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Claims  |
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We claim:
1. A sputtering apparatus comprising an anode, a target means arranged in
opposition to said anode which is biased as a cathode, means for
generating a magnetic field, and a shield disposed in proximity to said
target means, said target means including a substantially flat surface at
an outer marginal area thereof in proximity to said shield ring.
2. A sputtering apparatus according to claim 1, wherein said means for
generating a magnetic field and said shield is arranged around said target
means, wherein said substantially flat surface is formed at an edge of an
outer peripheral portion of said traget means.
3. A sputtering apparatus according to claim 1, wherein said target means
is formed by an annular member and has a substantially right-angle
triangular cross-sectional configuration, with an upper end part of the
triangle forming the substantially flat surface.
4. A sputtering apparatus comprising: an anode to which is applied a
positive potential for producing an electric field having a component
normal to a target;
a cathode in opposition to said anode to which is applied a negative
potential which functions as the target ions to be sputtered, said target
having an outer peripheral portion which is flat and which defines a
non-vertically disposed outside periphery;
means disposed around the outside periphery of said target for producing a
magnetic field which functions to confine electrons emitted between the
anode and the target; and
a shield interposed in a space disposed between the magnets and the target.
5. A sputtering apparatus in accordance with claim 1, wherein said target
is an annular member and has a cross-sectional configuration having a
first inclined section, a first horizontally disposed section having a
first end joined to the first inclined section and a second end, a second
inclined section having a first end joined to the second end of the first
horizontally disposed section and a second end and a second horizontally
disposed section joined to the second end of the second inclined section,
said second horizontally disposed section being said flat outer peripheral
portion.
6. A sputtering apparatus comprising:
an anode to which is applied a positive potential for producing an
electrical field having a component normal to a target;
a cathode to which is applied a negative potential which functions as the
target to be sputtered, said target being conical, disposed around said
anode and, having an interior portion which is substantially flat and a
peripheral portion which defines a substantially flat non-vertically
disposed surface;
means for producing a magnetic field disposed in proximity to said target
which functions to confine electrons emitted between the anode and the
target; and
a shield means facing said substantially flat non-vertically disposed
surface means.
7. A method for depositing atoms sputtered from a target, onto one or more
semiconductor wafers in which the occurrence of an electrical discharge
between the peripheral portion of the target and a shield is minimized
comprising:
providing the peripheral portion of the target with a substantially flat
surface which lessens the concentration of an electrical field between the
peripheral portion of the target and the shield during sputtering; and
depositing the atoms sputtered from the target onto one or more of the
semiconductor wafers whereby the
depositing of an undesired concentration of atoms on the one or more wafers
is minimized.
8. The method of claim 7 wherein said target is conical.
9. The method of claim 7 wherein said target is flat.
10. A sputtering apparatus comprising:
an anode to which is applied a positive potential for producing an
electrical field having a component normal to a target;
a planar cathode opposed to said anode to which is applied a negative
potential which functions as a target to be sputtered, said target having
an interior portion which is substantially flat and a peripheral portion
which is chamfered with respect to the horizontal to define a
substantially flat peripheral surface;
means disposed in proximity to said target for producing a magnetic field
which functions to confine electrons emitted between the anode and the
target; and
a shield facing the peripheral surface.
11. A target for sputtering having a target surface and a flat peripheral
surface inclined at an obtuse angle measured within the target with
respect to the target surface of the target, the peripheral surface being
adjacent to a shield ring when the target is in use.
12. A target according to claim 11, wherein the target is annular and has
at least one inner surface inclined to the longitudnal axis of the target,
the at least one inner surface being the target surface.
13. A target according to claim 12, wherein the peripheral surface is
substantially perpendicular to the longitudinal axis of the target.
14. A target according to claim 12, wherein the peripheral surface is
between the target surface and a cylindrical outer surface of the target.
15. A target according to claim 13, wherein the peripheral surface is
between the target surface and a cylindrical outer surface of the target.
16. A target according to claim 11 wherein the target is planar, the target
surface is a planar surface of the target, and the peripheral surface is
between the target surface and a side surface of the target.
17. A sputtering process, comprising applying a voltage between an anode
and a target forming a cathode, thereby to generate a glow discharge of
free ions, and
guiding the free ions onto the target by a means for producing a magnetic
field, thereby to generate free atoms, the free atoms travelling to a
substrate,
wherein there is a shield ring between the means for producing a magnetic
field and the target, and the target has a target surface and a flat
peripheral surface inclined at an obtuse angle measured within the target
with respect to the target surface, the peripheral surface being adjacent
to the shield ring when the target is in use.
18. A sputtering process in accordance with claim 17 wherein the target is
annular and has at least one inner surface inclined to the longitudinal
axis of the target, the at least one inner surface being the target
surface.
19. A process in accordance with claim 12 wherein the peripheral surface is
substantially perpendicular to the longitudinal axis of the target.
20. A sputtering process in accordance with claim 18 wherein the peripheral
surface is between the target surface and a cylindrical outer surface of
the target.
21. A sputtering process in accordance with claim 19 wherein the peripheral
surface is between the target surface and a cylindrical outer surface of
the target.
22. A sputtering process in accordance with claim 17 wherein the target is
planar, the target surface is a planar surface of the target and the
peripheral surface is between the target surface and a side surface of the
target.
23. A sputtering apparatus having:
a target for sputtering having a target surface and a flat peripheral
surface inclined at an obtuse angle measured within the target with
respect to the target surface of the target, the peripheral surface being
adjacent to a shield ring when the target is in use, said target forming a
cathode;
an anode in opposition to the cathode; and
a magnet and a shield ring located near the target such that the shield
ring is adjacent the peripheral surface of the target.
24. A sputtering apparatus in accordance with claim 23 wherein the target
is annular and has at least one inner surface inclined to the longitudinal
axis of the target, the at least one inner surface being the target
surface.
25. A sputtering apparatus in accordance with claim 24 wherein the
peripheral surface is substantially perpendicular to the longitudinal axis
of the target.
26. A sputtering apparatus in accordance with claim 24 wherein the
peripheral surface is between the target surface and a cylindrical outer
surface of the target.
27. A sputtering apparatus in accordance with claim 25 wherein the
peripheral surface is between the target surface and a cylindrical outer
surface of the target.
28. A sputtering apparatus in accordance with claim 23 wherein the target
is planar, the target surface is a planar surface of the target and the
peripheral surface is between the target surface and a side surface of the
target. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
The present invention relates to a sputtering apparatus and, more
particularly, to a magnetron type sputtering apparatus which is adapted to
prevent inferior sputtering attributable to bumping or sudden boiling.
In order to enhance the performance of semi-conductor devices, P-N
junctions of the semiconductor devices have become shallower and patterns
have become finer. Additionally, it has become necessary to adopt aluminum
alloy materials such as, for example, Al-Si and Al-Si-Cu, and high melting
metal materials such as, for example, Mo, W, and Pt as electrode wiring
materials. However, such materials are difficult to treat with
conventional vacuum evaporators.
Previously, sputtering apparatus have been principally utilized for
thin-film ICs and such apparatus are difficult to apply to the formation
of electrodes of semiconductor devices since, for example, the deposition
rate is relatively low and there is a rise in the substrate temperature
resulting in a damaging of the semiconductor device.
However, in an attempt to solve the above-noted problems, in recent years,
a magnetron type sputtering apparatus has been developed which utilizes an
orthogonal electromagnetic el field. Magnetron type sputtering apparatus
have been put into practical use in electrode wiring steps of
semiconductor devices.
A magnetron type sputtering apparatus may be classified into various types
depending upon the arrangements of the magnets and the shapes of the
targets. However, any magnetron type sputtering apparatus is based upon
the principal that a plasma moving in conformity with the Lorentz equation
is confined into a local space in a vicinity of a target by utilizing an
orthogonal electromagnetic field. More particularly, electrons execute a
cycloid motion on the target and collide against gas molecules resulting
in a generation of plasma of a high density. Since the electrons are
constrained by the magnetic field, it is possible to prevent a temperature
increase and damage to the semiconductor device due to the bombardment of
the wafer with electrons.
Generally, a magnetron type sputtering apparatus is constructed so that, in
a vicinity of a target or cathode, disposed in opposition to an
anode, magnets (permanent magnets or electromagnets) are disposed to form
the electromagnetic field near the target, with the plasma being confined
on the target by utilizing the cycloid motion of the electrons in order to
obtain a high sputtering rate.
An extensively used sputtering apparatus known as a "Sputter System 3125H",
manufactured by Varian, Inc, is based on the principle that argon gas,
introduced in a vacuum chamber of the apparatus, is ionized and a target
or film material is struck by the ions. A ring magnetron or a S-GUN, is
employed for ionizing the argon and accelerating the ions, with the S-GUN
forming a plasma discharge having a doughnut-shape. The plasma discharge
is established by an electric field and a magnetic field, and the argon
molecules are ionized and the target is bombarded with the ions by the
plasma discharge. Since the plasma is formed in a doughnut shape just on
the target, most of the secondary electrons are confined within the
plasma.
In the above-noted system, the S-GUN is incorporated into a chamber with
the system also including a planetary type substrate jig and a rotating
mechanism, along with a liquid nitrogen cold trap, a diffusion pump, an
ion gauge, a main valve, a variable orifice for regulating the argon gas,
and a substrate heater.
In use, a substrate is set on a member of the planetary type substrate jig
and, for example, up to three members may be put in the chamber. The
chamber is then closed or sealed by a door and a preliminary evacuation is
begun, with the evacuation being effected by a mechanical pump.
Subsequently, the diffusion pump is actuated to begin a main evacuation of
the chamber. The members of the planetary type substrate jig revolve
around the S-GUN while revolving around their own axes and, when a degree
of vacuum of the order to 10.sup.-6 Torr has been reached, the heater in
the chamber may be turned "on" to attain a set temperature. After a
thermal equilibrium has been reached, a RF etching is performed; however,
the heating and etching processes are optional. Thereafter, the argon gas
is introduced, and the argon gas is maintained in the chamber at a
pressure of up to the order to 10.sup.-3 Torr, whereupon the sputtering
begins.
In the above noted system, since a distance from the S-GUN to the substrate
is about 50 cm, the influence of the secondary electrons is substantially
avoided and a favorable uniformity and step coverage are attained by a
good angle of incidence at which the target molecules are deposited on the
substrate. Furthermore, the jig of the substrates revolves on its own axis
and also around the S-GUN so as to further improve the uniformity and step
coverage. When the deposition on the substrate has ended, dry nitrogen is
introduced to restore the interior of the chamber to atmospheric pressure
thereby terminating one cycle of operation.
SUMMARY OF THE INVENTION
The aim underlying the present invention essentially resides in providing a
sputtering apparatus which prevents a bumping or sudden boiling of a
target material from a marginal area of the target.
Another object of the present invention resides in providing a sputtering
apparatus which minimizes if not avoids a generation of a spark between a
marginal end of the target and a shield ring.
Yet another object of the present invention resides in providing a
sputtering apparatus which considerably lengthens a useful lifetime of the
target.
A still further object of the present invention resides in providing a
sputtering apparatus which avoids any appearance of splattering.
Yet another object of the present invention resides in providing a
sputtering apparatus which enables an efficient fabrication of
semiconductor devices and which reduces the number of defective
semiconductor devices produced as well as the overall production costs.
In accordance with advantageous features of the present invention, a
sputtering apparatus is provided which includes an anode, a target as a
cathode arranged in opposition to the anode, along with magnets and a
shield ring which are disposed in positions near the target. An end
portion of the target on a side nearer to the shield ring is formed so as
to be flat.
Advantageously, in accordance with further features of the present
invention, the magnets and shield ring are arranged around the target, and
an edge of an outer peripheral end part of the target is formed flat.
With an annular target, in accordance with the present invention, a section
of the target is substantially in the shape of a right angled triangle and
an upper end part thereof is formed flat.
These and other objects, features, and advantages of the present invention
will become more apparent from the following description when taken in
connection with the accompanying drawings which show, for the purpose of
illustration only, several embodiments in accordance with the present
invention:
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a cross sectional view of a sputter gun portion of a prior art
sputtering apparatus;
FIG. 2 is a cross sectional view, partially broken away, of a target of the
sputtering apparatus of FIG. 1;
FIG. 3 is a partially schematic view of a sputtering apparatus constructed
in accordance with the present invention;
FIG. 4 is a cross sectional view, on an enlarged scale, of a sputter gun of
the sputtering apparatus of the present invention;
FIG. 5 is a cross sectional view, partially broken away, of a target
constructed in accordance with the present invention; and
FIG. 6 is a schematic cross sectional view of another embodiment of a
sputter gun constructed in accordance with the present invention.
DETAILED DESCRIPTION
Referring now to the drawings wherein like reference numerals are used
throughout the various views to designate like parts and, more
particularly, to FIGS. 1 and 2, according to these figures, a sputter
apparatus corresponding to the above noted "Sputter System 3125H" includes
an aluminum annular target 2 forming a cathode, disposed around a
centrally located anode 1, with the target being supplied with a -500 to
-600V and the anode 1 having an applied voltage of a +24V. Permanent
magnets or electromagnets 3 are disposed around the target 2 so as to form
an orthogonal electromagnetic field on the target 1, with a grounded
shield ring being interposed between the magnets 3 and the target 2.
Electrons, emitted by a glow discharge rising between the anode 1 and
target 2, execute a cycloid motion due to the orthogonal electromagnetic
field, and a plasma, generated by raising the density of collisions
thereof, is confined to the target 2. In this manner, Al atoms, which are
generated or sputtered by the collisions of the positive ions in the
plasma against a target 2, are quickly generated so that an enhancement in
the disposition rate of Al on the wafer or substrate and an enhancement in
the purity thereof can be realized.
In the sputtering apparatus of FIGS. 1 and 2, the Al atoms sputtered from
the target 2 are deposited on the wafer (not shown) and are also scattered
toward the magnets 3 around the target, with the atoms tending to adhere
thereto. A shield ring 4 is disposed between the target 2 and the magnets
3 so as to prevent a deposition of the Al atoms on the magnets 3. However,
the Al atoms are deposited on the surface of the shield ring 4 and the
minute gaps thereof. When a large quantity of Al is deposited, the
orthogonal electromagnetic field formed by the magnets 3 is affected and
the orthogonal electromagnetic field becomes incapable of holding its
initial state due to the deterioration of the permanent magnets attributed
to changes. For these reasons the cycloid motion of the electrons
fluctuates and an end portion of the target 2 near the outer periphery
thereof becomes sputtered.
Consequently, the margin or end portion of the target becomes somewhat
roughened upon the occurrence of the sputtering. In particular a margin
2a, in the shape of an edge, is formed with a large number of roughened
parts on its surface. Therefore, an electric field concentration may arise
at the margin 2a and sparks are likely to appear between the margin 2a and
the proximate shield ring 4 which is held at a ground potential. When the
electric field concentration exceeds a predetermined limit, a spark arises
and a bumping or sudden boiling takes place from the target margin 2a due
to the impact of the spark. When a bumped Al atom adheres to the wafer
surface, the Al bulges or splatters thereby resulting in a wiring short
circuit developing.
Consequently, with a prior art system employing a target 2 with a marginal
area 2a which becomes roughened, it is necessary to exchange the target
quite frequently and, the short lifetime of the target 2 can result in
problems such as a low available precentage of semiconductor devices as
well as a high cost of the target.
As shown in FIG. 3, in accordance with the present invention, a
substantially spherical or global vacuum chamber 12 and chiller 11 are
mounted on a base 10, with a diffusion pump (not shown) being disposed in
the base 10 for evacuating an interior of the vacuum chamber 12 to, for
example, a high vacuum of, for example, 10.sup.-7 Torr. A rotary
mechanical pump 14 communicates with the base 10 through a pipe 13, and an
argon (Ar) gas source 100 is connected to the chamber 12 through a tube 15
so that argon gas can be introduced into the chamber 12, with valves 16,
17, 18 being provided for controlling the communication between the pump
14, gas source 100, and chamber 12.
A plurality of sputter guns 19, for example, three, in the illustrated
embodiment, are disposed within the vacuum chamber 12, and wafers 20,
representing objects to be processed, are supported at an upper part of
the chamber by a planetary arrangement generally designated by the
reference numeral 21, with heaters 22 being arranged near the sputter guns
19. The planetary arrangement 21 includes a rotary plate 23 which revolves
or rotates about its center axis, with a plurality of individual rotary
plates 24 being mounted at a periphery of the rotary plate which revolve
around their respective center axes. The plurality of wafers 20 are
supported on a surface of each of the rotary plates 24 as the rotary
plates are rotated around their center axes and, consequently, a planetary
rotary motion results wherein the planetary rotary plate 24 revolves along
its own center axis while revolving around the rotary plate 23.
As shown in FIG. 4, the sputter gun 19 includes a disc-like shield base 26
which is cantilievered in the chamber 12 by an arm 25. A base plate 27 is
disposed over the shield base 26 and is supported in an insulated manner.
An anode 28 extends through a central portion of the shield base 26 and
base plate 27 and is supported so as to be insulated from the shield base
26 and base plate 27. An anode disc is secured to an upper end of the
anode 28, and a coolant pipe 130 is provided for supplying, for example,
water to a hollow lower part of the anode 28. An electric connection is
made so as to apply about a +24 V to the anode 28. An annular target,
generally designated by the reference numeral 30, is disposed on the base
plate 27 surrounding the anode 28. Magnets 32 such as, for example,
permanent magnets are disposed around the target 30 by a bracket 31. The
target 30 is fashioned of a silicon material containing 2% of aluminum.
As shown most clearly in FIG. 5, the target 30 has a sectional shape of a
right angle triangle, with an oblique line being formed with a step.
Preferably, the target 30 has an outside diameter A of 131.0 mm and a
height B of 22.4 mm. An end part 30a at the outermost and highest position
of the target 30 is constructed so that its upper edge 30b defines a flat
surface. A width C of the upper edge 30b is preferably equal to 2.0.+-.0.5
mm. The target 30 is constructed as a cathode by applying a voltage of a
-500--600 V thereto through the base plate 27 and the magnets 32 are such
that a plurality of magnets are circumferentially arrayed in two stages,
namely, upper and lower stages. The magnets 30 along with an electric
field established by the voltage on the target 30 form an orthogonal
electromagnetic field on the target 30 in the vicinity of the inner slant
surface. A coolant pipe 33 is connected to the bracket 31 supporting the
magnets 32 for supplying, for example, cooling water.
As shown in FIG. 4, a shield wall 34, having a substantially L-shaped cross
section, is mounted on the outer periphery of the shield base 26 so as to
surround the magnets 32, and a sputter shield ring 35 is fixed to an inner
edge of the shield wall 34 so as to enable the shield ring 35 to extend in
a downward direction. A shield ring 36 is integrally mounted on a lower
surface of the sputter shield ring 35 so as to intervene or be interposed
between the target 30 and the magnets 32. The shield ring 35 and 36, etc
are grounded through the shield wall 34 and the shield base 26 and are
thus held at a ground potential (0 V).
The sputtering apparatus of the present invention operates in the following
manner:
First wafers 20 are set on the planetary arrangement 21, while the target
30, of a material to be sputtered, for example, Al containing 2% of Si, is
set on each base plate 27. In this condition, the diffusion pump, the pump
14, etc are operated to bring the interior of the vacuum chamber 12 to a
vacuum pressure of about 10.sup.-7 Torr and the required voltages are
applied to the anode 28 and the target 30. Argon gas is introduced into
the chamber 12 to set the interior thereof at 10.sup.-3 Torr and a plasma
is generated in each sputter gun 19 to start the sputtering operation.
More particularly, when the anode 28 has a +24 V applied thereto and the
target 30 has a -500--600 V applied thereto, a glow discharge arises
therebetween and then the electrons conduct a cycloid motion on the target
30 under the action of the orthogonal electromagnetic field based on the
magnets 32, and the plasma generated by raising the density of collisions
thereof is confined to the target 30. Therefore, the density at which the
argon ions and the plasma collide against the target 30 is also increased,
and the aluminum atoms are sputtered from the target 30 relatively
quickly. Accordingly, the aluminum atoms fly from the sputter gun 19 to
the upper part of the chamber 12 and are desposited on the surfaces of the
wafers 20. By this arrangement, the deposition rate is enhanced and a high
purity is obtained.
The sputtered aluminum atoms adhere, not only to the wafers 20 but also on
each shield ring 36 by being scattered laterally. When the intensity of
the orthogonal electromagnetic field has been lowered due to the adhesion
of the aluminum atoms on the shield rings 36 and when the field changes
with time, the cycloid motion fluctuates and the argon ions collide
against the target 30 at the outer peripheral end part thereof so as to
result in a sputtering. However, in the illustrated example, the target 30
has an end part 30a which is formed of a flat surface so that even when
the end part is roughened by the sputtering, it is always held in a round
shape without becoming acute. Accordingly, an electric field concentration
does not occur in the end part 30a of the target 30 and a spark is not
generated or does not appear between the shield ring 36 and the target 30.
Consequently, the bumping of aluminum does not arise and the aluminum
bulges or splatters are not formed so that no wire short circuit appears
on the surface of the wafer 20.
As a result of the above features, the target 30 can continue the
sputtering even when the end portion thereof is roughened. The lifetime of
the target 30 is significantly increased which increases the number of
semiconductor devices that can be processed without target replacement
while reducing the fabrication costs of such semiconductor devices. The
reason for this is that, even when the sputtering rate is raised, the
period of time in which the target 30 consumes is longer than that in the
prior art and, consequently, the frequency of exchange of targets is less.
With a target 30 whose end part 30a is formed as a flat surface, it is also
possible for both edges of the flat surface to be rounded. Needless to
say, when the dimensions of the outside diameter and the height of the
target 30 differ, the width dimension C of the flat surface becomes
correspondingly different and, when the material of the target 30 is
something other than aluminum, the value also differs.
FIG. 6 provides an example of a planar type sputtering apparatus wherein a
base plate 40 has installed or mounted thereon a flat target 41 with an
anode 42 being arranged around and over the target 41 and in proximity
thereto. Magnets 43 such as, for example, permanent magnets or
electromagnets, are embedded in the base plate 40 and form an orthogonal
electromagnetic field on the target 41, with a shield ring 44 being
provided.
In the sputtering apparatus of FIG. 6, electrons are caused to perform a
cycloid motion on the target 41 by the glow discharge between the anode 42
and the target 41, whereupon the target 41 is bombarded with argon ions in
a plasma so as to sputter aluminum atoms. Also, a peripheral end part of
the target 41, especially an upper peripheral edge 41a, proximate to the
anode 42, is cut and formed so as to define a flat surface. Thus, even
when the end part of the target 41 has been roughened by sputtering, an
electric field concentration does not arise and the appearance of a spark
between the end part of the target 41 and the shield ring 44 is prevented
so as to effectively prevent a bumping or sudden boiling. As a result the
lifetime of the target 41 is prolonged and there is an increase in the
number of semiconductor devices manufactured as well as a reduction in
overall manufacturing costs.
In accordance with the features of the present invention, a sputtering
apparatus is provided wherein an end part of a target 30 or 41 is formed
with a flat surface 30b or 41a so that no acute angled part exists on the
target. Therefore, even when the target end part is roughened by
sputtering, the occurrence of an electric field concentration in the end
part of the target 30 or 41 is prevented as well as the appearance of
sparks so that a bumping and the attendant splatters are prevented.
While we have shown and described several embodiments in accordance with
the present invention, it is understood that the same is not limited
thereto but is susceptible of numerous changes and modifications as known
to one having ordinary skill in the art and we therefore do not wish to be
limited to the details shown and described herein, but intend to cover all
such modifications as are encompassed by the scope of the appended claims.
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