JP4515755B2 - Processing equipment - Google Patents

Description

  The present invention relates to a processing apparatus that performs a desired process on a substrate to be processed on a mounting table in a processing chamber, and more particularly to a processing apparatus that heats a substrate on the mounting table.

  In processes such as single-wafer etching, deposition, oxidation, and sputtering used to manufacture semiconductor devices and FPDs (Flat Panel Displays), a substrate to be processed is mounted on a mounting table in a vacuum processing container. The processing gas is supplied into the processing container while keeping the temperature of the substrate constant on the mounting table. At that time, plasma is often used to promote ionization, chemical reaction, and the like of the processing gas.

  Substrate temperature control in this type of process is broadly divided into a cooling method that cools the substrate on the mounting table to a constant temperature, and a heating method that heats the substrate on the mounting table and controls it to a constant temperature. being classified. Conventionally, as a heating method, a plasma heat input method in which a substrate is heated by incident heat from plasma, a lamp heating method in which a lamp is provided above the mounting table and the substrate is heated by radiant heat from the lamp, and a mounting table There is known a hot plate system in which a heating wire is provided inside the substrate and the substrate is heated by resistance heating of the heating wire. In the hot plate method, in order to improve the efficiency and uniformity of transferring heat from the mounting table to the substrate, an electrostatic chuck is provided on the upper or upper surface of the mounting table, and the substrate is pressed against the mounting table by the electrostatic chucking force of the electrostatic chuck. I am doing so.

  However, the plasma heat input method has a drawback that the substrate temperature is easily affected by fluctuations in the plasma, and independent independent temperature control that does not depend on the plasma cannot be expected. In addition, the lamp heating method has a problem that it is difficult to attach the lamp to the processing vessel in terms of mechanism and space. In particular, in a parallel plate type plasma processing apparatus, since the mounting table is a lower electrode and the upper electrode is disposed opposite to the mounting electrode, it is normal that a space for arranging a lamp in the processing container cannot be secured. The hot plate method has a problem in that the structure inside the mounting table becomes complicated and the manufacturing cost increases because the heating wire is incorporated into the mounting table and the power supply line from the external heater power supply is drawn to the heating wire. In particular, when an electrostatic chuck is used, the configuration in which the installation of the heating wire and the feeding line and the feeding line with respect to the electrostatic chuck are both compatible or coexist in the mounting table is very complicated and requires a great deal of manufacturing. Cost is required.

  The present invention has been made in view of the above-described problems of the prior art, and the temperature of the substrate to be processed on the mounting table by a heating method that does not complicate the inside of the mounting table or install a special heating mechanism. It is an object of the present invention to provide a processing apparatus that can arbitrarily control the process.

The processing apparatus of the present invention includes a processing container capable of generating or introducing plasma, a first electrode for placing a substrate to be processed in the processing container, an electrode unit provided on the first electrode, An electrostatic chuck having a dielectric that sandwiches the electrode part from above and below, a DC power source that applies a DC voltage for electrostatic attraction to the electrode part of the electrostatic chuck via a first power supply line, An output terminal is electrically connected to the first electrode via a second power supply line, and is set in the middle of the first power supply line and a first high-frequency power source that outputs a first high-frequency for heating A high-frequency bypass circuit that cuts off the direct current from the direct-current power source and passes the first high-frequency between the first node and the other output terminal of the first high-frequency power source; Through the second power supply line and the second power supply line. A second high-frequency power source that is electrically connected to the first electrode and outputs a second high-frequency for high-frequency bias, and the first feed line closer to the electrode portion of the electrostatic chuck than the first node. A first part provided in the middle for passing the DC voltage from the DC power supply and passing the first high frequency from the first high frequency power supply, and blocking the second high frequency from the second high frequency power supply. The first high-frequency power source, the second power supply line, the electrode portion of the electrostatic chuck, the first power supply line, the first filter circuit, and the high-frequency bypass circuit. The first high-frequency current output from the first high-frequency power source flows in a closed circuit including the substrate, and the substrate on the mounting table is heated by Joule heat of the electrode portion of the electrostatic chuck. .

In the processing apparatus of the present invention , the first high-frequency current output from the first high-frequency power source flows through the electrodes of the electrostatic chuck through the first and second power supply lines, so that the electrode section is heated by Joule heat. Heat is generated and the substrate on the mounting table is heated by heat conduction. Here, the first power supply line is also used to apply a DC voltage for electrostatic attraction from a DC power source to the electrode portion of the electrostatic chuck. The second power supply line is also used to supply a second high frequency for high frequency bias from a second high frequency power supply to the first electrode. In the first power supply line, both the high-frequency power supply for heating and the DC power supply for electrostatic adsorption can be made compatible by the action of the high-frequency bias circuit.

  According to a preferred aspect of the present invention, the second power supply line is located closer to one output terminal of the first high-frequency power supply than the second node to which the third power supply line and the second power supply line are connected. On the way, a second filter circuit is provided that passes the first high frequency from the first high frequency power supply and blocks the second high frequency from the second high frequency power supply. With this second filter circuit, the first high-frequency power source can be protected from the second high-frequency for high-frequency bias, and the second power supply line can be shared by the first high-frequency and the second high-frequency. Preferably, a third filter circuit that passes the second high frequency from the second high frequency power supply and blocks the first high frequency from the first high frequency power supply is provided in the middle of the third power supply line. It's okay. The third filter circuit can protect the second high frequency power source from the first high frequency for heating.

  According to one preferable aspect of the present invention, the second electrode is disposed in the processing container so as to face the first electrode with a desired interval. In this case, the second high frequency supplied from the second high frequency power supply to the first electrode can also serve as a high frequency for generating plasma between the first electrode and the second electrode. Alternatively, the third high frequency for plasma generation can be supplied from the third high frequency power source to the second electrode via the fourth power supply line. In the first power supply line, the first filter circuit preferably blocks the third high frequency from the third high frequency power supply.

  According to the processing apparatus of the present invention, the temperature and temperature of the substrate to be processed on the mounting table can be arbitrarily set by a heating method that does not involve complicated installation inside the mounting table or installation of a special heating mechanism. Can be controlled.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

  FIG. 1 shows the configuration of a plasma etching apparatus according to the first embodiment of the present invention. This plasma etching apparatus is configured as a parallel plate type plasma etching apparatus, and has, for example, a cylindrical chamber (processing vessel) 10 made of aluminum whose surface is anodized (anodized). The chamber 10 is grounded for safety.

  A cylindrical support base 14 made of, for example, aluminum is disposed on the bottom of the chamber 10 via an insulating plate 12 such as ceramic, and a disk-like susceptor 16 made of, for example, aluminum is provided on the support base 14. Yes. The susceptor 16 serves as both a mounting table and a lower electrode, on which, for example, a semiconductor wafer W is mounted as a substrate to be processed.

  An electrostatic chuck 18 is provided on the upper surface of the susceptor 16 to hold the semiconductor wafer W with Coulomb force or Johnson Rabeck force. The electrostatic chuck 18 is obtained by sandwiching an electrode portion 20 made of a conductive plate or a conductive film between a pair of dielectric or insulator sheets 22 and 24, and a DC power source is connected to the electrode portion 20 via a power supply line 26. 28 output terminals are electrically connected. The semiconductor wafer W is attracted and held on the electrostatic chuck 18 by a Coulomb force or a Johnson-Rahbek force by a DC voltage from the DC power supply 28. The material of the electrode part 20 is preferably a refractory metal such as tungsten, molybdenum, or nickel. The power supply line 26 is housed in an insulating sheath (not shown) penetrating from the bottom of the chamber 10 through the chamber bottom plate, the insulating plate 12, the support 14 and the susceptor 16, and is preferably an electrode portion of the electrostatic chuck 18. It may be connected to 20 central parts.

  A focus ring 30 made of, for example, silicon is disposed on the upper surface of the susceptor 16 around the electrostatic chuck 18 to improve etching uniformity. A cylindrical inner wall member 32 made of, for example, quartz is attached to the side surfaces of the susceptor 16 and the support base 14.

  A coolant chamber 34 extending in the circumferential direction, for example, is provided inside the support base 14. A refrigerant of a predetermined temperature, for example, cooling water, is circulated and supplied to the refrigerant chamber 34 via pipes 36a and 36b from an external chiller unit (not shown). The processing temperature of the semiconductor wafer W on the susceptor 16 can be controlled by the temperature of the refrigerant.

  Above the susceptor 16, a shower head 38 is provided as an upper electrode of the ground potential so as to face the susceptor in parallel. The shower head 38 has a lower electrode plate 40 having a large number of gas vent holes 40a, and an electrode support 42 for detachably supporting the electrode plate 40. A buffer chamber 44 is provided inside the electrode support 42, and a gas supply pipe 48 from the processing gas supply unit 46 is connected to a gas inlet 44 a of the buffer chamber 44. A ring-shaped insulating shielding member 49 made of alumina, for example, is airtightly attached between the shower head 38 and the side wall of the chamber 10.

  An exhaust port 50 is provided at the bottom of the chamber 10, and an exhaust device 54 is connected to the exhaust port 50 via an exhaust pipe 52. The exhaust device 54 has a vacuum pump such as a turbo molecular pump, and can depressurize the plasma processing space in the chamber 10 to a desired degree of vacuum. A gate valve 56 that opens and closes the loading / unloading port of the semiconductor wafer W is attached to the side wall of the chamber 10.

  In the plasma etching apparatus of this embodiment, three high-frequency power sources 58, 60, and 62 are provided outside the chamber 10.

  The high frequency power source 58 is for heating the electrode portion 20 of the electrostatic chuck 18 by resistance in order to control the temperature of the semiconductor wafer W on the susceptor 16 by a heating method, and one output terminal thereof is connected to the susceptor via the power supply line 64. 16 and the other output terminal is connected to the ground potential, and preferably outputs a frequency within a range of 1 to 100 kHz, for example, a high frequency of 10 kHz, preferably with variable controllable power. The power supply line 64 is housed in an insulating sheath (not shown) that reaches the susceptor 16 through the chamber bottom plate, the insulating plate 12 and the support base 14 from below the chamber 10.

  The high-frequency power supply 60 is for RF bias, and one output terminal thereof is electrically connected to the susceptor 16 via the feed line 66, the node 68 and the feed line 64, and the other output terminal is connected to the ground potential. Preferably, a frequency within the range of 2 to 20 MHz, for example, a high frequency of 2 MHz is output.

  The high-frequency power source 62 is for generating plasma by high-frequency discharge between the upper electrode 38 and the lower electrode 16, and one output terminal thereof is electrically connected to the upper electrode 38 via the power supply line 70, The other output terminal is connected to the ground potential, and preferably outputs a frequency within a range of 50 to 300 MHz, for example, a high frequency of 60 MHz. A matching unit 72 for matching the load impedance to the output impedance of the high frequency power supply 62 may be provided in the middle of the power supply line 70.

  A heating high frequency (10 kHz) from the high frequency power supply 58 is passed in the middle of the power supply line 64 between the high frequency power supply 58 and the node 68, and an RF bias high frequency (2 MHz) from the high frequency power supply 60 and the high frequency power supply 62 are supplied. A low-pass filter (LPF) 74 that cuts off the high frequency (60 MHz) for plasma generation is provided.

  An RF bias high frequency (2 MHz) from the high frequency power supply 60 is passed in the middle of the power supply line 66, and the heating high frequency (10 kHz) from the high frequency power supply 58 and the plasma generating high frequency (60 MHz) from the high frequency power supply 62 are cut off. A band pass filter (BPF) 76 is provided. When providing a high-pass filter (not shown) for passing a plasma-generating high-frequency (60 MHz) from the high-frequency power source 62 between the susceptor 16 and the ground, a high-frequency filter is used instead of the band-pass filter (BPF) 76. A high-pass filter that only cuts off the heating high frequency (10 kHz) from the power source 58 can also be used.

  A matching unit (not shown) for matching the load impedance to the output impedance of the high frequency power supply 60 can be provided in the middle of the power feeding line 66 or in the middle of the power feeding line 64 closer to the susceptor 16 than the node 68.

  On the other hand, in the power supply line 26, a low-pass filter 84 including a resistor 80 and a capacitor 82 is connected between the output terminal of the DC power supply 28 and the node 78, and a capacitor 86, for example, is connected between the node 78 and the ground potential. A high frequency bypass circuit 88 is connected. Further, a filter 90 is provided in the middle of the power supply line 26 closer to the electrostatic chuck 18 than the node 78.

  The filter 90 passes a DC voltage from the DC power supply 28 and a heating high frequency (10 kHz) from the high frequency power supply 58, and a high frequency for RF bias (2 MHz) from the high frequency power supply 60 and a high frequency for plasma generation from the high frequency power supply 62 ( 60 MHz). The high frequency bypass circuit 88 has a function of cutting off the direct current voltage from the direct current power supply 28 and passing the heating high frequency (10 kHz) from the high frequency power supply 58. The low-pass filter 84 has a function of passing a DC voltage from the DC power supply 28 and blocking a heating high frequency (10 kHz) from the high frequency power supply 58.

  In order to perform etching in this plasma etching apparatus, first, the gate valve 56 is opened, and the semiconductor wafer W to be processed is loaded into the chamber 10 and placed on the electrostatic chuck 18. Then, an etching gas (generally a mixed gas) is introduced into the chamber 10 from the processing gas supply unit 46 at a predetermined flow rate and flow rate ratio, and the pressure in the chamber 10 is set to a set value by the exhaust device 54. A DC voltage is applied from the DC power source 28 to the electrode portion 20 of the electrostatic chuck 18 to fix the semiconductor wafer W on the electrostatic chuck 18. Further, a high frequency for RF bias is supplied from the high frequency power supply 60 to the susceptor (lower electrode) 16 with a predetermined power, and a high frequency for plasma generation is supplied from the high frequency power supply 62 to the shower head (upper electrode) 38 with a predetermined power. The etching gas discharged from the shower head 38 is turned into plasma by high-frequency discharge between the electrodes 16 and 38, and the main surface of the semiconductor wafer W is etched by radicals and ions generated by the plasma.

  In this plasma etching apparatus, a heating high frequency (10 kHz) is supplied from the high frequency power source 58 to the electrode portion 20 of the electrostatic chuck 18 through the power supply line 64 and the susceptor 16 with a predetermined power. Since the susceptor 16 and the electrode portion 20 of the electrostatic chuck 18 are AC-coupled or capacitively coupled via the lower dielectric 24 of the electrostatic chuck 18, the high-frequency current from the high-frequency power source 58 is lower than the susceptor 16. It flows into each part of the electrode part 20 of the electrostatic chuck 18 through the body 24. Then, the high-frequency current flowing into each part of the electrode unit 20 passes through the power supply line 26, enters the filter 90 through the power supply line 26, and exits the filter 90, then passes through the high-frequency bypass circuit 88 to the ground, that is, the other of the high-frequency power supply 58. Flows into the output terminal.

  In the cycle in which the polarity of the heating high frequency is reversed, the high frequency current from the other output terminal of the high frequency power supply 58 enters the filter 90 through the high frequency bypass circuit 88, exits the filter 90, and then passes through the feed line 26. It flows into the electrode part 20 of the electrostatic chuck 18. The high-frequency current that has flowed into the electrode unit 20 from the power supply line 26 is capacitively coupled to the susceptor 16 via the lower dielectric 24 from the respective parts of the electrode unit 20, and passes through the power supply line 64 from the susceptor 16 to one of the high-frequency power sources 58. Flows into the output terminal.

  As described above, when a high frequency current from the high frequency power supply 58 flows through the electrode portion 20 of the electrostatic chuck 18, Joule heat is generated in the electrode portion 20, and the Joule heat is applied to the semiconductor wafer W on the electrostatic chuck 18. The semiconductor wafer W is heated by heat conduction and heated. By variably adjusting the output power of the high-frequency power source 58, the heating amount for the semiconductor wafer W can be controlled, and consequently the temperature of the semiconductor wafer W can be controlled. In this embodiment, in order to control the processing temperature of the semiconductor wafer W to a desired temperature, a method of variably adjusting the temperature of the refrigerant supplied from the chiller unit to the refrigerant chamber 34 of the support base 14 is also used.

  As described above, in this embodiment, it is not necessary to provide a special heating mechanism such as a heating wire inside the susceptor 16, and the electrode of the electrostatic chuck 18 for holding the semiconductor wafer W on the susceptor 16. A high frequency for heating is supplied to the unit 20, and the semiconductor wafer W is heated to a desired temperature by Joule heat of the electrode unit 20. In addition, in order to supply the heating high frequency from the high frequency power supply 58 to the electrode portion 20 of the electrostatic chuck 18, the power supply line 64 used also to supply the RF bias high frequency from the high frequency power supply 60 to the susceptor 16; The power supply line 26 that is also used to supply the DC voltage for electrostatic attraction from the DC power source 28 to the electrode portion 20 of the electrostatic chuck 18 is used. In such shared use of the power supply lines 64 and 26, the high frequency power source 58 is protected from a high frequency for RF bias (2 MHz) and a high frequency for plasma generation (60 MHz) by a low-pass filter (LPF) 74. The filter (BPF) 76 protects the high frequency for heating (10 kHz) and the high frequency for plasma generation (60 MHz), and the DC power supply 28 is protected from all high frequencies by the filter 90 and the low-pass filter 84.

  In this embodiment, a high frequency for plasma generation is applied to the upper electrode (shower head) 38, and a high frequency for RF bias is applied to the lower electrode (susceptor) 16. However, the mode of applying a high frequency for plasma generation or RF bias to the upper or lower electrode is arbitrary, and various modes are possible. For example, without applying a high frequency for plasma generation to the upper electrode 38, two types of high frequency for RF bias and plasma generation are applied to the lower electrode 16, or for the RF bias and plasma generation to the lower electrode 16. It is also possible to apply one type of high frequency that also serves as In addition, a high frequency for plasma generation is applied to the upper electrode 38, while a self-bias method can be used without applying an RF bias to the lower electrode 16.

  FIG. 2 shows the configuration of the plasma etching apparatus according to the second embodiment. In the figure, parts having the same configuration or function as those in the first embodiment (FIG. 1) are denoted by the same reference numerals.

  In the second embodiment, a disc-shaped susceptor lower electrode 92 made of, for example, aluminum is disposed on the bottom of the chamber 10 via an insulating plate 12, and a susceptor 94 made of a dielectric, for example, ceramic is placed on the susceptor lower electrode 92. Is provided. Inside the susceptor 94, a plate-like or sheet-like susceptor upper electrode 96 is provided in the vicinity of the upper surface (substrate mounting surface). The material of the susceptor upper electrode 96 is preferably a refractory metal such as tungsten, molybdenum, or nickel.

  The high-frequency power source 98 heats the susceptor 94 itself made of a dielectric material by high-frequency heating in order to control the temperature of the semiconductor wafer W on the susceptor 94 by a heating method, and one output terminal is connected to the susceptor via the power supply line 100. It is electrically connected to the upper electrode 96, and the other output terminal is electrically connected to the susceptor lower electrode 92 through the ground, and preferably outputs a frequency within the range of 1 MHz to 200 MHz, for example, a high frequency of 10 MHz. When a high frequency from the high frequency power supply 98 is applied between the susceptor upper electrode 96 and the susceptor lower electrode 92, the inside of the susceptor 94 generates heat due to dielectric loss under a high frequency electric field formed between the electrodes 96, 92. The semiconductor wafer W on the susceptor 94 is heated by heat conduction. By variably controlling the output power of the high-frequency power source 98, the amount of heat generated inside the susceptor 94 can be arbitrarily controlled, and thus the temperature of the semiconductor wafer W can be arbitrarily controlled.

  In this embodiment, in order to hold the semiconductor wafer W on the susceptor 94 with an electrostatic attraction force, a DC voltage from the DC power supply 28 is applied to the susceptor upper electrode 96 via the power supply line 102, the node 104 and the power supply line 100. You can do it. In this case, in the middle of the power supply line 100 between the node 104 and the high-frequency power source 98, a high-pass filter that passes a high frequency from the high-frequency power source 98 and blocks a DC voltage from the DC power source 28 and a high frequency from the high-frequency power source 62 ( HPF) or bandpass filter 106 may be provided. In addition, a filter 108 that passes a DC voltage from the DC power supply 28 and blocks high frequencies from the high-frequency power supplies 98 and 62 may be provided in the middle of the power supply line 102.

  FIG. 3 shows the configuration of the plasma etching apparatus according to the third embodiment. In the figure, parts having the same configuration or function as those in the first or second embodiment (FIG. 1 or 2) are denoted by the same reference numerals.

  In the third embodiment, the coil 110 is disposed under the susceptor 94 so as to be substantially coaxial with the susceptor 94 or the susceptor electrode 96. The high-frequency power source 112 heats the electrode 96 inside the susceptor 94 by high-frequency heating in order to control the temperature of the semiconductor wafer W on the susceptor 94 by a heating method, and its output terminal is connected to the coil 110 via the power supply line 114. It is electrically connected, and preferably outputs a frequency in the range of 1 kHz to 10 MHz, for example, a high frequency of 2 kHz. When a high-frequency current from the high-frequency power source 112 flows through the coil 110, a high-frequency electromagnetic field J formed by the coil 110 penetrates the susceptor electrode 96, and the susceptor electrode 96 generates heat due to the eddy current generated in the susceptor electrode 96. The semiconductor wafer W on the susceptor 96 is heated by conduction. By variably controlling the output power of the high-frequency power source 112, the amount of heat generated by the susceptor electrode 96 can be arbitrarily controlled, and thus the temperature of the semiconductor wafer W can be arbitrarily controlled.

  In this embodiment, in order to hold the semiconductor wafer W on the susceptor 94 with an electrostatic attraction force, a DC voltage from the DC power supply 28 may be applied to the susceptor upper electrode 96 via the power supply line 116. It is also possible to apply the RF bias high frequency from the high frequency power supply 60 to the susceptor upper electrode 96 via the power supply line 118, the node 117 and the power supply line 116. Preferably, a filter 120 for passing a high frequency for heating from the high frequency power supply 112 and blocking a high frequency for RF bias from the high frequency power supply 60 and a high frequency for plasma generation from the high frequency power supply 62 is provided in the middle of the power supply line 114. Good. Further, a high pass filter (HPF) 122 that cuts the DC voltage from the DC power supply 28 through the RF bias RF from the RF power supply 60 may be provided in the middle of the power supply line 118.

  Also in the second and third embodiments described above, the form in which the high frequency for plasma generation or the high frequency for RF bias is applied to the upper or lower electrode is arbitrary, and various modifications are possible. In the present invention, the feeder line can take any form such as a cable or a conductor rod.

  The same applies to the plasma processing apparatus. In particular, the capacitively coupled parallel plate type plasma generation method as in the above embodiment is an example, and other arbitrary methods such as a magnetron method and an ECR (Electron Cyclotron Resonance) method can be used. The present invention is applicable. The type of plasma process is not limited to etching, and the present invention can be applied to any plasma process such as CVD (Chemical Vapor Deposition), oxidation, and sputtering. Furthermore, the target object to be processed by the plasma process is not limited to a semiconductor wafer, and can be applied to, for example, a glass substrate or an LCD (Liquid Crystal Display) substrate. Furthermore, the present invention can be applied to a processing apparatus other than the plasma processing apparatus.

It is a figure which shows the structure of the plasma etching apparatus by the 1st Embodiment of this invention. It is a figure which shows the structure of the plasma etching apparatus by 2nd Embodiment. It is a figure which shows the structure of the plasma etching apparatus by 3rd Embodiment.

Explanation of symbols

10 chamber 14 support 16 susceptor (lower electrode)
18 Electrostatic chuck 20 Electrode unit 24 Lower dielectric (sheet)
26 Power supply line 28 DC power supply 38 Shower head (upper electrode)
46 Processing gas supply unit 54 Exhaust device 58 High frequency power source for heating 60 High frequency power source for RF bias 62 High frequency power source for plasma generation 64, 66, 70 Feed line 74 Low pass filter (LPF)
76 Bandpass Filter (BPF)
84 Low-pass filter 88 High-frequency bypass circuit 90 Filter 92 Lower electrode of susceptor 94 Susceptor 96 Upper electrode of susceptor 98 High-frequency power source for heating 100, 102 Feed line 106 High-pass filter (HPF)
112 High frequency power supply for heating
114, 116, 118 Feed line 120 Filter

Claims (8)

A processing vessel capable of generating or introducing plasma; and
A first electrode for placing a substrate to be processed in the processing container;
An electrostatic chuck provided on the first electrode and having an electrode part and a dielectric sandwiching the electrode part from above and below;
A DC power supply for applying a DC voltage for electrostatic attraction to the electrode portion of the electrostatic chuck via a first power supply line;
A first high-frequency power source having one output terminal electrically connected to the first electrode via a second power supply line and outputting a first high-frequency for heating;
A high frequency bypass that cuts off direct current from the direct current power source and passes the first high frequency between a first node set in the middle of the first power supply line and the other output terminal of the first high frequency power source. Circuit,
A second high frequency power source having one output terminal electrically connected to the first electrode via a third power supply line and the second power supply line, and outputting a second high frequency for high frequency bias; ,
The first node is provided in the middle of the first power supply line closer to the electrode portion of the electrostatic chuck than the first node, passes the DC voltage from the DC power supply, and the first from the first high-frequency power supply. A first filter circuit that cuts off the second high-frequency power from the second high-frequency power source, the first high-frequency power source, the second power supply line, and the electrostatic chuck The first high-frequency current output from the first high-frequency power source flows in a closed circuit including the electrode unit, the first power supply line, the first filter circuit, and the high-frequency bypass circuit, and A processing apparatus in which the substrate on the mounting table is heated by Joule heat of an electrode portion of an electric chuck. The first frequency of the high frequency is lower than the frequency of the second high-frequency, processing apparatus according to claim 1. Provided in the middle of the second power supply line closer to one output terminal of the first high-frequency power supply than a second node to which the third power supply line and the second power supply line are connected; 3. The process according to claim 1 , further comprising: a second filter circuit that passes the first high frequency from a first high frequency power supply and blocks the second high frequency from the second high frequency power supply. apparatus. A third filter circuit provided in the middle of the third power supply line and configured to pass the second high frequency from the second high frequency power supply and cut off the first high frequency from the first high frequency power supply; a processing apparatus according to any one of claims 1 to 3. Wherein the processing vessel first electrode and opposite to a second electrode are spaced a desired interval, the processing apparatus according to any one of claims 1 to 3. The second high frequency supplied to the first electrode than the second high-frequency power source, also serves as a high frequency for generating plasma between the first electrode and the second electrode, claim 5. The processing apparatus according to 5 . Wherein the second electrode has a fourth third high-frequency power supply for supplying third RF power for plasma generation via a feed line, the processing apparatus according to claim 5. Said first filter circuit to block the third frequency from the third RF power supply, processing apparatus according to claim 6.

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