients
can both create and exacerbate the problems listed above.
[0014] Yet another temperature gradient typically exists between
the rear surface of the substrate wafer and the front surface of
the susceptor; i.e. a surface-to-surface gradient. It will thus be
understood that both radiant and conductive heat transfer typically
take place between susceptors and substrate wafers. Because many
susceptors are formed of graphite coated with silicon carbide, the
thermodynamic driving force created by the large temperature
gradients between the suseeptor and the silicon carbide wafers also
causes the silicon carbide coating to undesirably sublime from the
susceptor to the wafer.
[0015] Additionally, because such sublimation tends to promote pin
hole formation in the susceptor coating, it can permit contaminants
from the graphite to escape and unintentionally dope the substrates
or the epilayers. This in turn ultimately leads to non-uniform
doping levels in the semiconductor material, and reduces the
lifetime of the susceptor. The problems created by susceptors which
undesirably emit dopants is set forth for example in the background
portion of U.S. Pat. No. 5,119,540 to Kong et al.
[0016] Nevertheless, a need still exists for susceptors that can
operate at the high temperatures required for silicon carbide
processing while minimizing or eliminating these radial, axial and
surface to surface temperature gradients, and the associated
physical changes and problems.
OBJECT AND SUMMARY OF THE INVENTION
[0017] Therefore, it is an object of the present invention to
provide a susceptor for minimizing or eliminating radial, axial and
surface-to-surface thermal gradients across a substrate wafer.
[0018] The invention meets this object with a susceptor that
comprises a first portion that includes a surface for receiving a
semiconductor substrate wafer thereon, and a second portion facing
the substrate receiving surface and spaced from the substrate
receiving surface with the spacing being sufficiently large to
permit the flow of gases therebetween for epitaxial growth on a
substrate. The spacing remains small enough, however, for the
second susceptor portion to heat the exposed face of a substrate to
substantially the same temperature as the first susceptor portion
heats the face of the substrate that is in direct contact with the
substrate receiving surface.
[0019] In another aspect, the invention is a method for minimizing
or eliminating thermal gradients in and around a substrate during
epitaxial growth by heating a portion of a susceptor that faces,
but avoids contact with, a semiconductor substrate, and that is
spaced sufficiently far from the substrate to permit the flow of
gases between the substrate and the susceptor portion to encourage
epitaxial growth on the substrate facing the susceptor portion
wherein the susceptor is thermally responsive to the irradiating
radiation.
[0020] The foregoing and other objects, advantages and features of
the invention, and the manner in which the same are accomplished,
will be more readily apparent upon consideration of the following
detailed description of the invention taken in conjunction with the
accompanying drawings, which illustrate preferred and exemplary
embodiments, and wherein:
BRIEF DESCRIPTION OF THE DRAWINGS
[0021] FIG. 1 is a cross-sectional view of a platform type chemical
vapor deposition (CVD) system:
[0022] FIG. 2 is a cross-sectional view of a barrel-type CVD
system;
[0023] FIG. 3 is a graph illustrating the relationship between
wafer deflection and wafer diameter at various temperature
gradients;
[0024] FIG. 4 is a schematic view of a barrel-type susceptor;
[0025] FIG. 5 is a schematic view of wafer deflection and
temperature gradients;
[0026] FIG. 6 is a cross-sectional view of one embodiment of a
susceptor according to the present invention;
[0027] FIG. 7 is a partial cross-sectional view of a second
embodiment of the susceptor of the present invention;
[0028] FIG. 8 is a cross-sectional view of a pancake-type
susceptor;
[0029] FIG. 9 is a top plan view of a pancake-type susceptor
according to the present invention; and
[0030] FIG. 10 is a cross-sectional view of a pancake-type
susceptor according to the present invention.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0031] The present invention is a susceptor for minimizing or
eliminating thermal gradients, including radial, axial, and
surface-to-surface gradients, that affect a substrate wafer during
epitaxial growth. Substrates according to the present invention are
particularly useful for chemical vapor deposition systems as
illustrated in FIGS. 1 and 2, FIG. 1 shows a platform or pancake
type CVD system broadly designated at 20. The system comprises a
reactor vessel 21 formed of a material, typically a quartz tube or
bell jar, that is substantially transparent to the appropriate
frequencies of electromagnetic radiation. A gas supply system is in
fluid communication with the reaction vessel 21 and in FIG. 1 is
illustrated as the gas injector 22.
[0032] The system includes a source of electromagnetic radiation
that in FIG. 1 is illustrated as the induction coils 25. The
operation of such generators and induction coils is generally well
known to those of ordinary skill in the art, and will not be
discussed further herein in detail. As is also understood in this
art, alternative heating techniques can include electric resistance
heating, radiant lamp heating, and similar techniques.
[0033] The chemical vapor deposition system shown in FIG. 1 also
includes the platform type susceptor 26 with semiconductor
substrates, typically disc-shaped wafers 27 thereon. FIG. 1 also
illustrates the pumping port 30 for evacuating the system as
desired.
[0034] FIG. 2 illustrates a system that is very similar in terms of
its basic operation, but that is a barrel-type susceptor, rather
than a pancake-type. In FIG. 2, the CVD system is broadly
designated at 32 and shows a reaction vessel 33 which is surrounded
by a water jacket 34 which circulates water against the walls of
the reaction vessel 33. The CVD system 32 also includes a gas inlet
35 and a gas exhaust 36, a water inlet 37 and the water outlet 40,
and a lifting and rotation assembly 41 for the susceptor.
[0035] The susceptor itself is broadly designated at 42 and is in
the general shape of a cylinder although with a shallow slope that
general shape of a cylinder, although with a shallow slope that
gives it somewhat frustoconical shape. The cylinder is formed of a
plurality of adjacent straight sidewall sections 43 that define the
cylinder. A plurality of wafer pockets 44 are positioned on the
sidewalls 43 and hold the semiconductor substrates thereon. The
slight incline of the susceptor walls help keep the wafers in the
pockets 44, and improve the uniformity of the resulting epilayers
by encouraging more favorable gas flow. FIG. 2 also illustrates the
power supply 45 for the induction coil broadly designated at
46.
[0036] FIG. 3 is a graph that helps illustrate the problem
addressed by the present invention. In FIG. 3, the deflection of a
wafer expressed in thousandths of an inch is plotted against the
wafer diameter in inches for three different temperature gradients
("Delta T"). As noted in FIG. 3, the susceptor surface temperature
is 1530.degree. C. and the wafer thickness is 12 mils (0.012 inch).
As FIG. 3 illustrates, wafer deflection represents a minimal
problem when the diameter of the substrate wafer is about an inch
or less, For larger wafer, particularly those of two, three or even
four inches, the deflection becomes more severe, even at relatively
low temperature gradients.
[0037] FIG. 4 illustrates a barrel type susceptor similar to that
used in the illustration of FIG. 2. Using the same numbering system
as FIG. 2, the susceptor is broadly designated at 42, is made of a
plurality of straight sidewalls 43 that together define the
generally cylindrical shape. The sidewalls 43 include a plurality
of wafer pockets 44 for holding the substrate wafer.
[0038] FIG. 5 is a schematic illustration of the effects of the
temperature gradients plotted in FIG. 3, and includes the
designation of the axial temperature gradient (.DELTA.T.sub.1) and
of the radial gradient (.DELTA.T.sub.2).
[0039] FIG. 6 illustrates a susceptor according to the present
invention that is most appropriately used in the barrel type
systems illustrated in FIG. 2. In the embodiment illustrated in
FIG. 6, the susceptor is broadly designated at 50 and is a cylinder
formed of a plurality of adjacent straight sidewall sections 51.
FIG. 6 illustrates two of the sidewalls in cross-section and one in
side elevation. The straight sidewall sections 51, of which there
are most typically four, six, or eight, are formed of a material
that is thermally responsive to selected frequencies of
electromagnetic radiation. As noted above, the most common
electromagnetic radiation is in the radio frequency range, so the
susceptor material is generally selected to be thermally responsive
to such RF frequencies. In preferred embodiments, the susceptor 50
is formed of graphite coated with silicon carbide.
[0040] In a presently preferred embodiment, the electromagnetic
radiation is applied in the 8-10 kilocycle range using a solid
state power supply that takes advantage of the inherent
efficiencies of solid state technology. Those familiar with
inductive CVD processes will also recognize that thicker susceptor
walls require lower frequencies to achieve the most efficient
penetration.
[0041] In the embodiment illustrated in FIG. 6, the susceptor 50
includes a plurality of wafer pockets 52 on the inner circumference
of the cylinder. Thus, when the susceptor 50 is heated, the facing
walls radiantly heat the front of the wafers while the susceptor
heats the rear. In other words, the facing walls directly (i.e.,
actively or non-passively) heat one another in response to exposure
to electromagnetic radiation. As FIG. 6 illustrates, in this
embodiment, the sidewalls 51 preferably define an inverted
truncated cone with a relatively shallow slope as compared to a
true cylinder. As noted earlier, the shallow slope in the sidewalls
51 makes it somewhat easier to retain the wafers in the pockets 52
during chemical vapor deposition, and also helps provide a proper
flow pattern for the CVD gases.
[0042] FIG. 7 illustrates a next embodiment of the invention in
which the susceptor comprises a first cylinder (or "barrel")
broadly designated at 54. The cylinder is defined by a plurality of
adjacent straight sidewall sections 55, and is formed of a material
that is thermally responsive to selected frequencies of
electromagnetic radiation. The cylinder 54 includes a plurality of
wafer pockets 56 on the outer surface of the sidewall sections
55.
[0043] A second cylinder broadly designated at 57 surrounds the
first cylinder 54 and defines an annular space A between the first
and second cylinders. The second cylinder 57 is likewise made of a
material that is thermally responsive to the selected frequencies
of electromagnetic radiation, and the annular space between the
first and second cylinders (54, 57) is sufficiently large to permit
the flow of gases therebetween for epitaxial growth on substrates
in the wafer pockets 56, while small enough for the second cylinder
57 to heat the exposed face of substrates to substantially the same
temperature as the first cylinder 54 heats the faces of substrates
that are in direct contact with the first cylinder (i.e., the
second cylinder directly or actively heats the substrate and first
cylinder in response to electromagnetic radiation).
[0044] The first and second cylinders 54, 57 can be formed of
either the same or different materials. If used in a barrel type
susceptor system as illustrated in FIG. 2, the second cylinder 57
tends to heat the first cylinder 54 to encourage the cylinders to
reach substantially the same temperatures. As in other embodiments,
each of the cylinders is most preferably formed of graphite coated
with silicon carbide.
[0045] It will be understood that the use of a silicon carbide
coating on such susceptors is a function of the ceramic properties
of polycrystalline silicon carbide and is otherwise not related to
its semiconductor properties. Thus, susceptors made of stainless
steel, graphite, graphite coated with silicon carbide, or silicon
carbide, are typically used in the semiconductor industry for CVD
processes.
[0046] FIGS. 8, 9 and 10 illustrate another susceptor according to
the present invention. FIGS. 8 and 9 illustrate, in cross-section
and top plan view respectively, a pancake or plate-shaped susceptor
broadly designated at 60. The susceptor 60 has a top surface 61 for
receiving semiconductor substrate wafers thereon. In this
embodiment, the invention further comprises a horizontally disposed
second susceptor portion 63 parallel to and above the wafer
receiving surface 61 of the first susceptor portion 60. Both of the
susceptor portions 60 and 63 are formed of materials that are
thermally responsive to selected frequencies of electromagnetic
radiation, and as in the previous embodiments, are preferably
formed of the same material to be responsive the same frequencies
of electromagnetic radiation. Most preferably, both suseeptor
portions 60 and 63 are formed of graphite coated with silicon
carbide. As in the previous embodiments, the spacing designated B
(FIG. 10) between the two portions 60, 63 is sufficiently large to
permit the flow of gases therebetween for epitaxial growth on a
substrate on the surface 61, while small enough for the second
susceptor portion 63 to heat the exposed face of a substrate to
substantially the same temperature as the first susceptor portion
60 heats the face of substrate that is in direct contact with the
substrate receiving surface 61. As illustrated in FIGS. 8, 9 and
10, the top surface 61 of the first horizontal susceptor portion 60
preferably includes a plurality of wafer pockets 64.
[0047] In each of these embodiments, it will be understood that the
two susceptor portions can be connected to one another, or separate
portions of a single susceptor, or independent pieces as may be
desired or necessary under various circumstances. Additionally, the
optimum spacing between the substrate portions can be determined by
computer modeling or actual practice, and without requiring undue
experimentation.
[0048] In another aspect, the invention comprises a method for
minimizing or eliminating thermal gradients in a substrate during
epitaxial growth. In this aspect, the invention comprises
irradiating a susceptor, or a susceptor portion, that faces, but
avoids contact with, a semiconductor substrate wafer, and that is
spaced sufficiently far from the wafer to permit the flow of gases
between the substrate and the facing susceptor to thereby encourage
epitaxial growth on the substrate facing the susceptor portion. As
in the structural embodiments, the susceptor is thermally
responsive to the irradiating radiation.
[0049] As further set forth with respect to the structural aspects
of the invention, the invention also preferably comprises
concurrently irradiating a separate susceptor portion upon which
the wafer rests so that the exposed face of the substrate is heated
to substantially the same temperature as is the face of the
substrate that is in direct contact with the other susceptor
portion.
[0050] The method further comprises the steps of directing source
gases that flow between the heated susceptor portions. If the
epitaxial layers are to be formed of silicon carbide, the method
preferably comprises directing silicon and carbon containing source
gases such as silane, ethylene, and propane.
[0051] Where other materials, such as Group III nitrides, are to
form the epitaxial layers on the silicon carbide, the step of
directing sources gases can include directing source gases such as
trimethyl aluminum, trimethyl gallium, trimethyl indium, and
ammonia.
[0052] In preferred embodiments, the method also comprises the step
of preparing the substrate surface for growth. As set forth in more
detail in the references incorporated above, such preparation can
comprise steps such as oxidizing the surface followed by a chemical
etching step to remove the oxidized portion leaving a prepared
surface behind, or alternatively, dry etching the silicon carbide
surface to prepare it for further growth. As in most epitaxial
growth technique, surface preparation further typically comprises
lapping and polishing the substrate surface prior to the oxidation
or etching steps.
[0053] In the drawings and specifications, there have been
disclosed typically preferred embodiments of the invention and,
although specific terms have been employed, they have been used in
a generic sense and in descriptive sense only, and not for purposes
of limitation, the scope of the invention being set forth in the
following claims:
* * * * *