A plasma reactor for processing a semiconductor wafer typically holds the wafer inside the reactor chamber using an electrostatic chuck (ESC). Plasma ion energy at the wafer surface is controlled by applying a bias voltage to the wafer through the ESC. The ESC essentially consists of an insulator layer having a top surface for supporting the wafer. An electrode or conductive mesh inside the insulator layer beneath the wafer receives a D.C. voltage, creating a voltage drop across the insulator layer between the electrode and the wafer, which produces an electrostatic force clamping the wafer to the ESC. The clamping force is determined by the difference between the time-average of the wafer voltage and the D.C. voltage applied to the ESC electrode. The clamping voltage must be accurately controlled (by accurately controlling the D.C. supply voltage) in order to avoid an insufficient clamping voltage or an excessive clamping voltage. An insufficient clamping voltage would allow the wafer to pop off of the ESC. An excessive clamping voltage would increase the current through the wafer to a level that risks damaging the circuit features formed on the wafer surface. (Current flows from the ESC electrode through the dielectric layer to the wafer and returns through the plasma in the chamber. The stronger the clamping force, the greater the conductivity between the wafer and the ESC, and therefore the greater the current through the wafer.) In order to accurately control the clamping voltage, the wafer D.C. voltage must be measured accurately. An error in wafer voltage measurement may lead to wafer pop off or to excessive ESC-wafer current.
Use of ESC-wafer contact to control the wafer temperature imposes even more stringent requirements for accurate control of clamping voltage. As disclosed in co-pending U.S. patent application Ser. No. 10/929,104, filed Aug. 26, 2004 entitled, “Gasless High Voltage High Contact Force Wafer Contact-Cooling Electrostatic Chuck,” by Douglas Buchberger, Jr. et al., and assigned to the present assignee, the ESC may be heated or cooled so that the wafer is either heated or cooled at a rate determined by the ESC clamping force. The wafer temperature may therefore be accurately set and controlled as desired. In fact, the heat transfer rate is so great as the clamping voltage is increased, that the wafer temperature may be maintained under much higher heat load than was formerly possible. Thus, for example, the wafer bias power may be increased beyond previously permitted levels. However, the wafer temperature range is limited because the clamping voltage cannot closely approach the upper limit (above which the wafer current is excessive) or the lower limit (below which the wafer may pop off the ESC), without more accurate determination of wafer voltage. (The clamping voltage is determined from the difference between the time average of the wafer voltage and the D.C. supply voltage.) Current methods for estimating wafer voltage tend to be inaccurate, so that the clamping voltage range must be limited to ensure that wafer voltage measurement errors do not cause the clamping voltage to violate the upper and lower limits.
An accurate method for determining wafer voltage is disclosed in co-pending U.S. patent application Ser. No. 10/440,364, filed May 16, 2003 by Daniel Hoffman and assigned to the present assignee. This method is applicable to a plasma reactor in which bias power of a single bias frequency only is coupled to the wafer from the ESC. This method is inaccurate when more than one bias frequency is present. For example, the reactor may apply bias power having a low frequency (LF) component and a high frequency (HF) component in order to obtain a favorable ion energy distribution for a plasma process such as plasma enhance reactive ion etching. A large error in wafer voltage measurement occurs when such a dual frequency bias is employed. We have found that the error in the wafer voltage measurement in such a case can create a clamping voltage error exceeding the capacity of the ESC's D.C. voltage supply.
What is needed is an accurate way of measuring wafer voltage with a dual frequency bias. This would permit the clamping voltage to be set to values closer either the maximum or minimum allowed clamping voltage without fear of violating these limits due to wafer voltage measurement errors. This in turn permits the wafer temperature range to be expanded accordingly, a significant advantage.
In a plasma reactor having an electrostatic chuck (ESC) supporting a wafer to be processed, a method of processing the wafer while controlling an ESC clamping voltage includes applying RF bias power to the ESC from a bias power source at an input to the ESC and applying a D.C. voltage at the input to the ESC from a D.C. voltage source. The voltage and current is measured near the input to produce a measured voltage and a measured current. A wafer voltage signal is provided as a sum of the measured voltage and the measured current multiplied by first and second coefficients respectively, the wafer voltage signal representing the voltage on a wafer supported on the ESC. The method further includes computing a wafer clamping voltage as a difference between a D.C. component of the wafer voltage signal and the D.C. voltage from the D.C. voltage source, and controlling the D.C. voltage to regulate the wafer clamping voltage. In one embodiment, controlling the D.C. voltage is performed so as to minimize a difference between the wafer clamping voltage and a target clamping voltage.
factors employed by the measurement instrument of
ESC With High Contact Force Wafer Cooling:
Plasma RF bias power from a low frequency RF bias power generator 125 and from a high frequency RF bias power generator 125′ is applied through an impedance match circuit 130 to the wafer support pedestal 14. A D.C. chucking voltage is applied to the chuck 14 from a chucking voltage source 48 isolated from the RF bias power generator 125 by an isolation capacitor 50. The RF power delivered to the wafer 40 from the RF bias power generators 125, 125′ can heat the wafer 40 to temperatures beyond 400 degrees C., depending upon the level and duration of the applied RF plasma bias power. It is believed that about 80% or more of the RF power is dissipated as heat in the wafer 40.
The electrostatic chuck 14 of
The chuck 14 has a top layer 60, referred to as a puck, consisting of insulative or semi-insulative material, such as aluminum nitride or aluminum oxide, which may be doped with other materials to control its electrical and thermal properties. A metal (molybdenum, for example) wire mesh or metal layer 62 inside of the puck 60 forms a cathode (or electrode) to which the chucking voltage and RF bias power is applied via a coaxial cable 210. The puck 60 may be formed as a ceramic. Or, it may be formed by plasma or physical deposition processes, or chemical vapor deposition process or plasma or flame spray coating or other method. It is supported on a metal layer 64, preferably consisting of a metal having a high thermal conductivity, such as aluminum. The metal layer 64 rests on a highly insulative layer 66 whose thickness, dielectric constant and dielectric loss tangent are chosen to provide the chuck 14 with selected RF characteristics (e.g., capacitance, loss resistance) compatible with the reactor design and process requirements. A metal base layer 68 is connected to ground. The wafer 40 is held on the chuck 14 by applying a D.C. voltage from the chucking voltage source 48 to the electrode 62. The application of voltage across the insulator layer 60 polarizes the insulator 60 and induces an opposite (attractive) image charge in the bottom surface of the wafer 40. In the case of a semi-insulator layer 60, in addition to inducing image charge in the bottom surface of the wafer, charge from the electrode 62 migrates through the semi-insulator layer 60 to accumulate very close to the top surface of the semi-insulator layer 60, for a minimum gap between the charge and the overlying wafer 40. (The term “semi-insulator” is discussed below.) This induces an opposite (attractive) image charge in the bottom surface of the wafer 40. The effective gap between the two opposing charge layers is so minimal as a result of the upward charge migration in the insulator layer 60 that the attractive force between the chuck and the wafer 40 is very large for a relatively small applied chucking voltage. For example, a chucking voltage of only 300 volts D.C. on the electrode 62 produces a chucking force across the wafer 40 equivalent to a pressure of about 100 Torr. The puck semi-insulator layer 60 therefore is formed of a material having a desired charge mobility, so that the material is not a perfect insulator (hence, the term “semi-insulator”). This semi-insulator material, although not a perfect insulator, may also not be a typical semiconductor, in some cases. In any case, the charge induced by the chucking voltage on the electrode 62 is mobile in the semi-insulator material of the puck layer 60, and therefore it may be said that the puck semi-insulator layer 60 is formed of a “charge mobile” material. One example of a material suitable for the puck semi-insulator or charge mobile layer 60 is aluminum nitride. Another example is aluminum oxide, which may optionally be doped to increase charge mobility. For example, the dopant material may be titanium dioxide.
RF bias power from the RF bias power generators 125, 125′ may be applied through the impedance match circuit 130 to the electrode 62 or, alternatively, to the metal layer 64 for RF coupling through the semi-insulative puck layer 60.
A very high heat transfer coefficient between the wafer 40 and the puck 60 is realized by maintaining a very high chucking force. A suitable range for this force depends upon the anticipated heat loading of the wafer, and will be discussed later in this specification. The heat transfer coefficient (having units of Watts/m2° K or heat flux density for a given temperature difference) of the wafer-to-puck contacting surfaces is adequate to remove heat at the rate heat is deposited on the wafer. Specifically, the heat transfer coefficient is adequate because during plasma processing it either limits the wafer temperature below a specified maximum temperature or limits the time rate of rise of the wafer temperature below a maximum rate of rise. The maximum wafer temperature may be selected to be anywhere in a practical range from on the order to 100 degrees C. or higher, depending upon the heat load. The maximum rate of heat rise during processing may be anywhere in a range from 3 to 20 degrees per second. Specific examples may be 20 degrees per second, or 10 degrees per second or 3 degrees per second. By comparison, if the wafer is un-cooled, the rate of heat rise may be 86.7 degrees per second in the case of a typical 300 mm silicon wafer with a heat load of 7500 Watts, 80% of which is absorbed by the wafer. Thus, the rate of temperature rise is reduced to one-fourth of the un-cooled rate of heat rise in one embodiment of the invention.
Such performance is accomplished, first, by maintaining the puck at a sufficiently low temperature (for example, about 80° C. below the target wafer temperature), and second, by providing the top surface of the puck 60 with a sufficiently smooth finish (e.g., on the order of ten's of micro-inches RMS deviation, or preferably on the order of micro-inches RMS deviation). For this purpose, the top surface 60a of the puck 60 can be highly polished to a finish on the order of about 2 micro-inches RMS deviation, for example. Furthermore, heat is removed from the puck 60 by cooling the metal layer 64. For this reason, internal coolant passages 70 are provided within the metal layer 64 coupled to a coolant pump 72 and heat sink or cooling source 74. In an alternative embodiment, the internal cooling passages 70 may extend into the puck 60 or adjacent its back surface in addition or instead of extending through the metal layer 64. In any case, the coolant passages 70 are thermally coupled to the puck 60, either directly or through the metal layer 64, and are for cooling the puck 60. The coolant liquid circulating through the internal passages 70 can be water, ethylene glycol or a mixture, for example. Alternatively, the coolant may be a perfluorinated heat transfer liquid such as “fluorinert” (made by 3M company). Unlike the internal gas coolant passages of conventional chucks, this feature presents little or no risk of arcing in the presence of high RF bias power applied to the chuck 14 by the RF bias power generator 125.
One advantage of such contact-cooling of the wafer over the conventional method employing a coolant gas is that the thermal transfer efficiency between the coolant gas and each of the two surfaces (i.e., the puck surface and the wafer bottom surface) is very limited, in accordance with the thermal accommodation coefficient of the gas with the materials of the two surfaces. The heat transfer rate is attenuated by the product of the gas-to-wafer thermal accommodation coefficient and the gas-to-puck thermal accommodation coefficient. If both coefficients are about 0.5 (as a high rough estimate), then the wafer-gas-puck thermal conductance is attenuated by a factor of about 0.25. In contrast, the contact-cooling thermal conductance in the present invention has virtually no such attenuation, the thermal accommodation coefficient being in effect unity for the chuck 14 of
The heat transfer coefficient between the wafer 40 and the puck 60 in the wafer contact-cooling electrostatic chuck 14 is affected by the puck top surface finish and the chucking force. These parameters can be adjusted to achieve the requisite heat transfer coefficient for a particular environment. An important environmental factor determining the required heat transfer coefficient is the applied RF bias power level. It is believed that at least 80% of the RF bias power from the bias generator 125 is dissipated as heat in the wafer 40. Therefore, for example, if the RF bias power level is 7500 Watts and 80% of the RF bias power from the bias generator 125 is dissipated as heat in the wafer 40, if the wafer area is 706 cm2 (300 mm diameter wafer) and if a 80 degrees C. temperature difference is allowed between the wafer 40 and the puck 60, then the required heat transfer coefficient is h=7500×80% Watts/(706 cm2×80 degrees K), which is 1071 Watts/m2° K. For greater RF bias power levels, the heat transfer coefficient can be increased by augmenting any one or both of the foregoing factors, namely the temperature drop across the puck, the chucking force or the smoothness of the puck surface. Such a high heat transfer coefficient, rarely attained in conventional electrostatic chucks, is readily attained in the electrostatic chuck 14 of
In addition, the heat transfer is improved by providing more puck surface area available for direct contact with the wafer backside. In a conventional chuck, the puck surface available for wafer contact is greatly reduced by the presence of open coolant gas channels machined, ground or otherwise formed in the puck surface. These channels occupy a large percentage of the puck surface.
Dual Bias Power Frequencies for Enhanced Etch Performance:
The reactor of
Wafer Contact Force Feedback Control:
Conventional sensing circuits 132 within the impedance match circuit 130 have output terminals 133 providing signals indicating, respectively, the low frequency voltage V(f1), current I(f1) and (optionally) power Pbias(f1), and the high frequency voltage V(f2), current I(f2) and (optionally) power Pbias(f2) furnished at the output of the impedance match circuit 130 to the wafer support pedestal 14. A measurement instrument 140 uses the signals from the output terminals 133 to measure the voltage on the wafer 40. The measurement instrument 140 employs processes based upon an electrical model of the reactor 100 discussed below. A processor 80 periodically computes the D.C. voltage of the wafer 40. A subtractor 82 computes the net chucking voltage as the difference between the D.C. wafer voltage and the D.C. voltage applied to the pedestal 14 by the chucking voltage source 48. A feedback controller 84 compares the net chucking voltage provided by the subtractor 82 with a desired net chucking voltage to determine an error, and applies a corrective signal to change the D.C. output of the D.C. voltage supply 48 so as to reduce this error. The desired net chucking voltage may be furnished by a wafer temperature control processor that translates a user-commanded wafer temperature to a desired net chucking voltage.
Measurement of the Wafer Voltage With a Correction for Intermodulation Products of f1 and f2:
Referring to
Vin{ cos h [(Vch)(−length)]}+Iin{Zch sin h[(Vch)(−length)]}
so that one constant is cos h [(Vch)(−length)] and the other constant is Zch sin h [(Vch)(−length)]. These two constants are referred to herein as K1 and K2, respectively. Zch is the characteristic impedance of the coaxial cable 210, Vch is the complex phase velocity of the cable 210 and “length” is the cable length. The voltage Vwafer at the wafer 40 is obtained by incorporating into each of the constants the factor Zwafer/Zgrid, in accordance with the operation of the processor 520 of
K1=(Zwafer/Zgrid)cos h [(Vch)(−length)]
K2=(Zwafer/Zgrid)Zch sin h [(Vch)(−length)].
The foregoing is valid for a single bias frequency, in accordance with the referenced application. Each of the parameters Zwafer, Zgrid and Vch is evaluated at the particular bias frequency, so that K1 and K2 depend upon frequency.
In the reactor of
In order to determine the total D.C. voltage on the wafer attributable to both frequency components, we have found significant errors occur when a simple addition of the two frequency components, VDC(f1)+VDC(f2), is employed. This is because such a simple addition does not take into account the effects of intermodulation between the two bias frequencies. As discussed earlier in this specification, the error can exceed the capacity of the chucking D.C. voltage supply 48. Therefore, a correction factor is subtracted from the result, the correction factor containing the product of the two D.C. voltage components VDC(f1), VDC(f2). The combination of the simple sum and the correction factor is carried out by a processor 94 to determine total D.C. voltage on the wafer:
VDC(total)=VDC(f1)+VDC(f2)+E{[VDC(f1)][VDC(f2)]}F
Where E and F are constants. Theoretically, F=½ and E=1, but in practical application we have found superior results are obtained with F=0.43 and E=1. This provides a highly accurate measurement of the D.C. voltage on the wafer, VDC(wafer), which is the input to the feedback control loop 82, 84, 48 governing the ESC clamping force applied to the wafer. The subtractor 82 determines the net wafer clamping voltage, ΔVDC, as the difference between the measured D.C. wafer voltage from the processor 80, VDC(total), and the D.C. voltage output by the D.C. chuck voltage supply 48. The feedback controller 84 compares this value with a desired clamping voltage to determine an error, and changes the output of the ESC D.C. voltage supply 48 so as to reduce this error.
Measurement of the Wafer Voltage Based Upon the Electrical Characteristics of the Chamber:
The electrical model depicted in
In one implementation, the measurement instrument 140 of
The LF Measurement Instrument Section 140a:
Referring to
In summary, electrical measurements are made at the output of the impedance match circuit 130. The transmission line transformation processor 320 transforms these measurements at the near end of the cable 210 to a voltage at the far end. The grid to ground transformation processor 340 provides the transformation from the ground plane 64 near the far end of the cable to the conductive grid 62. The grid-to-wafer transformation processor 350 provides the transformation from the conductive grid 62 to the wafer 40.
The transmission line model 330, the model of the grid-to-ground capacitance 345 and the model 355 of the grid-to-wafer capacitance are not necessarily a part of the measurement instrument 140. Or, they may be memories within the measurement instrument 140 that store, respectively, the coaxial cable parameters (Vch(f1) and Zch), the grid-to-ground capacitance parameters (gap, ∈D, tanD(f1) and radius) and the grid-to-wafer capacitance parameters (gapP, ∈P, tanP(f1) and radius).
Iin(f1){ cos h [Vch(f1)(−length)]}+Vin(f1){(1/Zch)sin h [Vch(f1)(−length)]}
A junction voltage ALU 520 computes the voltage Vjunction(f1) at the junction between the coaxial cable 210 and the grid 62 as:
Vin(f1){ cos h [(Vch(f1)(−length)]+Iin(f1){Zch sin h [Vch(f1)(−length)]}
A divider 530 receives Ijunction and Vjunction computes Yjunction as Ijunction/Vjunction. Each of the electrical quantities in the foregoing computations (current, voltage, impedance, admittance, etc.) may be a complex number having both a real part and an imaginary part.
(∈0)(∈D)π(rad)2/gap
where ∈0 is the electrical permittivity of free space. An RD ALU 620 uses the value of CD from the CD ALU 610 and computes the dielectric resistance RD(f1) as follows:
(tanD(f1))/(2π)(f1)CD gap2)
(∈0)(∈P)π(rad)2/gapP
where ∈0 is the electrical permittivity of free space. An RP ALU 720 uses the value of CP from the CP ALU 710 and computes the plasma resistance RP(f1) as follows:
(tanP(f1))/((2π)(f1)CP gapD2)
[Yjunction(f1)−1/(RD(f1)+(1/(i2π(f1)CD)))]−1
A wafer impedance ALU 820 uses the output of the grid impedance ALU 810 to compute Zwafer (the impedance at the wafer 40 of
Zgrid(f1)−1/(RP(f1)+(1/(i2π(f1)CP)))
A wafer voltage ALU 830 uses the outputs of both ALUs 810 and 820 and Vjunction(f1) from the divider 530 of
It should be noted that the exact computation of Zgrid(f1) depends upon both Vin(f1) and Iin(f1) in respective transmission line equations for the voltage and current Vjunction(f1), Ijunction(f1) as described above, so that Zgrid(f1) is not necessarily a constant. In order to simplify the computation of the wafer voltage Vwafer(f1), the factor Zwafer(f1)/Zgrid(f1) is ignored (assigned a value of unity) Alternatively, the computation may be simplified by choosing an average value of Zgrid(f1) within an applicable operating process window as a constant to replace the exact computation of Zgrid(f1) in the determination of Vwafer(f1). With this simplification, the factor Zwafer(f1)/Zgrid(f1) becomes a constant, so that the determination of the wafer voltage Vwafer(f1) by ALU 380 becomes multiplication of the cable/electrode junction voltage Vjunction(f1) by a constant (i.e., by the factor Zwafer(f1)/Zgrid(f1). This may reduce the accuracy slightly but has the advantage of simplifying the computation of Vwafer(f1).
If desired, a processor 840 produces a measured wafer current by dividing the wafer voltage Vwafer(f1) by the wafer impedance Zwafer(f1).
The HF Measurement Instrument Section 140b:
Referring to
In summary, electrical measurements are made at the output of the impedance match circuit 130. The transmission line transformation processor 320′ transforms these measurements at the near end of the cable 210 to a voltage at the far end. The grid to ground transformation processor 340′ provides the transformation from the ground plane 64 near the far end of the cable to the conductive grid 62. The grid-to-wafer transformation processor 350′ provides the transformation from the conductive grid 62 to the wafer 40.
The transmission line model 330′, the model of the grid-to-ground capacitance 345 and the model 355 of the grid-to-wafer capacitance are not necessarily a part of the measurement instrument 140. Or, they may be memories within the measurement instrument 140 that store, respectively, the coaxial cable parameters (Vch(f2) and Zch), the grid-to-ground capacitance parameters (gap, ∈D, tanD(f2) and radius) and the grid-to-wafer capacitance parameters (gapP, ∈P, tanP(f2) and radius).
Iin(f2){ cos h [Vch(f2)(−length)]}+Vin(f2){(1/Zch)sin h [Vch(f2)(−length)]}.
A junction voltage ALU 520′ computes the voltage Vjunction(f2) at the junction between the coaxial cable 210 and the grid 62 as:
Vin(f2){ cos h [(Vch(f2)(−length)]+Iin(f2){Zch sin h [Vch(f2)(−length)]}.
A divider 530′ receives Ijunction and Vjunction computes Yjunction as Ijunction/Vjunction. Each of the electrical quantities in the foregoing computations (current, voltage, impedance, admittance, etc.) may be a complex number having both a real part and an imaginary part.
(∈0)(∈D)π(rad)2/gap
where ∈0 is the electrical permittivity of free space. An RD ALU 620′ uses the value of CD from the CD ALU 610′ and computes the dielectric resistance RD(f2) as follows:
(tanD(f2))(2π)(f1)CD gap2)
(∈0)(∈P)π(rad)2/gapP
where ∈0 is the electrical permittivity of free space. An RP ALU 720′ uses the value of CP from the CP ALU 710′ and computes the plasma resistance RP(f2) as follows:
(tanP(f2))/((2π)(f1)CP gapD2)
[Yjunction(f2)−1/(RD(f2)+(1/(i2π(f1)CD)))]−1
A wafer impedance ALU 820′ uses the output of the grid impedance ALU 810′ to compute Zwafer (the impedance at the wafer 120 of
Zgrid(f2)−1/(RP(f2)+(1/(i2π(f1)CP)))
A wafer voltage ALU 830′ uses the outputs of both ALUs 810′ and 820′ and Vjunction(f2) from the divider 530′ of
Vjunction(f2)Zwafer(f2)/Zgrid(f2).
It should be noted that the exact computation of Zgrid(f2) depends upon both Vin(f2) and Iin(f2) in respective transmission line equations for the voltage and current Vjunction(f2), Ijunction(f2) as described above, so that Zgrid(f2) is not necessarily a constant. In order to simplify the computation of the wafer voltage Vwafer(f2), the factor Zwafer(f2)/Zgrid(f2) is ignored (assigned a value of unity). Alternatively, in order to simplify the calculation, an average value of Zgrid(f2) within an applicable operating process window may be chosen as a constant to replace the exact computation of Zgrid(f2) in the determination of Vwafer(f2). With this simplification, the factor Zwafer(f2)/Zgrid(f2) becomes a constant, so that the determination of the wafer voltage Vwafer(f2) by ALU 830′ becomes multiplication of the cable/electrode junction voltage Vjunction(f2) by a constant (i.e., by the factor Zwafer(f2)/Zgrid(f2)). This may reduce the accuracy slightly but has the advantage of simplifying the computation of Vwafer(f2).
If desired, the wafer current at f2 may be measured by a processor 840′ that divides the wafer voltage Vwafer(f2) by the wafer impedance Zwafer(f2).
Determination of the Constants Used by the Processors of
The two measurement instrument sections 140a, 140b provide the LF and HF components of the wafer voltage Vwafer(f1), Vwafer(f2), respectively. These two components are used in the processor of
K1(f1)=[Zwafer(f1)/Zgrid(f1)] cos h [Vch(f1)(−length)]
K2(f1)=[Zwafer(f1)/Zgrid(f1)]Zch sin h [Vch(f1)(−length)]
The HF constants K1(f2), K2(f2) employed by the processor 91 of
K1(f2)=[Zwafer(f2)/Zgrid(f2)] cos h [Vch(f2)(−length)]
K2(f2)=[Zwafer(f2)/Zgrid(f2)]Zch sin h [Vch(f2)(−length)]
In a highly efficient implementation, phase information from the sensor 132 is not required. In this implementation, the phase processor 310 is not employed and the sensor voltages and currents V(f1), I(f1), V(f2), I(f2) are multiplied by the constants stored in the registers 90a, 90b, 91a, 91b in the manner shown in
While each operation performed in the measurement instrument 140 has been described with respect to a separate processor, several of the processors within the measurement instrument 140 may be realized in a single processor whose resources are shared to perform the different operations at different times. Or, all of the processors in the measurement instrument 140 are realized by a single processor that is a shared resource among the different operations performed by the measurement instrument, so that the measurement instrument 140 may be realized as computer using a central processing unit (CPU) to perform all the operations.
The phase processors 310a, 310b transform the measured values of the voltage and current sensed by the sensor 132 into input voltages and currents Vin(f1), Iin(f1), Vin(f2), Iin(f2). For purposes of the claims below, therefore, the phase processors 310a, 310b may be considered to be part of the sensor 132, so that the outputs Vin(f1), Iin(f1), Vin(f2), Iin(f2) of the phase processors 310, 310b are considered as the measured voltages and currents from the sensor 132. In fact, in some cases it may be possible to eliminate or bypass the phase processors 310.
The use of stored constants K1(f1), K2(f1), K1(f2), K2(f2) greatly simplifies the computations of the wafer voltage frequency components by reducing them to simple multiplications of the sensed current and voltage by respective constants and summations of the resulting products. This makes it unnecessary to measure phase in order to determine the wafer voltage.
Some Advantages of the Invention:
The invention may be used with a Johnson-Raybeck electrostatic chuck (ESC) (i.e., the type of ESC depicted in
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.
This application is a divisional of U.S. patent application Ser. No. 11/127,036, filed May 10, 2005 entitled DUAL BIAS FREQUENCY WITH FEEDBACK CONTROL OF E.S.C. VOLTAGE USING WAFER VOLTAGE MEASUREMENT AT THE BIAS SUPPLY OUTPUT by Jang Gyoo Yang, et al. and assigned to the present assignee.
Number | Name | Date | Kind |
---|---|---|---|
2951960 | Watrous, Jr. | Sep 1960 | A |
2967926 | Edstrom | Jan 1961 | A |
3355615 | Bihan et al. | Nov 1967 | A |
3610986 | King | Oct 1971 | A |
4458180 | Sohval | Jul 1984 | A |
4464223 | Gorin | Aug 1984 | A |
4570106 | Sohval et al. | Feb 1986 | A |
4579618 | Celestino et al. | Apr 1986 | A |
4859908 | Yoshida et al. | Aug 1989 | A |
4888518 | Grunwald | Dec 1989 | A |
4973883 | Hirose et al. | Nov 1990 | A |
4990229 | Campbell et al. | Feb 1991 | A |
5006760 | Drake, Jr. | Apr 1991 | A |
5017835 | Oechsner | May 1991 | A |
5032202 | Tsai et al. | Jul 1991 | A |
5053678 | Koike et al. | Oct 1991 | A |
5055853 | Garnier | Oct 1991 | A |
5077499 | Oku | Dec 1991 | A |
5089083 | Kojima et al. | Feb 1992 | A |
5107170 | Ishikawa et al. | Apr 1992 | A |
5115167 | Ootera et al. | May 1992 | A |
5122251 | Campbell et al. | Jun 1992 | A |
5140223 | Gesche et al. | Aug 1992 | A |
5175472 | Johnson et al. | Dec 1992 | A |
5195045 | Keane et al. | Mar 1993 | A |
5198725 | Chen et al. | Mar 1993 | A |
5210466 | Collins et al. | May 1993 | A |
5213658 | Ishida | May 1993 | A |
5218271 | Egorov et al. | Jun 1993 | A |
5223457 | Mintz et al. | Jun 1993 | A |
5225024 | Hanley et al. | Jul 1993 | A |
5246532 | Ishida | Sep 1993 | A |
5256931 | Bernadet | Oct 1993 | A |
5272417 | Ohmi | Dec 1993 | A |
5273610 | Thomas, III et al. | Dec 1993 | A |
5274306 | Kaufman et al. | Dec 1993 | A |
5279669 | Lee | Jan 1994 | A |
5280219 | Ghanbari | Jan 1994 | A |
5300460 | Collins et al. | Apr 1994 | A |
5314603 | Sugiyama et al. | May 1994 | A |
5325019 | Miller et al. | Jun 1994 | A |
5401351 | Samukawa | Mar 1995 | A |
5432315 | Kaji et al. | Jul 1995 | A |
5453305 | Lee | Sep 1995 | A |
5463525 | Barnes et al. | Oct 1995 | A |
5467013 | Williams et al. | Nov 1995 | A |
5474648 | Patrick et al. | Dec 1995 | A |
5512130 | Barna et al. | Apr 1996 | A |
5534070 | Okamura et al. | Jul 1996 | A |
5537004 | Imahashi et al. | Jul 1996 | A |
5554223 | Imahashi | Sep 1996 | A |
5556549 | Patrick et al. | Sep 1996 | A |
5567268 | Kadomura | Oct 1996 | A |
5576600 | McCrary et al. | Nov 1996 | A |
5576629 | Turner et al. | Nov 1996 | A |
5587038 | Cecchi et al. | Dec 1996 | A |
5592055 | Capacci et al. | Jan 1997 | A |
5595627 | Inazawa et al. | Jan 1997 | A |
5605637 | Shan et al. | Feb 1997 | A |
5618382 | Mintz et al. | Apr 1997 | A |
5627435 | Jansen et al. | May 1997 | A |
5660671 | Harada et al. | Aug 1997 | A |
5662770 | Donohoe | Sep 1997 | A |
5674321 | Pu et al. | Oct 1997 | A |
5685914 | Hills et al. | Nov 1997 | A |
5705019 | Yamada et al. | Jan 1998 | A |
5707486 | Collins | Jan 1998 | A |
5710486 | Ye et al. | Jan 1998 | A |
5720826 | Hayashi et al. | Feb 1998 | A |
5733511 | De Francesco | Mar 1998 | A |
5770922 | Gerrish et al. | Jun 1998 | A |
5792376 | Kanai et al. | Aug 1998 | A |
5846885 | Kamata et al. | Dec 1998 | A |
5849136 | Mintz et al. | Dec 1998 | A |
5849372 | Annaratone et al. | Dec 1998 | A |
5855685 | Tobe et al. | Jan 1999 | A |
5858819 | Miyasaka | Jan 1999 | A |
5863376 | Wicker et al. | Jan 1999 | A |
5866986 | Pennington | Feb 1999 | A |
5868848 | Tsukamoto | Feb 1999 | A |
5885358 | Maydan et al. | Mar 1999 | A |
5904799 | Donohoe | May 1999 | A |
5914568 | Nonaka | Jun 1999 | A |
5929717 | Richardson et al. | Jul 1999 | A |
5936481 | Fiji | Aug 1999 | A |
5939886 | Turner et al. | Aug 1999 | A |
5942074 | Lenz et al. | Aug 1999 | A |
5971591 | Vona et al. | Oct 1999 | A |
5997962 | Ogasawara et al. | Dec 1999 | A |
6016131 | Sato et al. | Jan 2000 | A |
6043608 | Samukawa et al. | Mar 2000 | A |
6089182 | Hama | Jul 2000 | A |
6093457 | Okumura et al. | Jul 2000 | A |
6095084 | Shamouilian et al. | Aug 2000 | A |
6096160 | Kadomura | Aug 2000 | A |
6106663 | Kuthi et al. | Aug 2000 | A |
6110395 | Gibson, Jr. | Aug 2000 | A |
6113731 | Shan et al. | Sep 2000 | A |
6142096 | Sakai et al. | Nov 2000 | A |
6152071 | Akiyama et al. | Nov 2000 | A |
6155200 | Horijke et al. | Dec 2000 | A |
6162709 | Raoux et al. | Dec 2000 | A |
6174450 | Patrick et al. | Jan 2001 | B1 |
6188564 | Hao | Feb 2001 | B1 |
6213050 | Liu et al. | Apr 2001 | B1 |
6218312 | Collins et al. | Apr 2001 | B1 |
6245190 | Masuda et al. | Jun 2001 | B1 |
6251216 | Okamura et al. | Jun 2001 | B1 |
6262538 | Keller | Jul 2001 | B1 |
6290806 | Donohoe | Sep 2001 | B1 |
6291999 | Nishimori et al. | Sep 2001 | B1 |
6337292 | Kim et al. | Jan 2002 | B1 |
6346915 | Okumura et al. | Feb 2002 | B1 |
RE37580 | Barnes et al. | Mar 2002 | E |
6449568 | Gerrish | Sep 2002 | B1 |
6451703 | Liu et al. | Sep 2002 | B1 |
6462481 | Holland et al. | Oct 2002 | B1 |
6528751 | Hoffman et al. | Mar 2003 | B1 |
6586886 | Katz et al. | Jul 2003 | B1 |
6652712 | Wang et al. | Nov 2003 | B2 |
6727655 | McChesney et al. | Apr 2004 | B2 |
6894245 | Hoffman et al. | May 2005 | B2 |
20020108933 | Hoffman et al. | Aug 2002 | A1 |
20020139477 | Ni et al. | Oct 2002 | A1 |
20030132195 | Edamura et al. | Jul 2003 | A1 |
20030168427 | Flamm et al. | Sep 2003 | A1 |
Number | Date | Country |
---|---|---|
0 343 500 | Nov 1989 | EP |
0 678 903 | Oct 1995 | EP |
0 719 447 | Jul 1998 | EP |
WO 0171765 | Sep 2001 | WO |
Number | Date | Country | |
---|---|---|---|
20070127188 A1 | Jun 2007 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 11127036 | May 2005 | US |
Child | 11672362 | US |