WO2004114461A2 - Plasma production device and method and rf driver circuit with adjustable duty cycle - Google Patents
Plasma production device and method and rf driver circuit with adjustable duty cycle Download PDFInfo
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- WO2004114461A2 WO2004114461A2 PCT/US2004/019931 US2004019931W WO2004114461A2 WO 2004114461 A2 WO2004114461 A2 WO 2004114461A2 US 2004019931 W US2004019931 W US 2004019931W WO 2004114461 A2 WO2004114461 A2 WO 2004114461A2
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- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05H—PLASMA TECHNIQUE; PRODUCTION OF ACCELERATED ELECTRICALLY-CHARGED PARTICLES OR OF NEUTRONS; PRODUCTION OR ACCELERATION OF NEUTRAL MOLECULAR OR ATOMIC BEAMS
- H05H1/00—Generating plasma; Handling plasma
- H05H1/24—Generating plasma
- H05H1/26—Plasma torches
- H05H1/32—Plasma torches using an arc
- H05H1/34—Details, e.g. electrodes, nozzles
- H05H1/36—Circuit arrangements
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- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05H—PLASMA TECHNIQUE; PRODUCTION OF ACCELERATED ELECTRICALLY-CHARGED PARTICLES OR OF NEUTRONS; PRODUCTION OR ACCELERATION OF NEUTRAL MOLECULAR OR ATOMIC BEAMS
- H05H1/00—Generating plasma; Handling plasma
- H05H1/24—Generating plasma
- H05H1/46—Generating plasma using applied electromagnetic fields, e.g. high frequency or microwave energy
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q1/00—Details of, or arrangements associated with, antennas
- H01Q1/12—Supports; Mounting means
- H01Q1/22—Supports; Mounting means by structural association with other equipment or articles
- H01Q1/26—Supports; Mounting means by structural association with other equipment or articles with electric discharge tube
-
- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05B—ELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
- H05B31/00—Electric arc lamps
- H05B31/02—Details
- H05B31/26—Influencing the shape of arc discharge by gas blowing devices
Definitions
- the present invention relates generally to the design and implementation of a plasma generation system. More particularly, it relates to radio frequency amplifiers, antennas and effective circuit connections for interfacing the amplifiers and antennas for generating plasma.
- Plasma is generally considered to be one of the four states of matter, the others being solid, liquid and gas states.
- the elementary constituents of a substance are substantially in an ionized form. This form is useful for many applications due to, inter alia, its enhanced reactivity, energy, and suitability for the formation of directed beams.
- Plasma generators are routinely used in the manufacture of electronic components, integrated circuits, and medical equipment, and in the operation of a variety of goods and machines.
- plasma is extensively used (i) to deposit layers of a desired substance, for instance, following a chemical reaction or sputtering from a source, (ii) to etch material with high precision, (iii) to sterilize objects by the free radicals present in the plasma or induced by the plasma, and (iv) to modify surface properties of materials.
- Plasma generators based on radio frequency (“RF”) power supplies are often used in experimental and industrial settings since they provide a ready plasma source, and are often portable and easy to relocate. Such plasma generators couple RF radiation to a gas, typically at reduced pressure (and density), causing the gas to ionize.
- the plasma represents a variable load at the antenna terminals, which are typically driven by the RF power supply, as the process conditions change.
- Such variable process conditions include, changes in working gas and pressure, which affect the amount of loading seen at the antenna terminals.
- the amplitude of the RF drive waveform itself affects the plasma temperature and density, which in turn also affects the antenna loading.
- the antenna/plasma combination is a non- constant and nonlinear load.
- a typical RF source has an output impedance of about 50 ohm, and as a result couples most efficiently to a load that presents a matching 50 ohm impedance. Because of the often unpredictable changes in the plasma self inductance, effective resistance, and mutual inductance to the antenna, provision for dynamic impedance matching is made by retuning some circuit elements and possibly the plasma to obtain satisfactory energy transfer from the RF source to the generated plasma. To achieve this, an adjustable impedance matching network, or "matching box" is typically used to compensate for the variation in load impedance due to changes in plasma conditions.
- a typical dynamic matching box contains two independent tunable components: one for adjusting the series impedance and another for adjusting the shunt impedance. These tunable components must be adjusted in tandem with each other in order to achieve the optimum power transfer to the plasma. Not surprisingly, accurate tuning of these components is often a difficult process. Typically, retuning requires both manual/mechanical operations/actuators to adjust one or more component values as the plasma impedance changes and generally sophisticated feedback circuitry for the rather limited degree of automation possible.
- Whistler waves are right-hand-circularly-polarized electromagnetic waves (sometimes referred to as R-waves) that can propagate in an infinite plasma immersed in a static magnetic field B 0 . If these waves are generated in a finite plasma, such as a cylinder, the existence of boundary conditions - i.e. the fact that the system is not infinite - cause a left-hand-circularly- polarized mode (L-wave) to exist simultaneously, together with an electrostatic contribution to the total wave field.
- These "bounded Whistler” are known as Helicon waves. See Boswell, R.W., Plasma Phys. 26, 1147 (1981 ).
- N p Significant plasma density enhancement and uniformity
- RF power sources typically receive an external RF signal as input or include an RF signal generating circuit. In many processing applications, this RF signal is at a frequency of about 13.56 MHz.
- the RF signal is amplified by a power output stage and then coupled via an antenna to a gas/ plasma in a plasma generator for the production of plasma.
- Amplifiers including RF amplifiers suitable for RF power sources, are conventionally divided into various classes based on their performance characteristics such as efficiency, linearity, amplification, impedance, and the like, and intended applications.
- efficiency linearity
- amplification impedance
- impedance impedance
- a characteristic of interest is the output impedance presented by an amplifier since it sets inherent limitations on the power wasted by an amplifier.
- Typical RF amplifiers are designed to present a standard output impedance of 50 Ohms. Since, the voltage across and current through the output terminals of such an amplifier are both non-zero, their product provides an estimate of the power dissipated by the amplifier.
- This product can be reduced by introducing a phase difference between the voltage and the current across the output terminals of the amplifier in analogy with the power dissipated in a switch.
- a switch presents two states: it is either ON, corresponding to a short circuit, i.e., low impedance, or OFF, corresponding to an open circuit, i.e., infinite (or at least a vary large) impedance.
- the amplifier element acts as a switch under the control of the signal to be amplified. By suitably shaping the signals, for instance with a matching load network, it is possible to introduce a phase difference between the current and the voltage such that they are out of phase to minimize the power dissipation in the switch element.
- United States Patents Nos. 3,919,656 and 5,187,580 disclose various voltage/current relationships for reducing or even minimizing the power dissipated in a switched mode amplifier.
- United States Patent No. 5,747,935 discloses switched mode RF amplifiers and matching load networks in which the impedance presented at the desired frequency is high while harmonics of the fundamental are short circuited to better stabilize the RF power source in view of plasma impedance variations.
- These matching networks add to the complexity for operation with a switched mode power supply rather than eliminate the dynamic matching network.
- Such a matching load network is also not very frequency agile since it depends on strong selection for a narrow frequency band about the fundamental.
- United States Patent No. 6,432,260 discloses use of switched elements in matching impedance networks to ensure that the dynamic complex impedance of the plasma is seen as a near resistive value, effectively neutralizing the reactive components of plasma impedance. This allows a power source to only respond to resistive changes in the plasma since it is only such changes that are seen by the power source.
- the dynamic plasma resistance controls the power delivered to the plasma.
- United States Patent Nos. 6,150,628, 6,388,226, 6,486,431 , and 6,552,296 disclose constant current switching mode RF power supply containing an inductive element in series with the plasma load.
- the plasma is primarily driven as the secondary of a iron- or ferrite-core transformer, the primary of which is driven by the RF power supply.
- dynamic impedance matching network is disclosed to be not required.
- the current through the plasma is maintained at about the value of the initial inductor current to adjust the power based on the size of the load.
- M parameter ⁇ ⁇ , lp is the mutual inductance between the primary inductance l_ ⁇ and the plasma inductance L p , is quite small.
- the problems faced in efficient plasma generator design include the need for a low maintenance and easily configured antenna, the elimination of expensive dynamic matching networks for directly coupling the RF power source to the non-linear dynamic impedance presented by a plasma, and the need for RF power sources that can be efficiently modulated and are frequency agile.
- An improved design for efficiently coupling one or more RF sources to a plasma is disclosed. Also disclosed are method and system for generating a plasma with the aid of an RF power source without requiring the use of a dynamic matching network to couple the RF power source to the plasma.
- a dynamic matching network requires impedance adjustments in response to the dynamic impedance presented by a plasma.
- a reactive network couples the RF power source to the antenna-plasma combination.
- the reactive network is selected so that at least a first plasma impedance value, a substantially resistive load is presented to the RF power source.
- a second plasma impedance value preferably, selected so as to significantly cover the expected dynamic plasma reactance range, the reactance seen by the RF power source is about the same as that of the RF power source itself.
- the reactive circuit In addition to the plasma impedance, other considerations may also be taken into account in the design of the reactive circuit. For instance, it may be designed so as to present a phase difference at the switched power supply, the RF power source, since this improves the efficiency of the power supply by reducing resistive losses at the switches. Such additional conditions may, in general require the values of three or more reactance elements to be determined for providing the desired behavior.
- An illustrative plasma generator system comprises at least one plasma source, the at least one plasma source having an antenna including a plurality of loops, each loop having a loop axis, the plurality of loops arranged about a common axis such that each loop axis is substantially orthogonal to the common axis; at least one radio frequency power source for driving the plurality of loops substantially in quadrature and coupled to a plasma load driven in a circularly polarized mode, preferably a helicon mode, via the antenna; a static magnetic field substantially along the common axis; and a reactive network coupling the switching amplifier to the antenna loops.
- the radio frequency power source preferably comprises at least one member from the group consisting of a substantially Class A amplifier, a substantially Class AB amplifier, a substantially Class B amplifier, a substantially Class C amplifier, a substantially Class D amplifier, a substantially Class E amplifier, and a substantially Class F amplifier. In one embodiment, these are connected to the primary of a transformer to reduce the drive impedance to a low value. Even more preferably the radio frequency power source includes a Class D amplifier in a push-pull configuration with a relatively low output impedance.
- the radio frequency power source preferably exhibits a low output impedance.
- the low output impedance is significantly less than the standard impedance of 50 Ohm.
- the output impedance is preferably within a range selected from the set consisting of less than about 0.5 Ohms, less than about 2 Ohms, less than about 3 Ohms, less than about 5 Ohms, less than about 8 Ohms, less than about 10 Ohms, and less than about 20 Ohms.
- the output impedance is less than 5 Ohms, even more preferably the output impedance is between 0.5 to 2 Ohms, and most preferably the output impedance is less than 1 Ohm. In a preferred embodiment, the output impedance is about 12 Ohms.
- a further advantage of the disclosed system is that the voltage applied to the antenna can be made quite large prior to plasma formation, thus increasing the ability to initiate the plasma in a variety of working conditions. Once the plasma is formed, the voltage reduces to a lower level to sustain the plasma.
- MICP magnetized inductively coupled plasma
- P 0 approximately 100 mTorr
- the currents in the antenna elements appear to abruptly "lock" into a quadrature excitation mode when the conditions on neutral pressure P 0 , input power P RF , and externally applied axial magnetic field B 0 , are right. When this occurs, advantageously the plasma appears to fill the chamber approximately uniformly, thus providing the ability to produce uniform processing conditions.
- the combination of antenna system plus RF generator can create and maintain a plasma under conditions where the plasma parameters vary over much larger ranges than have been reported for other sources (e.g. neutral pressure P 0 varied from 100 mTorr down to 5 mTorr, and then back up again to 100+ mTorr, in a cycle lasting approximately one minute), without the need for the adjustment of any dynamic matching network components.
- neutral pressure P 0 varied from 100 mTorr down to 5 mTorr, and then back up again to 100+ mTorr, in a cycle lasting approximately one minute
- Another advantage of the disclosed system is that the elimination of the dynamic matching network allows an "instant-on" type of operation for the plasma source.
- This characteristic can be used to provide an additional control for the process being used.
- it is possible to modulate the amplitude of the RF power generating the plasma between two (or more) levels such as 30% and 100%, or in a fully on-off manner (0% to 100%).
- This modulation can occur rapidly, e.g. at a frequency of several kilohertz, and can accomplish several purposes.
- the average RF power can be reduced with a consequent reduction in average plasma density.
- the "instant-on" operation can generate plasma with an average RF input power of as little as 5 W in a volume of 50 liters.
- modulation can be used to control the spatial distribution of the working gas within the reaction chamber:
- the plasma modifies the distribution of the working gas, thus, contributing to the non-uniformity of fluxes of the active chemicals or radicals.
- modulating the duty cycle of plasma production the flow characteristics of the neutral gas during the plasma off time (or reduced-power-level time) can be adjusted to control the uniformity of the process. Since the plasma initiation time is usually within 10- 20 microseconds of the application of the RF, the duty cycle may be controlled at frequencies as high as tens or hundreds of kHz.
- FIGURE 1 illustrates a plasma source chamber with two sets of antenna elements
- FIGURE 2 illustrates a tunable circuit with an RF power source coupled to an antenna
- FIGURE 3 illustrates a second tunable circuit with an RF power source coupled to an antenna
- FIGURE 4 illustrates a third tunable circuit with an RF power source coupled to an antenna
- FIGURE 5 illustrates a circuit with an RF power amplifier coupled to an antenna current strap
- FIGURE 6 illustrates a second circuit with an RF power amplifier coupled to an antenna current strap
- FIGURE 7 illustrates a third circuit with an RF power amplifier coupled to an antenna current strap
- FIGURE 8 illustrates a simplified model of the RF power amplifier, antenna current strap, and plasma
- FIGURE 9 illustrates a lumped circuit equivalent of the model depicted in FIGURE 8.
- FIGURE 10 illustrates the frequency response of a plasma source without a plasma
- FIGURE 11 illustrates the frequency response of a plasma source with a plasma present
- FIGURE 12 illustrates a feedback arrangement for controlling a plasma source.
- FIGURE 13 illustrates a reactive network for coupling an RF power source to a plasma
- FIGURE 14 shows an illustrative embodiment of the invention with elements selected in a reactive network to eliminate the need for a dynamic matching network.
- FIGURE 1 illustrates a plasma source chamber with two sets of antenna elements.
- the antenna design includes two orthogonal single- or multi-turn loop elements 105, 110, 115, and 120, arranged about a common axis.
- the antenna elements 105, 110, 115, and 120 are each driven by RF power sources, A 125 or B 130 as shown.
- Each antenna loop may be coupled to the same RF power source with a phase splitter, or to distinct RF power sources, to drive the antenna elements in quadrature.
- the loops in the antenna are constructed from eight (8) gauge teflon coated wire although bare copper wire or other conductors may also be used.
- FIGURE 1 shows two orthogonal sets of two-element Helmholtz-coil- like loop antennas, with loop elements 105 and 115 in one set and loop elements 110 and 120 in the second set.
- the loop elements are wrapped azimuthally around an insulating cylinder 135 such that the magnetic fields that are produced when a current is passed through them are approximately transverse to the axis of the cylinder.
- the opposing elements of each set are connected in series, in a Helmholtz configuration.
- the wires interconnecting opposing loop elements are preferably arranged such that adjacent segments carry currents flowing in opposite directions in order to enhance cancellation of stray fields associated with them, although this is not necessary to the device operation.
- the antennas are energized such that the currents in both orthogonal branches are nearly equal and phased 90 degrees apart to produce an approximation to a rotating transverse magnetic field.
- the amplitude and direction of the current producing the external field may be adjusted to modulate the performance of the plasma generator.
- the overall amplitude of the necessary field is typically in the range 10-100 Gauss for the parameters discussed here, but for different size sources alternative ranges may be employed. Once the static field optimum amplitude and direction are chosen, they typically need no further adjustment.
- a quartz bell jar has approximately 12" inside diameter (such as a standard K.J. Lesker 12 x 12), consisting of a straight-cylindrical section approximately 15 cm tall with a 6" radius hemispherical top. The jar rests atop a vacuum chamber approximately 12" i.d. x 8" tall (not part of the plasma source).
- the antennas consist of two sets of opposing, close-packed, approximately rectangular, two- turn continuous loop antenna elements that surround the bell jar, with approximately 1/8" to 1/2" spacing between the antennas and the bell jar at every point.
- the turns within each element are connected in series, and the two elements within each set are also connected in series, such that their fields are additive.
- the self-inductance of each set is approximately 10 microHenries in this example, and the mutual inductance between the two sets is less than 1 microHenry.
- Vertical and horizontal antenna loop sections approximately 25cm and 20 cm long, respectively, consist of 8-guage Teflon- coated wire.
- single turns of rigid copper conductors may be employed in place of one or two turns of Teflon-coated wire.
- a conventional RF power source and dynamic matching scheme may be used to excite the antenna currents in the antenna described above.
- the circuits of FIGURES 2 to 4 are compatible with many of the disclosed methods. Some of these methods include steps such as providing a low output impedance to an RF power source; and adjusting a reactance coupling the RF power source to the antenna such that the resonance frequency in the absence of a plasma is the desired RF frequency.
- a low output impedance can be understood by reference to the quality factor ("Q") for the circuit with and without the plasma.
- Q quality factor
- the "Q" with no plasma present should be five to ten-fold or even higher than in the presence of the plasma.
- such a combination of the RF power source and antenna will not need to be readjusted in the presence of plasma by changing the reactance in response to changes in the plasma impedance.
- the RF source 200 may be a commercial 2 MHz, 0-1 kW generator, connected to the quadrature/hybrid circuit at port "A" 125 illustrated in FIGURE 1 via 50 ohm coax.
- the "+45 degree” and “- 45 degree” legs of the quadrature/hybrid circuit are connected to individual L-type capacitative matching networks composed of adjustable capacitors 205, 210, 215, and 220 as shown.
- the reactance of capacitors 225 is about 100 ohms each at the operating frequency, and the reactance of either side of the transformer 230 is about 100 ohms with the other side open.
- a single RF source 200 may be used, together with a passive power splitter (the quadrature/hybrid circuit) and four adjustable tuning elements 205, 210, 215, and 220 to match to the two separate antenna inductances 235 and 240.
- a passive power splitter the quadrature/hybrid circuit
- adjustable tuning elements 205, 210, 215, and 220 to match to the two separate antenna inductances 235 and 240.
- FIGURE 3 Another embodiment, illustrated in FIGURE 3, employs two separate RF power sources 305 and 310, and thus entirely separates the two antenna power circuits connected to inductances 335 and 340 via tunable capacitors 315, 320, 325, and 330 respectively.
- each RF source can be operated at full power, thus doubling the amount of input power as compared to that of a single RF source, and the phasing and amplitude ratio may be adjusted between the antennas.
- sources 305 and 310 are operated at roughly the same amplitude and at 90 degrees out of phase, although the amplitude and/or phase difference might be varied in order to change the nature of the excited mode. For example, by operating them at different amplitudes, an elliptically polarized plasma helicon mode rather than a strictly circularly polarized mode could be sustained.
- a third embodiment, illustrated in FIGURE 4, places a passive resonant circuit, comprising inductor/antenna inductance 405 and adjustable capacitor 410 on one leg, and drives the other leg with an RF source 400 with a dynamic matching circuit having tunable capacitors 415 and 420 connected to antenna inductance 425.
- This arrangement tends to excite the same sort of elliptical helicon mode in the plasma, with the passive side operating approximately 90 degrees out of phase with the driven side, thus providing many advantages but with only a single RF source and dynamic matching network.
- the working gas in this example setup is Argon, with pressure ranging from 10 mTorr to over 100 mTorr.
- a static axial field is manually settable to 0 - 150G and is produced by a coil situated outside the bell jar/antenna assembly, with a radius of about 9".
- Plasma operation at a pressure of approximately 75 mTorr exhibits at least three distinct modes.
- a bright mode in which the plasma is concentrated near the edge of the bell jar is observed for B 0 ⁇ B cr i t icai when P RF is less than or approximately 200W.
- B 0 is the axial magnetic field
- Bcri t i ca i is a critical value for the axial field for exciting a plasma using a helicon mode.
- power levels PRF and Pthr es oid denote the RF power supplied to the antenna and a threshold power described below. In this mode, the RF antenna currents tend to not be in quadrature, instead being as much as 180 degrees out of phase.
- the conventional RF power source and tunable matching network described in FIGURES 2 to 4 may be eliminated in favor of a streamlined power circuit.
- an RF power circuit drives the antenna current strap directly, using an arrangement such as that shown in FIGURE 5.
- the RF amplifier illustrated in FIGURE 5 is preferably one of the many types of RF amplifiers having a low output impedance (i.e. a push-pull output stage) that are known in the field.
- Transistors 505 and 510 are driven in a push-pull arrangement by appropriate circuitry 500, as is known to one of ordinary skill in the art. In this arrangement typically one transistor is conducting at any time, typically with a duty cycle of or less than 50%. The output of the the transistors is combined to generate the complete signal.
- the power semiconductors e.g., transistors 505 and 510, in the output stage are operated in switching mode.
- these are depicted as FETs, but they can also be, for example, bipolar transistors, IGBTs, vacuum tubes, or any other suitable amplifying device.
- An example of switching mode operations is provided by Class D amplifier operation. In this mode alternate output devices are rapidly switched on and off on opposite half-cycles of the RF waveform. Ideally since the output devices are either completely ON with zero voltage drop, or completely OFF with no current flow there should be no power dissipation. Consequently class D operation is ideally capable of 100% efficiency. However, this estimate assumes zero ON- impedance switches with infinitely fast switching times. Actual implementations typically exhibit efficiencies approaching 90%.
- the RF driver is coupled directly to the antenna current strap 520 through a fixed or variable reactance 515, preferably a capacitor.
- This coupling reactance value is preferably such that the resonant frequency of the circuit with the coupling reactance and the antenna, with no plasma present, is approximately equal to the RF operating frequency.
- FIGURE 6 (A) An alternative arrangement of the output stage of this circuit, illustrated in FIGURE 6 (A), includes a transformer 620 following or incorporated into the push-pull stage, with driver 600 and transistors 605 and 610, to provide electrical isolation.
- Transformer 620 may optionally be configured to transform the output impedance of the push-pull stage, if too high, to a low impedance.
- Capacitor 615 is arranged to be in resonance at the desired drive frequency with the inductive circuit formed by transformer 620 and antenna current strap 625.
- FIGURE 6(B) A similar embodiment is shown in FIGURE 6(B), where capacitor 615 is used for DC elimination, and capacitor 630 is resonant in the series circuit formed by leakage inductance of transformer 620 and inductance of the current strap 625.
- FIGURE 7 illustrates yet another RF power and antenna current strap configuration.
- a center-tapped inductor 725 incorporated in the DC power feed is connected to the output stage having push-pull driver 700 and transistors 705 and 710. Isolation is provided by transformer 720. Again, only one or the other transistor is conducting at any time, typically with a duty cycle of less than 50%.
- the circuits of FIGURES 5-7 are provided as illustrative examples only. Any well-known push-pull stage or other configurations providing a low output impedance may be used in their place.
- the RF power source may also be used with any helicon antenna, such as either a symmetric (Nagoya Type III or variation thereof, e.g., Boswell-type paddle-shaped antenna) or asymmetric (e.g., right-hand helical, twisted-Nagoya-lll antenna) antenna configuration, or any other non-helicon inductively coupled configuration.
- a symmetric Negoya Type III or variation thereof, e.g., Boswell-type paddle-shaped antenna
- asymmetric e.g., right-hand helical, twisted-Nagoya-lll antenna
- the RF power source may be amplitude modulated with a variable duty cycle to provide times of reduced or zero plasma density interspersed with times of higher plasma density.
- This modulation of the plasma density can be used to affect the flow dynamics and uniformity of the working gas, and consequently the uniformity of the process.
- a more spatially uniform distribution comprising plasma may therefore be generated by a plasma generator system by a suitable choice of a modulation scheme.
- a plasma generator system may use radio frequency power sources based on operation as a substantially Class A amplifier, a substantially Class AB amplifier, a substantially Class B amplifier, a substantially Class C amplifier, a substantially Class D amplifier, a substantially Class E amplifier, or a substantially Class F amplifier or any sub- combination thereof.
- Such power sources in further combination with the antennas for exciting helicon mode are suitable for generating high density plasmas.
- an intermediate stage to transform the RF source impedance to a low output impedance may be employed to approximate the efficient operation of the switching amplifier based embodiments described herein.
- the antenna current strap is located in proximity to the region where plasma is formed, usually outside of an insulating vessel. From a circuit point of view, the antenna element forms the primary of a non-ideal transformer, with the plasma being the secondary.
- FIGURE 8 An equivalent circuit is shown in FIGURE 8, in which inductor 810 represents a lumped-element representation of the current strap and any inductance in the wiring, including any inductance added by e.g., the driver's output transformer present in some embodiments.
- Components in the box labeled P represent the plasma: inductor 820 is the plasma self inductance, and impedance 815 represents the plasma dissipation, modeled as an effective resistance.
- M represents the mutual inductance between the antenna and plasma.
- Transistor driver 800 is represented as a square-wave voltage source.
- the capacitance 805 is adjusted at the time the system is installed to make the resonant frequency of the circuit approximately match the desired operating frequency.
- the RF frequency may be adjusted to achieve the same effect.
- FIGURE 9 For illustrating the operation of the system, the overall system may be modeled as shown in FIGURE 9.
- all inductors have been lumped into inductance 905, all capacitors into capacitance 910, and all dissipating elements into resistor 915, and the amplifier should ideally operate as an RF voltage source (i.e., having zero output impedance).
- the circuit when operating with a plasma load the circuit is relatively insensitive to variations in operating conditions, and requires no retuning. This is illustrated in FIGURE 11 , where the overall system resonance has shifted its frequency slightly, although the Q is sufficiently reduced that the operation of the system remains efficient. With the reduced Q of the circuit, the voltage applied to the plasma self-adjusts to be considerably reduced over the no-plasma case. In some embodiments, it may be somewhat advantageous to actually detune the operating frequency of the RF drive slightly from the exact no-plasma resonance to one side or the other, depending on the shift of the resonant frequency when the plasma forms.
- the level of power input to the plasma may be controlled by a variety of techniques, such as adjusting the DC supply level on the RF output stage.
- the supply voltage may be in response to sensed variations in plasma loading to maintain a relatively constant power into the plasma source.
- the sensing of plasma loading for adjustments by DC supply regulator 1230 may be achieved, for example, by monitoring the voltage from the DC supply 1215 by voltage sensor 1200 and the DC current into the RF/Plasma system by current sensor 1205, and using their product together with a previously measured approximation to the amplifier efficiency in module 1210 to estimate the net power into the plasma 1225 from RF Amplifier 1220.
- Efficiency multiplier for gain module 1235 can be measured for different output levels, for instance by monitoring heat loads at various points of the system, and stored digitally, so that variations in efficiency with output level are accounted for.
- the RF voltage and current can be measured, and their in-phase product evaluated to estimate the real power being dissipated in the plasma.
- the sensing of plasma may also extend to sensing spatial uniformity by either direct sensing or indirect sensing by way of variations in the voltage or current. Changing the duty cycle in response to such variations can then control the spatial distribution of plasma. In addition, modulating the duty cycle can further allow control over the average input power to improve the efficiency of plasma generation.
- the feedback arrangement of FIGURE 12 can also allow switching between two or more power levels as described previously.
- Low impedance means that the series resonant circuit shown in FIGURE 9 has a "Q" that should be five to ten-fold or even higher with no plasma present than with plasma present. That is, the amplifier output impedance should be sufficiently small that the energy dissipated in a half-cycle of output is much less than that stored in the reactive components.
- the RF amplifier will approach operation as a voltage source when this condition holds.
- a low resistance e.g., for the output impedance of the RF source, generally refers to a resistance of less than about 10 ohm, preferably less than about 6 Ohms, more preferably less than about 4 Ohms, and most preferably less than about 1 Ohm.
- the elements in the reactive circuit coupling the RF power source to the antenna/plasma be selected based on the resonant frequency of the circuit without a plasma being present.
- alternative conditions are possible that allow a suitable specification of the reactive circuit such that there is no need for a dynamic matching circuit while efficient coupling is possible with the dynamic impedance of a plasma.
- a high expected plasma reactance component and a low expected plasma reactance may be specified. For instance, such a specification may reflect a one- ⁇ distance away from the expected mean value. Many other similar specifications are possible to indicate the likelihood of the plasma impedance actually falling outside the specified limits. Indeed, instead of a high expected plasma reactance, it is possible to specify a value that is not symmetrically placed relative to the low expected plasma reactance. Moreover, while a particular plasma impedance may fail to conform to a normal distribution, a collection of several plasmas is likely to collectively present a normal distribution for the combined impedance.
- a collection of several RF power sources connected together is likely to exhibit a normal distribution, both with respect to frequency and time. Then a suitable choice of a reactance network may actually ensure that the variation in plasma reactance is well matched to the variation in the RF power sources by matching them at two values of the expected plasma reactance.
- this complex value may be adjusted with suitable components to be 14 +/12.6 Ohms by adjusting C a to be about 81.6 pF and C b at about 376 pF.
- an illustrative plasma antenna combination may, for example, present a resistance R p of about 1 to 4 Ohms and a reactance X p of about -8 to -25 Ohms.
- R p of about 1 to 4 Ohms
- X p of about -8 to -25 Ohms.
- the transistor switching circuit will safely operate with a supply voltage that is a fraction of the desired peak supply voltage of about 700 to 800 V, e.g., at about 250 V (more likely 200).
- the peak output voltage is given by V SU ppiy/2 X
- a total impedance when operating at a given frequency, a total impedance may be adjusted by adding an inductor (having a positive reactance) or a capacitor (having a negative reactance) in series with the impedance.
- an inductor having a positive reactance
- a capacitor having a negative reactance
- the total impedance may be adjusted to a level at or near zero for a given operating frequency by adding a capacitor in series, with the capacitance adjusted so
- FIGURE 14 shows an illustrative general reactive circuit 1400 suitable for coupling radiofrequency power source 1405 to a capacitively driven plasma or an antenna-plasma combination.
- this circuit relates to a capacitively coupled driver, e.g., for the RF biasing of a substrate in a semiconductor processing plasma, but the principle for determining the values of the components applies to an inductively coupled system as well.
- the illustrative general reactive circuit 1400 may be tuned either using the capacitors or inductors or both. For instance, the reactance of capacitors 1415 and 1425 may be chosen to be approximately the same as the minimum plasma reactive component, at about 500 pF each.
- Inductors 1410 and 1420 are then tuned to satisfy two conditions: a) at the largest magnitude of plasma reactance, i.e., a high expected plasma reactance limit, the imaginary part of the overall load seen by the transistor output stage is small, and b) at the smallest magnitude of plasma reactance, i.e., a low expected plasma reactance limit, the imaginary part of the load seen by the output stage is adjusted to optimize operation of the radio frequency power source, e.g., +12 Ohms as in the circuit described in the above Directed Energy reference.
- the radio frequency power source e.g., +12 Ohms
- 0ad Z-u-io + Z 1415 + (Z-i 2o + Z- ⁇ 25)
- 0 represents the impedance of inductor 1410 in FIGURE 14 and the like while Z p represents one value of expected plasma reactance. That is, the driver sees capacitor 1410 in series with inductor 1415 and in series with the parallel combination of plasma impedance 1440 and capacitor 1425 + inductor 1420 series combination.
- case "a” corresponds to lm(Z
- Case "b” corresponds to lm(Z
- values of inductance 1420 is about 345 nH and inductance 1415 is about 185 nH resulting in lm(Z
- More sophisticated calculations preferably take into account stray inductances, coil inductances and the like along with other non-ideal effects.
- Alternative output transistor stages may be operated at different impedances in the reactive load, including a slightly capacitive load. Then, the condition lm(Z
- the imaginary part of the overall load seen by the transistor output stage is small.
- the specified plasma reactance may be a value outside the range of expected operation. However, such a specification may result in higher output current.
- adding a resistive path in parallel with capacitor 1425 improves the performance of the reactive circuit.
- the reactive circuit may include resistive elements as well.
- nonlinear resistive or reactive elements may be used for the purpose of reducing the impedance variation seen by the RF power source.
- the inductors 1415 and 1420 may be arranged to have a small amount of mutual inductance, which can be either positive or negative.
- a positive mutual inductance M- ⁇ 415 ⁇ 142 o e.g., in the range
- tuning or setting up of a reactive network provide several advantages in addition to removing the need for a dynamically tuned matching circuit. For example, since the tuning at one plasma reactance in the range of reactance values expected for a plasma matches that for the operation of amplifier, it provides the transistors with the reactive impedance needed for efficiently operating at a high voltage. Further, although at the other end of the plasma range, the reactance seen by the output stage is small, the total load is also small, enabling operation at high current and low supply voltage resulting in the reactance presented to the transistors being less important. Moreover, this specification ensures that over a broad range of plasma reactance, a reasonable amount of power may be delivered from the RF source to the plasma. In another aspect, with this design enables use of a large number of output stages that may be combined, for instance, in parallel.
- this transfer function has a resonant character, in that the magnitude of H is greater than one over a substantial, if not the entire, range of operation.
- varies from approximately 21 to 1.6. Therefore, selecting a reactance network well suited for operation at the lowest expected plasma resistance ensures with high degree of certainty that the variation in plasma impedance would be smaller at a higher values of the plasma resistance.
- the disclosed system and methods provide an advantage in being able to break down this gas and initiate the plasma by virtue of the fact that the high Q of the circuit with no plasma allows high voltages to be induced on the antenna element with relatively low power requirements.
- This no-plasma voltage can be controlled to give a programmed breakdown of the working gas; once the plasma forms, induced currents in the plasma serve to load the system and lower the high voltages for inducing the breakdown, and thus, avoid stressing the system.
- variable tuning element such as a mechanically adjustable capacitor
- the various circuits can also be constructed using a variable capacitor that is adjusted, for example, for matching of the system resonance to the desired operating frequency, in a preferred embodiment, and is not needed for real-time impedance matching with the plasma operating point. Such matching is useful to counter the effects of mechanical vibration or aging that may cause the L-C resonant frequency to drift.
- the operating frequency is adjusted to compensate for small deviations from resonance, while mechanically tuning the capacitor compensates for large deviations.
- adjustments are made by tuning the capacitor.
- this tuning is automated and takes place during periods when the source is offline.
- the disclosed arrangement reduces the number of adjustable elements to as few as one in embodiments with adjustable tuning elements.
Abstract
Description
Claims
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CA002529794A CA2529794A1 (en) | 2003-06-19 | 2004-06-21 | Plasma production device and method and rf driver circuit with adjustable duty cycle |
JP2006517522A JP2007524963A (en) | 2003-06-19 | 2004-06-21 | Plasma generating apparatus and method, and variable duty cycle high frequency driving circuit |
EP04755834A EP1689907A4 (en) | 2003-06-19 | 2004-06-21 | Plasma production device and method and rf driver circuit with adjustable duty cycle |
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US48033803P | 2003-06-19 | 2003-06-19 | |
US60/480,338 | 2003-06-19 |
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WO2004114461A3 WO2004114461A3 (en) | 2006-07-06 |
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PCT/US2004/019931 WO2004114461A2 (en) | 2003-06-19 | 2004-06-21 | Plasma production device and method and rf driver circuit with adjustable duty cycle |
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EP (1) | EP1689907A4 (en) |
JP (1) | JP2007524963A (en) |
KR (1) | KR20060029621A (en) |
CN (1) | CN1871373A (en) |
CA (1) | CA2529794A1 (en) |
WO (1) | WO2004114461A2 (en) |
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- 2004-06-21 CN CNA2004800232588A patent/CN1871373A/en active Pending
- 2004-06-21 CA CA002529794A patent/CA2529794A1/en not_active Abandoned
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Also Published As
Publication number | Publication date |
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JP2007524963A (en) | 2007-08-30 |
CN1871373A (en) | 2006-11-29 |
EP1689907A2 (en) | 2006-08-16 |
KR20060029621A (en) | 2006-04-06 |
CA2529794A1 (en) | 2004-12-29 |
EP1689907A4 (en) | 2008-07-23 |
WO2004114461A3 (en) | 2006-07-06 |
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