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This invention relates to a method of producing hydrogenated amorphous
silicon which comprises thermally decomposing silane gas by passing said
silane gas through a tungsten tube heated to about 1700.degree. C. and up
to 2100.degree. C. or 2300.degree. C. in vacuum to form a flux of atomic
hydrogen and atomic silicon, depositing said flux onto a substrate by
directing the stream of said flux at a substrate, which can be heated to a
temperature less than 500.degree. C., situated outside said tungsten tube,
and recovering hydrogenated amorphous silicon.
Amorphous silicon is a material which has commercial application as a low
cost photovoltaic material. However, the methods heretofore utilized in
its preparation have limited its utility because of the presence of
impurities and the failure of the removal of such impurities from the
deposited amorphous silicon; as well as the non-uniformity in the
electrical properties of the resultant deposited amorphous silicon film.
This may have detrimental effects on electrical performance.
In addition, presently available processes of producing amorphous silicon,
such as electron beam deposition, cause clusters of silicon to form, which
are believed to degrade the properties of amorphous silicon.
It has now been found that in the present process, atomic silicon is
deposited along with atomic hydrogen and the mean free path for collisions
is long enough in the chamber so that clusters should not form. In
addition, control of the temperature of the tungsten tube will control the
decomposition compounds coming from the silane gas or other silicohydride
gas. Another advantage of present process, which utilizes a high vacuum
environment, is that it can be used in combination with electron beam
deposition.
The hydrogenated amorphous silicon produced by present process will possess
superior properties since the silicon will be purely atomic prior to
deposition. It is further believed that the excellent properties of this
material comes from the significant passivation of dangling (free)bonds
present in pure amorphous silicon, with the atomic hydrogen that results
from the silane decomposition.
Accordingly, it is a primary object of instant invention to provide
hydrogenated amorphous silicon having particular utility as a photovoltaic
material.
Another object of instant invention is to provide a process for the thermal
decomposition of a silane into a gaseous mixture of atomic hydrogen and
atomic silicon which is deposited on a substrate outside the source of
thermal decomposition to form hydrogenated amorphous silicon.
Still another object of instant invention is to provide a hydrogenated
amorphous silicon of improved and uniform electrical properties.
Still another object of instant invention is to provide an efficient
process for producing a hydrogenated amorphous silicon film of controlled
electrical properties.
Accordingly, present invention relates to a process of producing
hydrogenated amorphous silicon which comprises thermally decomposing a gas
containing silicon and hydrogen such as silane, disilane, trisilane,
tetrasilane and the like into a mixture of atomic hydrogen and atomic
silicon, and depositing said gaseous mixture onto a substrate situated
outside the source of thermal decomposition, which may or may not be
heated.
More specifically, the present process of producing hydrogenated amorphous
silicon comprises decomposing a silane gas in a tungsten tube heated to a
temperature of about 1700.degree.-2100.degree. C. in a vacuum of about
10.sup.-8 to 10.sup.-4 torr, into a gaseous mixture of silicon and atomic
hydrogen and directing a stream of this mixture at a substrate outside the
tungsten tube. Silane gas (SiH.sub.4) is thermally dissociated in the tube
forming a mixture of Si, H, SiH, SiH.sub.2 and SiH.sub.3. Control of the
temperature of the tungsten tube will control the relative proportions of
the decomposition compounds. At 1700.degree. C., a greater proportion of
SiH.sub.3 and SiH.sub.2 is formed than at 2100.degree. C. This process
also affords control of the silicon jet that leaves the thermal
decomposition source, making for an efficient deposition process.
Calculations show that rates of deposition of up to 10 monolayers/sec are
possible with a pressure of about 10.sup.-4 torr in the vacuum chamber.
This allows mass spectrographic control and determination of impurities,
plus the combination with other deposition techniques, such as electron
beam deposition. Present process provides for easier thermal decomposition
compared to glow discharge decomposition of silane in the production of
amorphous silicon.
PRIOR ART
The thermal decomposition of silane at elevated temperatures in the
production of amorphous, polycrystalline or monocrystalline silicon is
generally known in the prior art. For example, U.S. Pat. No. 2,993,763 to
Lewis discloses the process of preparing flakes of sintered silicon by
decomposing silane in a vacuum chamber to form a first layer of a brown
amorphous silicon deposited on the walls of said chamber and subsequent
layers of sintered silicon, heating the deposited silicon to a temperature
above 450.degree. C. by means of a heated silicon element such as a
silicon rod located within said chamber to further sinter the silicon and
form large silvery-grey flakes of sintered silicon. The Benzing et al U.S.
Pat. Nos. 3,014,791 and 3,112,997 disclose an apparatus and method for the
pyroylsis of silanes to form a high yield of crystalline silicon and a low
yield of amorphous silicon which consists in introducing a mixture of
silane and hydrogen or helium gas via a glass tube into a vacuum chamber
provided with a fused quartz heating tube which is heated to about
600.degree.-800.degree. C., said heating tube being provided with
protrusions whereon hyperpure polycrystals of dense silicon is deposited,
whereas amorphous silicon deposits on the walls of the chamber, and the
liberated hydrogen is removed from the chamber.
U.S. Pat. No. 3,765,960 to Boss et al discloses a method of minimizing
autodoping during the deposition of epitaxial polycrystalline or amorphous
layers of silicon on a heated silicon wafer which comprises contacting
said wafer with a gaseous reaction mixture of hydrogen and silane at a
temperature of 800.degree.-1300.degree. C., and at a pressure of 0.01 to
150 torr. U.S. Pat. No. 4,068,020 to Reuschel discloses the method of
producing an amorphous silicon layer by pyrolytically depositing elemental
silicon and a minor amount of at least one other element selected from
Groups IV through VIII which are nonsemiconductive, from a gaseous
reaction mixture containing thermally decomposable compounds of silicon
and said second element, onto a substrate (mandrel) heated to
800.degree.-1150.degree. C., said substrate being the heating element as
well. In all of aforesaid processes, a heating element heated to
450.degree.-1100.degree. C., which may be silicon or fused quartz, is
placed in a chamber containing a silane atmosphere, and amorphous silicon
is deposited on the walls of the chamber and/or the heating element within
said chamber.
In the production of crystalline silicon, the heating element for
decomposing the silane is also the substrate for collecting the
crystalline silicon as disclosed in U.S. Pat. Nos. 3,078,015 to Raymond,
3,130,013 to Wilson et al, and 3,140,922 to Sterling wherein the seed
crystal is both the substrate and the heating element. U.S. Pat. No.
3,147,141 to Ishizuka replaces the seed crystal of the above processes
with a tantalum wire as both the heating element and the substrate. The
use of the heating element as the substrate (carrier) for the crystalline
silicon in the thermal decomposition of silane is also disclosed by U.S.
Pat. No. 3,160,522 to Heywang, who uses temperatures slightly in excess of
1420.degree. C. (the melting point of silicon) and a quartz, ceramic or
metal carrier; U.S. Pat. No. 3,286,685 to Sandmann et al, who uses
temperatures of 1100.degree.-1400.degree. C. and a silicon carrier; U.S.
Pat. No. 3,496,037 to Jackson et al, who uses a sapphire substrate and a
temperature of 850.degree.-1000.degree. C.; U.S. Pat. No. 3,607,054 to
Conrod who grows a continuous filament crystal on a seed crystal of
silicon; U.S. Pat. No. 3,796,597 to Porter who heat treats the spinel
(MgO.Al.sub.2 O.sub.3) substrate to a temperature of
1045.degree.-1145.degree. C. to modify its surface and then deposits
crystalline silicon thereon; and U.S. Pat. No. 4,027,053 to Lesk who
produces a ribbon of polycrystalline silicon on a heated quartz or
tungsten substrate at a temperature of 1000.degree.-1200.degree. C.
U.S. Pat. No. 3,900,597 to Chruma et al places the substrate or carrier
which are wafers of silicon, germanium, sapphire, spinel, ceramic, silicon
dioxide, tungsten or molybdenum, into a quartz tube which is heated to
600.degree.-700.degree. C. under a vacuum of 600-1600 millitorrs; thereby
disclosing a heating element which is separate from the substrate or
carriers for the crystalline silicon. However, the wafer carriers or
substrate are inside the heated quartz tube.
Although the prior art discloses the thermal decomposition of a gas
containing hydrogen and silicon, such as silane, into amorphous and/or
crystalline silicon which is deposited on the walls of the decomposition
chamber, or on a substrate which also serves as the heating element or on
a substrate situated within the thermal decomposition source (inside the
heated tube); there is no disclosure of the production of hydrogenated
amorphous silicon collected on an independent substrate situated outside
the thermal decomposition source. The presence of the hydrogen in the
amorphous silicon film is responsible for improved electrical and optical
properties, the hydrogen compensating dangling bonds present in pure
amorphous silicon; whereas amorphous silicon produced by evaporation or
sputtering in a pure argon atmosphere has low resistivity (about 10.sup.3
ohms cm), poor photoconductivity and a high optical absorption below 1.5
eV.
DESCRIPTION OF THE INVENTION
The hydrogenated amorphous silicon according to present invention is
produced by the thermal decomposition of a gas containing silicon and
hydrogen such as the silicohydrides which include monosilane, disilane,
trisilane and tetrasilane, at a temperature above the decomposition
temperature of said gas, preferably about 1700.degree.-2100.degree. C. and
under a vacuum of preferably about 10.sup.-6 to 10.sup.-4 torr into a flux
(mixture) of silicon and hydrogen, and depositing said flux as a film on a
substrate positioned outside said source of thermal decomposition.
These and other novel features of the invention will be better understood
with reference to the following description of one embodiment thereof,
given by way of example in conjunction with the accompanying drawing which
is a diagrammatic view of a suitable form of apparatus for carrying out
the invention.
The apparatus comprises a vacuum chamber 10 pumped down to a reasonable
vacuum, about 10.sup.-6 torr, via outley pipe 11; a tungsten tube 12
positioned within said vacuum chamber 10 and heated by means of current
leads 13 to a temperature preferably of about 1700.degree. C., which is
well above the decomposition temperature of silane (about 1000.degree.
C.). Silane is fed into said heated tungsten tube 12 via inlet pipe 14
wherein it decomposes into elemental silicon and atomic hydrogen; the flux
of silicon and hydrogen 15 is then deposited on a substrate 16 through
opening 17 in tungsten tube 12. Substrate 16 upon which the hydrogenated
amorphous silicon condenses is placed above tube 12 and can be heated if
desired to a temperature below 500.degree. C., and preferably
225.degree.-325.degree. C., with the film quality at 325.degree. being
optimum. A temperature above 500.degree. C. produces crystalline silicon.
At 1700.degree. C., appreciable hydrogen is generated which reacts with
the silicon condensing on the substrate to yield
amorphous-silicon-hydrogen alloy. At a temperature of 1700.degree. C.,
elemental silicon has an appreciable vapor pressure approximately 1.8
torr; while the vapor pressure of tungsten is essentially negligible,
which negates contamination of the silicon.
As the silane decomposes, the pressure in the vacuum chamber typically
rises from 1.times.10.sup.-6 to about 5.times.10.sup.-4 torr which is the
maximum pressure when heating the tungsten tube by electron beam
bombardment. However, when using other means of heating the tungsten tube,
higher pressures may be used, limited only by the fact that at higher
pressures there is appreciable interaction between molecules in the gas
phase which may or may not be desirable. It is preferable to maintain an
ambient pressure of about 10.sup.-6 to 10.sup.-4 torr in the vacuum
chamber and most preferably 10.sup.-5 to 10.sup.-4 torr.
The substrate, which may be sapphire, fused quartz, silicon, or other
similar materials is placed about 6 inches away from the tube opening 17
in order to promote uniform coatings, and amorphous silicon film growth
rates of about 1 A/sec. However, the distance of the substrate from tube
opening 17 may be varied between 1 and 12 inches to produce film growths
of .about.3 A/sec.
In addition, conventional dopant gases can be added to the silane, if
desired, via inlet pipe 14 prior to decomposition of the silane in heated
tungsten tube 12.
Care is taken to avoid tungsten contamination of the films. This
contamination was inferred from the effect of the temperature of the
tungsten tube on the dark conductivity (.sigma..sub.d) and the
photoconductivity (.sigma..sub.p). When the tungsten was heated to high
temperatures (greater than 2100.degree. C.), .sigma..sub.d was higher and
.sigma..sub.p was lower than when the tungsten was kept at about
1700.degree. C. Further reduction of the tungsten temperature had no
beneficial effect. At a tungsten temperature of 2100.degree. C., the
tungsten contamination was less than 0.1% as determined by a microprobe
analysis.
The base pressure of the system, prior to the silane decomposition, was
.about.1.times.10.sup.-6 torr. During deposition the pressure in the
chamber rose to .about.5.times.10.sup.-4 torr. This was indicative of the
decomposition products of the silane gas. The decomposition products were
collected on a heated substrate. The optimum substrate temperature was
found to be approximately 325.degree. C. Table I gives the growth
conditions and parameters of the hydrogenated amorphous silicon films
including the temperature of the substrate during deposition (Td), growth
rate (R) operating pressure (P), and the resulting thickness of the films
(D).
TABLE I
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Film Substrate Td(.degree.C.)
R(A/sec)
P(torr)
D(A)
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A sapphire 275 1.1 5 .times. 10.sup.-4
1000
B sapphire 325 2.4 5 .times. 10.sup.-4
2400
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Increasing the substrate temperature from 275.degree.-325.degree. C.
decreases the overall hydrogen content in the fims since higher substrate
deposition temperatures reduce the multiply grouped hydrogen sites. The
formation of SiH is less temperature dependent in this range than the
formation of SiH.sub.2 and SiH.sub.3 groups. Similar behavior is observed
for silane films.
Similarly, it has been found that for a fixed deposition temperature
(325.degree. C.) and a fixed partial pressure of hydrogen, the lower
deposition rate produces the larger photocurrent. This is consistent with
a higher percentage of hydrogen incorporated at the lower deposition rate.
On freshly grown films exposed to the atmosphere before measurement of
their temperature dependence, it is found that dark conductivities are
typically 10.sup.-9 to 10.sup.-11 ohms.sup.-1 cm.sup.-1. Thermal
activation energies are 0.75 to 0.80 eV. Though initial growth parameters
yield reproducible dark conductivities and photoconductivities the values
of photoconductivity measured are 10.sup.-2 to 10.sup.-3 less than the
highest values reported for silane films. The power law dependence for
light intensity is between 0.7 and 0.9 for all temperatures and light
intensity levels used.
It is understood that the foregoing detailed description is given merely by
way of illustration and that variations may be made therein without
departing from the spirit of the invention. The "Abstract" given above is
merely for the convenience of technical searchers and is not to be given
any weight with respect to the scope of the invention.
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