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What is claimed is:
1. A plasma reactor, comprising:
a reactor chamber for containing a substrate to be processed and a gas
inlet to permit introduction of an ionizable gas into said chamber;
a variable frequency RF power source;
an RF antenna near said chamber, said antenna connected to said RF power
source for coupling RF power to said ionizable gas to produce a plasma
therefrom;
a power sensor connected to said antenna for sensing at least one of: (a)
transmitted power to said plasma and (b) reflected power to said source;
and
a control circuit connected to a control input of the variable frequency RF
power source and responsive to said power sensor for regulating the
frequency of said variable frequency RF power source so as to effect at
least one of: (a) an increase in said transmitted power and (b) a decrease
in said reflected power.
2. The reactor of claim 1 further comprising a fixed RF match circuit
comprising at least one reactive component connected to said RF antenna.
3. The reactor of claim 1 further comprising a movable RF connector on said
RF antenna, said movable RF connector being translatable along the length
of said RF antenna, said variable frequency RF power source being
connected to said RF antenna at said movable RF connector.
4. The reactor of claim 3 wherein the location of said movable RF connector
and a reactance of said reactive component provide an initial RF match of
said variable frequency RF power source.
5. The reactor of claim 1 further comprising an RF bias source, a wafer
pedestal within said chamber and a bias RF match circuit connected between
said RF bias source and said wafer pedestal.
6. The reactor of claim 5 wherein said RF bias source has a fixed RF
frequency and said bias RF match circuit provides an RF match of said RF
bias source to said wafer pedestal at said fixed RF frequency of said RF
bias source.
7. The reactor of claim 3 wherein:
said reactive component comprises a capacitor connected between one end of
said RF antenna and ground;
an opposite end of said RF antenna is connected directly to ground; and
said movable connector is located between said ends of said antenna.
8. The reactor of claim 1 wherein said control circuit comprises a computer
programmed monitor coupled to said power sensor and to change said
frequency of said variable frequency RF power source so as to effect one
of: (a) minimizing said reflected power and (b) maximizing said
transmitted power.
9. The reactor of claim 8 wherein said computer is programmed to determine
which one of an increase or decrease in frequency minimizes reflected
power and to change the frequency of said variable frequency RF power
source until said reflected power is minimized.
10. The reactor of claim 7 wherein said antenna comprises an inductive coil
antenna and wherein said reactor is an inductively coupled plasma reactor.
11. The plasma reactor of claim 1 wherein said RF antenna comprises a top
coil section overlying said chamber and a side coil section surrounding a
portion of said chamber.
12. The plasma reactor of claim 11 wherein said top and side coil sections
comprise a single winding.
13. The plasma reactor of claim 11 wherein said top and side coil sections
are separately connected to said RF power source.
14. The plasma reactor of claim 1 wherein said RF antenna comprises plural
coil sections, adjacent ones of said plural coil sections being oppositely
wound and having a common connection therebetween.
15. The plasma reactor of claim 14 wherein said common connection is
connected to said RF power source.
16. The plasma reactor of claim 14 wherein there are plural pairs of
adjacent coil sections with plural common connections therebetween,
alternate ones of said common connections being connected to said RF power
source and remaining ones of said common connections being connected to
ground.
17. The plasma reactor of claim 1 wherein said RF antenna comprises plural
concentric windings having a common apex connection and respective ends.
18. The plasma reactor of claim 17 wherein said common apex connection is
connected to one of (a) said RF power source and (b) ground, and wherein
said respective ends are connected to the other one of (a) said RF power
source and (b) ground.
19. The plasma reactor of claim 17 wherein said RF antenna comprises a dome
structure of said plural concentric windings.
20. The plasma reactor of claim 17 wherein said RF antenna comprises a flat
disk of said plural concentric windings.
21. The plasma reactor of claim 17 wherein said RF antenna comprises a
cylindrical structure of said plural concentric windings.
22. The plasma reactor of claim 17 wherein said RF antenna comprises a
cylindrical structure of plural concentric windings underlying one of (a)
a dome structure of plural concentric windings and (b) a disk structure of
plural concentric windings.
23. A method of operating an RF plasma reactor for processing a substrate
having a reactor chamber, an RF antenna adjacent said reactor chamber, and
a gas inlet to permit introduction of an ionizable gas into the chamber,
said method comprising the steps of:
providing RF power from an RF power source having a variable frequency to
the RF antenna to ionize gas within the chamber;
regulating the frequency of said RF power source so as to effect at least
one of: (a) an increase in transmitted power and (b) a decrease in
reflected power.
24. The method of claim 23 wherein said regulating step effects one of: (a)
maximizing said transmitted power and (b) minimizing said reflected power.
25. The method of claim 23 wherein said RF antenna comprises a movable RF
connector translatable along the length of said RF antenna, said RF power
source being connected to said RF antenna at said movable RF connector,
and wherein said reactor further comprises a fixed RF match circuit
comprising at least a reactive element connected to said RF antenna, said
method further comprising initially obtaining an RF match by translating
said movable connector until one of: (a) said transmitted power is
maximized and (b) said reflected power is minimized.
26. The method of claim 23 wherein said reactor comprises a wafer pedestal
in said chamber for supporting said wafer, said method further comprising
applying a bias RF power to said wafer pedestal at a fixed frequency
through an RF match circuit.
27. The method of claim 23 wherein said regulating step comprises
determining which one of an increase and a decrease in the frequency of
said RF source provides a decrease in said reflected power and performing
the one of said increase or decrease in said frequency until said
reflected power reaches a minimum.
28. The method of claim 23 further comprising the step of sensing one of:
(a) transmitted power to said plasma reactor and (b) reflected power to
said source.
29. The method of claim 23 wherein said regulating step so as to effect a
decrease in said reflected power comprises:
(a) initially sampling the reflected power, incrementing said frequency of
said RF power source by a selected amount, secondarily sampling said
reflected power in response to said incremented frequency, and repeating
said incrementing step and said secondarily sampling step until said
secondarily sampled reflected power is greater than said initially sampled
reflected power; and
(b) initially sampling said reflected power, decrementing said frequency of
said RF power source by a selected amount, secondarily sampling said
reflected power in response to said decremented frequency, and repeating
said decrementing step and said secondarily sampling step until said
secondarily sampled reflected power is greater than said initially sampled
reflected power; and
(c) successively repeating steps (a) and (b).
30. The method of claim 23 wherein said regulating step so as to effect an
increase in said transmitted power comprises:
(a) initially sampling the transmitted power, incrementing said frequency
of said RF power source by a selected amount, secondarily sampling said
transmitted power in response to said incremented frequency, and repeating
said incrementing step and said secondarily sampling step until said
secondarily sampled transmitted power is less than said initially sampled
transmitted power; and
(b) initially sampling said transmitted power, decrementing said frequency
of said RF power source by a selected amount, secondarily sampling said
transmitted power in response to said decremented frequency, and repeating
said decrementing step and said secondarily sampling step until said
secondarily sampled transmitted power is less than said initially sampled
transmitted power; and
(c) successively repeating steps (a) and (b). |
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Description |
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BACKGROUND OF THE INVENTION
1. Technical Field
The present invention is related to inductively coupled RF plasma reactors
used in semiconductor processing, of the type employing a coiled antenna
to couple RF power to the plasma reactor chamber, and in particular to
methods for tuning the RF power circuit (including the coil antenna) in
response to impedance changes in the plasma.
2. Background Art
An inductively coupled plasma reactor typically has a coiled antenna
adjacent the plasma reactor chamber and an RF generator connected through
an impedance match circuit and a 50 Ohm cable to the coiled antenna. As
disclosed in U.S. patent application Ser. No. 08/277,531 filed Jul. 18,
1994 by Gerald Yin et al. entitled PLASMA REACTOR WITH MULTI-SECTION RF
COIL AND ISOLATED CONDUCTING LID and assigned to the assignee of the
present application, such an inductively coupled plasma reactor may have a
ceiling over which the coiled antenna is wound. In carrying out
semiconductor processes such as metal etching, as one example, the amount
of power applied to the plasma in the chamber is a critical parameter and
is selected with great care. Any significant deviation from the selected
power level may so change the process as to reduce product yield, as is
well-known to those skilled in the art. For example, the plasma density,
which affects etch rate, is a function of the power coupled to the plasma.
The RF impedance presented by the plasma fluctuates during processing.
Unless the RF match circuit is able to compensate for such fluctuations,
an RF mis-match arises between the RF source and the plasma, so that some
of the RF power is reflected back to the source rather than being coupled
to the plasma. Plasma impedance fluctuations during RF plasma processing
on the order of 5% are typical. In order to enable the RF match circuit to
compensate or follow such fluctuations and maintain an RF match condition,
the RF match circuit includes variable capacitors controlled by electric
motor servos governed by an RF detector circuit. The RF detector circuit
responds to changes in reflected power by changing the variable capacitors
to maintain RF match between the RF source and the plasma.
One problem with this approach is that the electric motor servos and
variable capacitors are expensive and heavy. A related problem is that it
is difficult to compensate for large fluctuations in plasma impedance
using electric motor servos and variable capacitors. A further problem is
that the electric motor servos are relatively slow and unreliable (being
subject to mechanical breakdown). What is needed is a device for instantly
responding to wide fluctuations in plasma impedance to maintain RF match
without employing heavy or expensive mechanical devices or variable
capacitors.
SUMMARY OF THE INVENTION
The invention is embodied in an RF plasma reactor having a reactor chamber
for containing a semiconductor substrate to be processed and gas inlet
apparatus for introducing an ionizable gas into the chamber, a variable
frequency RF power source, an RF antenna near the chamber, the antenna
connected to the RF power source for coupling RF power to the ionizable
gas to produce a plasma therefrom, a power sensor connected to the antenna
for sensing either (or both) transmitted power to the plasma or reflected
power to said source, and a control circuit connected to a control input
of the variable frequency RF power source and responsive to the power
sensor for changing the frequency of the variable frequency RF power
source so as to either increase the transmitted power or decrease the
reflected power, so as to provide an accurate RF match instantly
responsive to changes in plasma impedance.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic diagram of an RF plasma reactor system including the
present invention.
FIG. 2 is a block flow diagram illustrating a frequency control process
carried out by logic in the system of FIG. 1.
FIG. 3 is a block flow diagram illustrating a frequency control process
carried out by logic in an alternative embodiment of the system of FIG. 1.
FIG. 4 illustrates a translatable RF connector employed in the embodiment
of FIG. 1.
FIGS. 5-11 are simplified diagrams of embodiments of the invention in which
the antenna coil has a top section overlying the chamber and a side
section surrounding a portion of the chamber.
FIGS. 12-17 are simplified diagrams of embodiments of the invention in
which the antenna coil consists of plural oppositely wound sections joined
at common points of connection.
FIGS. 18-21 are simplified diagrams of embodiments of the invention in
which the antenna coil consists of plural concentric windings.
DETAILED DESCRIPTION OF THE INVENTION
Referring now to FIG. 1, an inductively coupled RF plasma reactor 10
includes a sealed reactor chamber 12 bounded by a generally cylindrical
conductive (metal) side wall 14 and a dielectric (quartz) dome-shaped
ceiling 16. Gas inlet apparatus 17 coupled to a gas supply provides an
ionizable processing gas into the interior of the chamber 12. A wafer
pedestal 18 in the middle of the chamber supports a semiconductor wafer 20
on an isolated conductive top 22. RF power is coupled to the plasma in the
chamber 10 by a coiled antenna 24 wound around the exterior of the
dome-shaped ceiling 16. The coil 24 is connected to a matched RF source 26
via a 50-Ohm cable 28. In order to control plasma ion energy, the wafer
pedestal base 22 is connected through an RF match circuit 30 and a 50-Ohm
cable 32 to an RF generator 34 and amplifier 36. In one implementation,
the RF match circuit 30 includes a series 100-picoFarad capacitor 40, a
series variable inductor 42 (nominally 3 microHenries) and a variable
shunt capacitor 44 (nominally 1200 picoFarads). However, it should be
understood that these values will vary depending upon specific plasma
reactor design choices, and are readily determined by the skilled worker
for a particular reactor design. A conventional vacuum pump (not shown)
maintains the interior of the chamber 12 at a desired pressure (e.g.,
between 0 and 100 milliTorr.
In accordance with one aspect of the invention, no separate RF match
circuit (such as the RF match circuit 30) is required to match the RF
source 26 to the load. Instead, a match is achieved by employing the coil
antenna 24 itself as a fixed RF match reactance. For this purpose, the
power cable from the RF source 26 is connected through a slidable
conductor attachment A (FIG. 4) to an intermediate point P (FIG. 1) on the
coil antenna 24. The point P divides the coil antenna 24 into two
windings, a top winding 24a and a bottom winding 24b. The end of the top
winding 24a is grounded through a high voltage capacitor 46 to an RF
shield 48 surrounding the coil antenna 24. In the illustrated
implementation, the high voltage capacitor 46 was 500 picoFarads. The end
of the bottom winding 24b is grounded directly to the RF shield 48. A
perfect RF match is achieved by sliding the slidable attachment A to vary
the location of the attachment point P along the conductor of the coil
antenna 24 while continuously measuring RF power reflected back to the RF
source until the reflected RF power is minimized. For this purpose, the
skilled worker may connect a conventional power meter such as the
reflected power sensor 50 at the output of the RF source 26. Such a
conventional power meter typically provides continuous measurements of
both reflected power and transmitted power. As is well-known to those
skilled in the art, such a power meter is readily implemented with a
conventional RF dual direction coupler circuit. It should be noted that
the worker may have to try sliding the attachment A in both directions to
determine which direction is the correct one in which to move the slidable
attachment A.
Of course, once a plasma is ignited within the chamber 12, the RF match
condition may be lost as the plasma impedance fluctuates. Therefore, it is
necessary to compensate for such fluctuations to maintain RF match between
the RF source 26 and the load or chamber 12. For this purpose, the RF
source 26 employs a conventional variable-frequency RF generator 52 having
a frequency control input 54 and power output 56 with an amplifier 57 and
a computer 58. The computer 58 monitors the reflected power level measured
by the reflected power sensor 50 and applies a control signal to the
frequency control input 54 of the variable-frequency RF generator 52. In
one implementation the RF generator is a voltage-controlled oscillator and
the computer 58 changes the output frequency of the generator 52 by
varying the voltage applied to the control input 54. In other
implementations of the invention, any device capable of performing the
above-described control tasks of the computer 58, such as a programmed
logic array or an analog control circuit, may be employed in lieu thereof.
The computer 58 (which is preferably a conventional microprocessor with a
programmable read-only memory) is programmed to vary the frequency of the
RF generator 52 so as to continuously minimize the amount of reflected
power measured by the reflected power sensor 50. One algorithm with which
the computer 58 may be programmed to accomplish this purpose is
illustrated in FIG. 2. The successive steps of the algorithm of FIG. 2 are
performed serially during successive execution cycles of the computer 58.
First, the frequency of the RF generator 52 is incremented (increased by a
predetermined amount) and the reflected RF power is then sampled (block 60
of FIG. 2). The computer 58 then makes a decision (block 62 of FIG. 2): If
the current sampled reflected RF power is less than the previous sample
(YES branch of block 62), then the incrementing and sampling step of block
60 is repeated. Otherwise (NO branch of block 60), the next step (block
64) is to decrement the frequency and again sample the reflected RF power.
Again, the computer makes a decision (block 66): If the reflected RF power
has decreased (YES branch of block 66), then the decrementing and sampling
step of block 64 is repeated. Otherwise, (NO branch of block 66), the
algorithm returns to the incrementing and sampling step of block 60.
The result is that in response to any large fluctuation in plasma
impedance, either the frequency incrementing step of block 60 will be
repeated many times until RF match is reached or else the frequency
decrementing step of block 64 will be repeated many times until RF match
is reached. At RF match, the algorithm dithers between alternating
frequency decrementing and frequency incrementing steps.
In the illustrated implementation, the nominal frequency of the RF source
26 was 2.0 MHz. Typical plasma impedance fluctuations require a 5%
increase or decrease in that frequency to maintain RF match. Such a
fractional change in frequency does not appreciably affect the processing
characteristics of the plasma reactor. The computer 58 increments or
decrements the output frequency of the RF generator 52 preferably in 0.01
MHz steps, so that the entire range of frequency variations is covered in
100 execution cycles of the computer. Since the computer 58 may be
expected to operate at MegaHertz rates, the response to any plasma
impedance fluctuations is virtually instantaneous, compared with the slow
response of prior art variable capacitors and electric motor servos.
The invention thus eliminates not only the need for variable capacitors and
electric motor servos in the RF match circuit, but also eliminates the
entire RF match circuit itself, exploiting the coil antenna 24 to obtain
the needed reactance for an RF match between the chamber 10 and the RF
source 26.
In operation, a nominal or initial RF match is obtained prior to plasma
ignition by moving the connection point P until reflected RF power
measured by the sensor 50 is minimized. Then, after the plasma is ignited
in the chamber 10, the computer 58 controls the frequency of the RF
generator 52 to compensate for the plasma impedance and any changes in
plasma impedance. Preferably, if it is determined, for example, that an RF
match is expected to obtain at a nominal output frequency of the RF source
26 of 2.0 MHZ, then frequency of the RF source 26 is set at slightly below
the expected match frequency of 2.0 MHz (e.g., 1.7 MHz) when the plasma if
ignited, so that the computer 58 increases the frequency until RF match
(minimum reflected RF power) is obtained.
In the illustrated embodiment, the coil antenna 24 had an inductance of 10
microHenries and the attachment point P was located such that the ratio of
the number of windings in the top winding 24a and the bottom winding 24b
was approximately 8:2.
While the invention has been described with reference to an embodiment in
which the computer 58 samples the reflected power measured by the sensor
50 and strives to minimize that power in the algorithm of FIG. 2, in an
alternative embodiment the computer samples transmitted power measured by
the sensor 50 and strives to maximize that measurement. In this
alternative embodiment, the algorithm of FIG. 2 is modified to change the
"decrease?" inquiries of steps 62 and 66 to "increase?" inquiries, as
illustrated in FIG. 3. Thus, in FIG. 3, the frequency is incremented and
the transmitted power is sampled (block 70 of FIG. 3). If this results in
an increase in transmitted power (YES branch of block 72) then the step is
repeated. Otherwise (NO branch of block 72), the frequency is decremented
and the transmitted power sampled thereafter (block 74). If this results
in an increase in transmitted power (YES branch of block 76, then this
step is repeated. Otherwise (NO branch of block 76), the process returns
to the initial step of block 70.
While the invention has been described with reference to an embodiment in
which the RF match circuit is eliminated, a separate RF match circuit may
be connected at the output of the RF source 26, although no variable
reactive components (e.g., variable capacitors) would be required.
FIG. 4 illustrates an implementation of the movable attachment point A,
which is a conductive ring 100 around the conductor of the coil antenna
24, the ring 100 maintaining electrical contact with the antenna 24 but
being sufficiently loose to permit translation in either direction along
the length of the coil antenna 24.
Referring to FIG. 5, the coil antenna 24 may have a multi-radius dome
shape, the slide connection conductive ring 100 being on or near the
bottom winding of the coil antenna 24. Referring to FIG. 6, the coil
antenna 24 may comprise a flat or disk-shaped top portion 610 overlying
the chamber and a cylindrical side portion 620 surrounding a portion of
the chamber. Referring to FIG. 7, the coil antenna 24 may comprise a lower
cylindrical portion 710, an intermediate dome-shaped corner 720 and a flat
or discoid top portion 730. Referring to FIG. 8, the coil antenna 24 may
comprise a lower truncated conical portion 810 and a flat discoid top 820.
Referring to FIG. 9, the coil antenna of FIG. 6 may be divided so that the
discoid top winding 610 and the cylindrical winding 620 are separately
connected to the R.F. source 26. In the implementation of FIG. 9, the top
winding 610 is connected to the R.F. source 26 by a first slide connection
ring 100a on or near the outermost winding thereof, while the cylindrical
winding is connected to the R.F. source 26 by a second slide connection
ring 100b on or near the top winding thereof. Referring to FIG. 10, the
coil antenna of FIG. 7 may be divided so that the cylindrical portion 710
is connected at the top winding thereof by the first slide connector ring
100a to the R.F. source 26 while the dome and discoid portions 720, 730
are connected to the R.F. source 26 at the outermost winding thereof by
the second slide connector ring 100b. Referring to FIG. 11, the embodiment
of FIG. 8 may be divided so that the conical winding 810 is connected on
or near its top winding to the R.F. source 26 by the first slide connector
ring 100a while the discoid winding 820 is connected at or near its
outermost winding to the R.F. source 26 by the second slide connector ring
100b. The embodiments of FIGS. 5-11 incorporate inventions disclosed in
U.S. application Ser. No. 08/389,899 filed on Feb. 15, 1995 by Hiroji
Hanawa et al. and entitled "RF Plasma Reactor with Hybrid Coil Inductor
and Multi-Radius Dome Ceiling" and assigned to the present assignee, the
disclosure of which is incorporated herein by reference.
Referring to FIG. 12, the coil antenna 24 may be divided into two
oppositely wound sections 1210, 1220 connected at a common point A to the
RF source 26 by the slidable connector ring 100, while the top and bottom
ends of the coil antenna 24 are grounded. The two sections 1210, 1220 are
oppositely wound so that the magnetic flux from each section reinforces
that of the other. Referring to FIG. 13, the common connection point of
two sections 1310, 1320 is fixed while the connections near the top and
bottom ends of the coil antenna 24 comprise the two slidable connection
rings 100a, 100b, respectively. While the embodiments of FIGS. 12 and 13
are dome-shaped windings, FIGS. 14 and 15 illustrate cylindrical-shaped
windings corresponding to variations of the embodiments of the embodiments
of FIGS. 12 and 13, respectively. FIG. 16 is a perspective view of the
embodiment of FIG. 15. While each of the embodiments of FIGS. 12-16 is
illustrated as having two coil sections with a single common connection
point, the perspective view of FIG. 17 illustrates how the same structure
may be repeated to provide three (or more) sections 1710, 1720, 1730, each
pair of adjacent sections being oppositely wound and having a common
connection point (1740, 1750, 1760, 1770) therebetween, alternate common
connection points 1750, 1770) being connected to the RF source 26 and
remaining common connection points (1740, 1760) being connected to ground.
The embodiments of FIGS. 12-17 incorporate inventions disclosed in U.S.
application Ser. No. 08/277,531 filed Jul. 18, 1994 by Gerald Z. Yin et
al. and entitled "Plasma Reactor with Multi-Section RF Coil and Isolated
Conducting Lid" and assigned to the present assignee, the disclosure of
which is incorporated herein by reference.
Referring to FIG. 18, the coil antenna 24 may comprise plural (e.g., three)
concentrically wound conductors 1810, 1820, 1830 having a common apex
point 1840 connected to ground and three ends 1810a, 1820a, 1830a
symmetrically disposed around the outer circumference of the coil antenna.
In the implementation of FIG. 18, the three ends 1810a, 1820a, 1830a are
connected to the RF source 26 by three slide connector rings 100a, 100b,
100c, respectively. While the embodiment of FIG. 18 is a flat discoid
coil, FIG. 19 illustrates how the plural concentric windings may have a
cylindrical shape. FIG. 20 illustrates how the embodiments of FIGS. 18 and
19 may be combined to provide a flat top discoid winding 2010 and a
cylindrical side winding 2020. The embodiment of FIG. 21 comprises a
dome-shaped top 2110 consisting of plural concentric windings. As
illustrated in FIG. 21, the dome-shaped top 2110 may be combined with the
cylindrical side winding 2020 of FIG. 20. The embodiments of FIGS. 18-21
incorporate inventions disclosed in U.S. application Ser. No. 08/332,569
filed Oct. 31, 1994 by Xue-Yu Qian et al. entitled "Inductively Coupled
Plasma Reactor with Symmetrical Parallel Multiple Coils Having a Common RF
Terminal" and assigned to the present assignee, the disclosure of which is
incorporated herein by reference.
While the invention has been described in detail by specific reference to
preferred embodiments, it is understood that variations and modifications
thereof may be made without departing from the true spirit and scope of
the invention.
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