JP2008235288A - Device for plasma processing, and wave retardation plate - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve an intimate contact between a wave retardation plate and a slot plate constituting a microwave radiation surface so as to prevent an abnormal electric discharge in a microwave plasma processing apparatus that uses a radial line slot antenna. <P>SOLUTION: A slot plate 16 is formed by a material having a thermal expansion rate close to the wave retardation plate 18. Alternatively, the slot plate 16 is formed by depositing a metal on a dielectric plate constituting the wave retardation plate 18. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention generally relates to a plasma processing apparatus, and more particularly to a microwave plasma processing apparatus.

  The plasma processing step and the plasma processing apparatus are used in the manufacture of ultra-miniaturized semiconductor devices having a gate length close to or less than 0.1 μm, which are called so-called deep sub-micron elements or deep sub-quarter micron elements, and liquid crystal display devices. This is an indispensable technique for manufacturing a high-resolution flat panel display device.

  Various plasma excitation methods have been used in the past as plasma processing devices used in the manufacture of semiconductor devices and liquid crystal display devices. In particular, parallel plate high frequency excitation plasma processing devices or inductively coupled plasma processing devices are generally used. Is. However, these conventional plasma processing apparatuses have a problem that it is difficult to perform a uniform process over the entire surface of the substrate to be processed at a high processing speed, that is, a throughput because the plasma formation is non-uniform and the region where the electron density is high is limited. Has a point. This problem is particularly serious when processing a large-diameter substrate. In addition, these conventional plasma processing apparatuses have some essential problems such as damage to semiconductor elements formed on the substrate to be processed due to high electron temperature, and large metal contamination due to sputtering of the processing chamber wall. Have. For this reason, it is becoming difficult for conventional plasma processing apparatuses to meet strict requirements for further miniaturization of semiconductor devices and liquid crystal display devices and further improvement of productivity.

  On the other hand, a microwave plasma processing apparatus that uses high-density plasma excited by a microwave electric field without using a DC magnetic field has been proposed. For example, microwaves are radiated into a processing vessel from a planar antenna (radial line slot antenna) having a large number of slots arranged to generate uniform microwaves, and gas in the vacuum vessel is generated by the microwave electric field. There has been proposed a plasma processing apparatus configured to excite plasma by exciting the plasma. (For example, see JP-A-9-63793.) With microwave plasma excited by such a method, a high plasma density can be realized over a wide region directly under the antenna, and uniform plasma treatment can be performed in a short time. is there. In addition, the microwave plasma formed by such a method has a high excitation frequency and does not use an electron resonance phenomenon using a magnetic field, so that the electron temperature is low and damage to the substrate to be processed and metal contamination can be avoided. . Furthermore, since uniform plasma can be easily excited even on a large-area substrate, it is possible to easily cope with a manufacturing process of a semiconductor device using a large-diameter semiconductor substrate and a large-sized liquid crystal display device.

  1A and 1B show the configuration of a conventional microwave plasma processing apparatus 100 using such a radial line slot antenna. 1A is a cross-sectional view of the microwave plasma processing apparatus 100, and FIG. 1B is a diagram showing a configuration of a radial line slot antenna.

  Referring to FIG. 1A, a microwave plasma processing apparatus 100 has a processing chamber 101 exhausted from a plurality of exhaust ports 116, and a holding table 115 that holds a substrate to be processed 114 in the processing chamber 101. Is formed. In order to achieve uniform exhaust of the processing chamber 101, a ring-shaped space 101A is formed around the holding table 115, and the plurality of exhaust ports 116 are connected at equal intervals so as to communicate with the space 101A. In other words, the processing chamber 101 can be uniformly evacuated through the space 101A and the exhaust port 116 by being formed symmetrically with respect to the substrate to be processed.

  A large number of openings 107 made of a low dielectric loss dielectric are formed on the processing chamber 101 as a part of the outer wall of the processing chamber 101 at a position corresponding to the substrate 114 to be processed on the holding table 115. A plate-like shower plate 103 is formed through a seal ring 109, and a cover plate 102 made of the same low dielectric loss dielectric is provided outside the shower plate 103 through another seal ring 108. ing.

  A plasma gas passage 104 is formed on the upper surface of the shower plate 103, and each of the plurality of openings 107 is formed to communicate with the plasma gas passage 104. Further, a plasma excitation gas supply passage 106 communicating with the plasma gas supply port 105 provided on the outer wall of the processing vessel 101 is formed inside the shower plate 103. The supplied plasma excitation gas such as Ar or Kr is supplied from the supply passage 106 to the opening 107 through the passage 104, and the space immediately below the shower plate 103 inside the processing vessel 101 from the opening 107. 101B is released at a substantially uniform concentration.

  On the processing container 101, a radial line slot antenna 110 having a radiation surface shown in FIG. 1B is provided outside the cover plate 102 at a distance of 4 to 5 mm from the cover plate 102. . The radial line slot antenna 110 is connected to an external microwave source (not shown) via a coaxial waveguide 110A, and the plasma excitation gas discharged into the space 101B by the microwave from the microwave source is supplied. Excited. A gap between the cover plate 102 and the radiation surface of the radial line slot antenna 110 is filled with air.

  The radial line slot antenna 110 is formed in a flat disk-shaped radial line back metal plate 110B connected to the outer conductor of the coaxial waveguide 110A and an opening of the radial line back metal plate 110B. 1 (B) and a radiation plate 110C formed with a number of slots 110b perpendicular to the slot 110a, and a thickness between the radial line back metal plate 110B and the radiation plate 110C A slow wave plate 110D made of a constant dielectric is inserted.

  In the radial line slot antenna 110 having such a configuration, the microwaves fed from the coaxial waveguide 110 travel between the disk-shaped radial line back metal plate 110B and the radiation plate 110C while spreading in the radial direction. However, at that time, the wavelength is compressed by the action of the retardation plate 110D. Thus, by forming the slots 110a and 110b concentrically and orthogonally to each other in accordance with the wavelength of the microwave traveling in the radial direction in this way, a plane wave having circular polarization can be obtained. Radiation can be performed in a direction substantially perpendicular to the radiation plate 110C.

  By using the radial line slot antenna 110, uniform high-density plasma is formed in the space 101B immediately below the shower plate 103. The high-density plasma thus formed has a low electron temperature, so that the substrate to be processed 114 is not damaged, and metal contamination due to sputtering of the vessel wall of the processing vessel 101 does not occur.

  In the plasma processing apparatus 100 of FIG. 1, in the processing container 101, a diffusion plasma region between the shower plate 103 and the substrate to be processed 114 is supplied from an external processing gas source (not shown) into the processing container 101. A conductive structure 111 is formed in which a plurality of nozzles 113 for supplying a processing gas is formed through a processing gas passage 112 formed in the nozzle 113, and each of the nozzles 113 supplies the processing gas supplied thereto to the conductor. The light is discharged into a space 101C between the structure 111 and the substrate to be processed 114. The conductor structure 111 has an opening between the adjacent nozzles 113 and 113 having a size that allows the plasma formed in the space 101B to efficiently pass through the space 101B from the space 101B to the space 101C. The part is formed.

  Therefore, when the processing gas is discharged from the conductor structure 111 to the space 101C through the nozzle 113 in this way, since excessive dissociation of the processing gas can be suppressed because the plasma is at a low electron temperature, Uniform and high-quality plasma treatment is performed on the substrate 114 to be processed efficiently and at high speed without damaging the substrate and the element structure on the substrate, and without contaminating the substrate. On the other hand, the microwave radiated from the radial line slot antenna 110 is blocked by the conductor structure 111, and the substrate to be processed 114 is not damaged even before the plasma ignition.

A microwave plasma processing apparatus having a radial slot antenna as described above is disclosed in Patent Document 1, for example.
JP 2000-286237 A

By the way, in the plasma processing apparatus 100 using such a radial line slot antenna 110, since the density of plasma formed in the space 101B reaches the order of 10 ¹² / cm ³ , the shower plate 103 uses the high-density plasma. Exposure to a large amount of constituent ions and electrons causes heating by these ions and electrons. The heat flux resulting from such ions and electrons reaches 1 to ² W / cm ² . In addition, the plasma processing apparatus 100 is often operated with the wall of the processing chamber 101 held at a temperature of about 150 ° C. in order to suppress adhesion of deposits to the processing chamber 101. As a result of the heating of the processing chamber 101, heat accumulates in the shower plate 103 and the cover plate 102 made of a dielectric material, resulting in a very large temperature distribution.

  In order to reduce the accumulation of heat in the shower plate 103 and the cover plate 102, it is preferable that the radial line slot antenna 110 is in close contact with the cover plate 102 and the heat is removed using the antenna 110 as a heat sink. In the conventional radial line slot antenna 110, since the radiation plate 110C is screwed to the central conductor of the coaxial waveguide 110A, a space for the screw head is provided between the cover plate 102 and the radiation plate 110C. Therefore, it is difficult to adopt such a configuration.

  Further, in the conventional plasma processing apparatus 100, the radial line slot antenna 110 is substantially heated by the heat flux from the shower plate 103 and the cover plate 102 even if the radial line slot antenna 110 is not in close contact with the cover plate 102. Rises. Further, when the radial line slot antenna 110 is in close contact, the temperature rise of the antenna is further increased.

  Conventional radial line slot antennas are not designed for use in such a high temperature environment. Therefore, when the temperature of the antenna rises in this way, due to the difference in thermal expansion coefficient, the inside of the antenna, particularly the slow wave plate, In some cases, a gap may be formed between the dielectric plate 110D and the radiation plate 110C. When a gap is generated between the slow wave plate 110D and the radiation plate 110C in this manner, the impedance felt by the microwave propagating through the slow wave plate is disturbed, and undesirable abnormal discharge and reflected wave formation in the antenna, or constant Problems such as the formation of standing waves occur. If abnormal discharge occurs, the antenna becomes unusable thereafter.

  Therefore, an object of the present invention is to provide a novel and useful plasma processing apparatus that solves the above-described problems.

  A more specific object of the present invention is to improve the adhesion between a slow wave plate and a radiation plate in a radial line slot antenna in a plasma processing apparatus that excites plasma using a radial line slot antenna.

  Another object of the present invention is to provide a configuration capable of stably radiating microwaves even when the antenna is heated in a plasma processing apparatus that excites plasma using a radial line slot antenna.

The present invention solves the above problems.
A processing vessel defined by an outer wall and provided with a holding table for holding a substrate to be processed;
An exhaust system coupled to the processing vessel;
A plasma gas supply unit for supplying plasma gas into the processing vessel;
On the processing vessel, provided corresponding to the plasma gas supply unit, and comprising a microwave antenna fed by a coaxial waveguide,
The microwave antenna includes a radial line back metal plate having an opening, a microwave radiation surface having a plurality of slots provided on the radial line back metal plate so as to cover the opening, and the radial line back metal. It consists of a dielectric plate provided between the plate and the microwave radiation surface,
The plasma is characterized in that the microwave radiation surface is made of a conductive material such that a difference in thermal expansion coefficient from the dielectric plate is within 10% of the thermal expansion coefficient of the dielectric plate. A processing apparatus, or the dielectric plate is selected from any of Al ₂ O ₃ , SiO ₂ and Si ₃ N ₄ , or the dielectric plate is made of alumina ceramic, The microwave radiation surface is made of a plasma processing apparatus made of an alloy of Cu and W, or the microwave radiation surface is coated with a base material made of a conductive material and a surface of the base material, Ni A plasma processing apparatus comprising a plating layer made of Au, Au, Ag or Cu, or a plasma characterized in that the plating layer has a thickness of 6 μm or more By a processing apparatus, or by a plasma processing apparatus, wherein the microwave radiation surface and the dielectric plate are bonded by a ceramic adhesive layer, or the microwave radiation surface and the dielectric plate Is a plasma processing apparatus bonded by a conductive adhesive layer, or a processing container defined by an outer wall and provided with a holding table for holding a substrate to be processed;
An exhaust system coupled to the processing vessel;
A plasma gas supply unit for supplying plasma gas into the processing vessel;
On the processing vessel, provided corresponding to the plasma gas supply unit, and comprising a microwave antenna fed by a coaxial waveguide,
The microwave antenna includes a radial line back metal plate having an opening, a microwave radiation surface having a plurality of slots provided on the radial line back metal plate so as to cover the opening, and the radial line back metal. It consists of a dielectric plate provided between the plate and the microwave radiation surface,
The microwave radiation surface is composed of a plating layer of a conductor material formed on the dielectric plate, or the plating layer of the conductor material is an electroless plating layer Or the plating layer is composed of at least an atomic electroless plating layer and an electrolytic plating layer formed on the electroless plating layer. Or a plasma processing apparatus in which the conductive material is made of Cu, or the plating layer is formed of a Ni layer in contact with the dielectric plate and a Cu layer formed on the Ni layer. A plasma processing apparatus, or at least the Cu layer has a thickness of 6 μm or more. The slot is formed by etching, or a plasma processing apparatus, or
A processing container provided with a mounting table on which a substrate to be processed is mounted;
A microwave generator that generates a microwave and supplies the microwave to the processing container; a delay generator that is provided between the microwave generator and the processing container and that shortens the wavelength of the microwave supplied from the microwave generator. Corrugated sheet,
A microwave radiating member that radiates a microwave whose wavelength is shortened by the slow wave plate to a space in the processing container,
A metal layer is formed on at least an upper surface and a lower surface of the retardation plate;
The microwave radiating member is composed of the metal layer formed on the surface of the slow wave plate, or a plasma processing apparatus, or
The microwave radiating member has a number of slots, and the slots are formed by removing the metal layer by etching, or by a microwave plasma processing apparatus,
The thickness of the metal layer is greater than the skin depth of the microwave generated by the microwave generator, or a plasma processing apparatus,
The metal layer is a plating layer made of a material selected from the group consisting of copper, gold, silver, and nickel, or
The microwave wavelength is 2.45 GHz, the metal layer is made of a copper plating layer, and the thickness of the copper plating layer is 6 μm or more, or
The metal layer is a metal film deposited by chemical vapor deposition (CVD), or a plasma processing apparatus, or
The metal layer is a metal film deposited by physical vapor deposition (PVD), or by a plasma processing apparatus, or
A coaxial waveguide for supplying the microwave from the microwave generator to the retardation plate;
An outer tube and an inner cable of the coaxial waveguide are connected to a central portion of the slow wave plate by soldering, or a plasma processing apparatus, or
A processing container having a mounting table on which a substrate to be processed is mounted, a microwave generator that generates a microwave and supplies the microwave to the processing container, and between the microwave generator and the processing container A slow wave plate for shortening the wavelength of the microwave from the microwave generator, and at least an upper surface and a lower surface of the metal layer formed on the surface of the slow wave plate. A plasma processing method using a microwave plasma processing apparatus having a microwave radiating member constituted by a part,
The processing surface of the substrate to be processed is placed on the mounting table so as to face the microwave radiating member,
Supplying microwaves to the slow wave plate, introducing microwaves into the processing vessel from a number of slots formed in a part of the metal layer,
Plasma is generated in the processing container by the introduced microwave, and plasma processing is performed on the substrate to be processed by the generated plasma, or
Used in a microwave plasma processing apparatus having a processing vessel for performing plasma processing and a microwave generator for generating and supplying microwaves to the processing vessel. The wavelength of the microwaves supplied from the microwave generators A slow wave plate,
A slow wave plate characterized in that at least an upper surface and a lower surface are covered with a metal layer, and a microwave radiation member is constituted by a part of the metal layer; or
The microwave radiating member has a plurality of slots, and the slots are formed by removing the metal layer by etching, or
The thickness of the metal layer is greater than the skin depth of the microwave generated by the microwave generator, or
The metal layer is a slow wave plate characterized by being a plating layer made of a material selected from the group consisting of copper, gold, silver, nickel, or
The wavelength of the supplied microwave is 2.45 GHz, the metal plating layer is made of a copper plating layer, and the thickness of the copper plating layer is 6 μm or more, or
The problem is solved by a slow wave plate characterized by having, at the central portion, a protrusion that is joined by soldering to a coaxial waveguide that supplies microwaves from the microwave generator to the slow wave plate.

[Action]
According to the present invention, since the thermal expansion difference between the slow wave plate in the radial line slot antenna and the slot plate constituting the radiation surface is controlled to 10% or less, even if the antenna is heated by plasma, In this case, problems such as the generation of gaps do not occur, and accordingly, problems such as abnormal discharge, formation of reflected waves, and formation of standing waves can be avoided.

  Further, in the present invention, by forming the slot plate on the slow wave plate by plating, fine irregularities on the slow wave plate are filled with a plating layer, and the slot plate and the slow wave plate are interposed. It becomes possible to realize ideal close contact.

  Furthermore, in the present invention, by forming a plating layer on at least the upper surface and the lower surface of the slow wave plate and causing the lower plating layer to function as a microwave radiation material, even if the microwave radiation material is heated by plasma, microwave radiation is achieved. There is no problem that a gap is generated between the material and the slow wave plate. Therefore, problems such as abnormal discharge, formation of reflected waves, and formation of standing waves can be avoided. In addition, since the plating layer formed on the upper surface of the slow wave plate does not cause a gap between the metal part and the slow wave plate even on the upper surface portion of the slow wave plate, the microwave radiation characteristic is stabilized.

  Further, according to the above-described invention, since the microwave radiating member is formed of a metal layer, the thickness of the slot portion can be reduced, and reflection of microwaves due to the cut-off phenomenon at the slot portion can be suppressed. , Radiation efficiency is improved. Furthermore, since the microwave radiating member is integrally formed with the slow wave plate as a part of the metal layer, it is not necessary to produce and join the slow wave plate and the microwave radiating member as separate parts. This prevents a gap from being formed between the retardation plate and the microwave radiating member due to thermal expansion or change over time, and uniform microwaves can be introduced into the processing container. Accordingly, it is possible to perform plasma processing with little change over time and good reproducibility. In addition, since almost the whole of the slow wave plate is covered with the metal plating layer, the microwave supplied to the slow wave plate is introduced into the processing container without leaking, so that efficient plasma generation can be performed.

  According to the present invention, in the microwave plasma processing apparatus using a radial line slot antenna, the slot plate is made of a Cu-W alloy, so that the difference in thermal expansion coefficient with the dielectric plate constituting the slow wave plate can be reduced. An antenna that can be minimized and whose microwave radiation characteristics do not change even when heated can be realized. Also, by forming the slot plate with a plating layer, an antenna that can realize ideal adhesion between the slow wave plate and the slot plate, and does not change the microwave radiation characteristics even when overheated, and can prevent abnormal discharge Can be realized. Furthermore, by forming a metal layer such as a plating layer on the upper and lower surfaces of the slow wave plate, abnormal discharge on the upper and lower surfaces of the slow wave plate can be prevented.

[First embodiment]
2A and 2B show the configuration of the microwave plasma processing apparatus 10 according to the first embodiment of the present invention.

Referring to FIG. 2A, the microwave plasma processing apparatus 10 is provided in a processing container 11 and the processing container 11 and preferably has a hot isostatic pressure for holding a substrate 12 to be processed by an electrostatic chuck. And a holding table 13 made of AlN or Al ₂ O ₃ formed by a pressurization method (HIP), and the processing vessel 11 has a space 11A surrounding the holding table 13 at equal intervals, that is, on the holding table 13. Exhaust ports 11a are formed in at least two locations, preferably three or more locations, in a substantially axisymmetric relationship with respect to the substrate 12 to be processed. The processing vessel 11 is evacuated and decompressed by an unequal pitch unequal angle screw pump or the like through the exhaust port 11a.

The processing vessel 11 is preferably made of austenitic stainless steel containing Al, and a protective film made of aluminum oxide is formed on the inner wall surface by oxidation treatment. Further, a disc-shaped shower plate having a large number of nozzle openings 14A made of dense Al ₂ O ₃ formed by the HIP method is formed on the outer wall of the processing container 11 corresponding to the substrate 12 to be processed. 14 is formed as part of the outer wall. The Al ₂ O ₃ shower plate 14 formed by the HIP method is formed using Y ₂ O ₃ as a sintering aid and has a porosity of 0.03% or less and substantially includes pores and pinholes. However, although it does not reach AlN, reaching 30 W / m · K, it has a very large thermal conductivity as a ceramic.

The shower plate 14 is mounted on the processing vessel 11 via a seal ring 11s, and a cover plate 15 made of a dense Al ₂ O ₃ formed by the same HIP process is further sealed on the shower plate 14. It is provided via a ring 11t. On the side of the shower plate 14 that is in contact with the cover plate 15, a recess 14 </ b> B that communicates with each of the nozzle openings 14 </ b> A and forms a plasma excitation gas flow path is formed. It is formed and communicates with another plasma gas flow path 14C communicating with the plasma gas inlet 11p formed on the outer wall of the processing vessel 11.

  The shower plate 14 is held by an overhanging portion 11b formed on the inner wall of the processing container 11, and the portion of the overhanging portion 11b that holds the shower plate 14 is rounded to suppress abnormal discharge. Is formed.

  Therefore, the plasma gas such as Ar or Kr supplied to the plasma excitation gas inlet 11p sequentially passes through the channels 14C and 14B inside the shower plate 14, and then directly below the shower plate 14 through the opening 14A. It is uniformly supplied into the space 11B.

On the cover plate 15, a disk-shaped slot plate 16 in which a large number of slots 16 a and 16 b shown in FIG. 2B are formed in close contact with the cover plate 15, and a disk-shaped slot plate 16 that holds the slot plate 16. Slowly composed of a metal plate 17 (radial line back metal plate) and a low dielectric loss dielectric material of Al ₂ O ₃ , SiO ₂ or Si ₃ N ₄ sandwiched between the slot plate 16 and the metal plate 17. A radial line slot antenna 20 constituted by a corrugated plate 18 is provided. The slot plate 16 is preferably made of Cu (copper) containing up to 10 wt% of W (tungsten). Particularly, the slow wave plate 18 has a linear expansion coefficient of 7 to 8 × 10 ⁻⁶ / ° C. When Al ₂ O ₃ is used, a thermal expansion difference between the slow wave plate 18 and the slow wave plate 18 is obtained by using a Cu—W alloy having a linear expansion coefficient of about 7 × 10 ⁻⁶ / ° C. Can be suppressed to 10% or less. Since the Cu-W alloy has a relatively large specific resistance, when used as the slot plate 16 of the radial line slot antenna, Au (gold), Ag (silver), as shown in the enlarged view of FIG. The low resistance layer 16r such as copper (Cu) is preferably formed to a thickness of about 3 μm or more in consideration of the skin effect of the microwave. The low resistance layer 16r can be easily formed by, for example, electrolytic plating.

The slot plate 16 can be bonded to the slow wave plate 18 with a ceramic adhesive. As such a ceramic adhesive, typically, an alumina particle dispersed in a solvent is commercially available. After bonding, the solvent is volatilized by annealing at 200 to 300 ° C., and the strong adhesive layer 18 ₁ having no microwave loss shown in FIG. 3 is obtained.

The radial slot line antenna 20 is mounted on the processing vessel 11 via a seal ring 11u, and the radial line slot antenna 20 is connected to a radial microwave source (not shown) via a coaxial waveguide 21. A microwave having a frequency of 2.45 GHz or 8.3 GHz is supplied. The supplied microwave is radiated from the slots 16a and 16b on the slot plate 16 into the processing container 11 through the cover plate 15 and the shower plate 14, and the opening portion is formed in the space 11B immediately below the shower plate 14. Plasma is excited in the plasma gas supplied from 14A. At that time, the cover plate 15 and the shower plate 14 are made of Al ₂ O ₃ and function as an efficient microwave transmission window. At this time, in order to avoid excitation of plasma in the plasma gas flow paths 14A to 14C, the plasma gas is maintained at a pressure of about 6666 Pa to 13332 Pa (about 50 to 100 Torr) in the flow paths 14A to 14C. The

  In order to improve the adhesion between the radial line slot antenna 20 and the cover plate 15, in the microwave plasma processing apparatus 10 of this embodiment, a ring is formed on a part of the upper surface of the processing container 11 that engages with the slot plate 16. A groove 11g is formed, and the groove 11g is exhausted through an exhaust port 11G communicating with the groove 11g, whereby the gap formed between the slot plate 16 and the cover plate 15 is decompressed, The radial line slot antenna 20 can be firmly pressed against the cover plate 15 by the atmospheric pressure. The gap includes slots 16a and 16b formed in the slot plate 16, but a gap may be formed for various reasons. The gap is sealed by a seal ring 11 u between the radial line slot antenna 20 and the processing container 11.

  Further, by filling the gap between the slot plate 16 and the cover plate 15 through the exhaust port 11G and the groove 15g with an inert gas having a high thermal conductivity, the cover plate 15 to the slot plate 16 is filled. Can facilitate the transport of heat. As such an inert gas, it is preferable to use He having high thermal conductivity and high ionization energy. When filling the gap with He, it is preferable to set the pressure to about 0.8 atm. In the configuration of FIG. 3, a valve 11V is connected to the exhaust port 11G for exhausting the groove 15g and filling the groove 15g with inert gas.

  Out of the coaxial waveguide 21, the outer waveguide 21 </ b> A is connected to a disk-shaped metal plate 17 (radial line back metal plate), and the center conductor 21 </ b> B has an opening formed in the slow wave plate 18. And connected to the slot plate 16. Therefore, the microwave supplied to the coaxial waveguide 21 is radiated from the slots 16 a and 16 b while traveling in the radial direction between the metal plate 17 and the slot plate 16.

  FIG. 2B shows the slots 16 a and 16 b formed on the slot plate 16.

  Referring to FIG. 2 (B), the slots 16a are arranged concentrically, and slots 16b perpendicular to the slots 16a are also concentrically formed corresponding to the slots 16a. The slots 16 a and 16 b are formed in the radial direction of the slot plate 16 at an interval corresponding to the wavelength of the microwave compressed by the slow wave plate 18, and as a result, the microwave is substantially from the slot plate 16. Radiated as a plane wave. At this time, since the slots 16a and 16b are formed so as to be orthogonal to each other, the microwave radiated in this way forms a circularly polarized wave including two orthogonal polarization components.

Further, in the plasma processing apparatus 10 shown in FIG. 2A, a cooling block 19 having a cooling water passage 19A is formed on the metal plate 17, and the cooling block 19 is cooled in the cooling water passage 19A. By cooling with water, the heat accumulated in the shower plate 14 is absorbed through the radial line slot antenna 20. The cooling water passage 19A is formed in a spiral shape on the cooling block 19, and is preferably passed with cooling water that excludes dissolved oxygen by bubbling H ₂ gas and controls the oxidation-reduction potential.

Further, in the microwave plasma processing apparatus 10 of FIG. 2A, the processing vessel 11 is provided on the outer wall of the processing vessel 11 between the shower plate 14 and the substrate 12 to be processed on the holding table 13. A processing gas supply structure 31 having a grid-like processing gas passage 31A for supplying a processing gas from the processing gas inlet 11r and discharging it from a number of processing gas nozzle openings 31B (see FIG. 4) is provided. In the space 11C between the gas supply structure 31 and the substrate to be processed 12, a desired uniform substrate processing is performed. Such substrate processing includes plasma oxidation processing, plasma nitriding processing, plasma oxynitriding processing, plasma CVD processing, and the like. Further, a carbon-rich fluorocarbon gas such as C ₄ F ₈ , C ₅ F ₈ or C ₄ F ₆ , an etching gas such as an F-based or Cl-based gas is supplied from the processing gas supply structure 31 to the space 11C. Reactive ion etching can be performed on the substrate 12 by applying a high frequency voltage from the high frequency power source 13 </ b> A to the holding table 13.

  In the microwave plasma processing apparatus 10 according to the present embodiment, the outer wall of the processing vessel 11 is heated to a temperature of about 150 ° C., thereby preventing the deposition of reaction byproducts on the inner wall of the processing vessel. By performing dry cleaning about once a day, it is possible to operate stably and stably.

  FIG. 4 is a bottom view showing the configuration of the processing gas supply structure 31 of FIG.

  Referring to FIG. 4, the processing gas supply structure 31 is made of a conductor such as Al alloy containing Mg or Al-added stainless steel, and the lattice-shaped processing gas passage 31A is connected to the processing gas inlet 11r. The processing gas is uniformly discharged into the space 11C from a large number of processing gas nozzle openings 31B formed on the lower surface, which are connected to the processing gas supply port 31R. In the processing gas supply structure 31, a plasma diffusion passage 31 </ b> C is formed between adjacent processing gas passages 31 </ b> A for passing plasma or processing gas contained in the plasma. When the processing gas supply structure 31 is formed of an Mg-containing Al alloy, it is preferable to form a fluoride film on the surface. When the processing gas supply structure 31 is formed of Al-added stainless steel, it is desirable to form an aluminum oxide passivation film on the surface. In the plasma processing apparatus 10 according to the present invention, since the electron temperature in the excited plasma to be excited is low, the incident energy of ions in the plasma is small, and the processing gas supply structure 31 is sputtered to contaminate the substrate 12 to be processed. The problem of generating is avoided. The processing gas supply structure 31 can also be formed of a dielectric such as quartz or alumina.

  The lattice-like process gas passages 31A and the process gas nozzle openings 31B are provided so as to cover a region slightly larger than the substrate 12 to be processed, which is indicated by a broken line in FIG. By providing the processing gas supply structure 31 between the shower plate 14 and the substrate 12 to be processed, the processing gas can be plasma-excited and can be uniformly processed by the plasma-excited processing gas. .

  When the processing gas supply structure 31 is formed of a conductor such as a metal, the interval between the lattice processing gas passages 31A is set smaller than the size of the cutoff waveguide corresponding to the wavelength of the microwave. The process gas supply structure 31 forms a short-circuit surface of the microwave. In this case, microwave excitation of plasma occurs only in the space 11B, and in the space 11C including the surface of the substrate 12 to be processed, the processing gas is activated by the plasma diffused from the excitation space 11B. Further, since the substrate to be processed 12 can be prevented from being directly exposed to microwaves during plasma ignition, substrate damage due to microwaves can also be prevented.

  In the microwave plasma processing apparatus 10 according to the present embodiment, since the supply of the processing gas is uniformly controlled by using the processing gas supply structure 31, the problem of excessive dissociation of the processing gas on the surface of the substrate 12 to be processed is solved. Even when a structure having a large aspect ratio is formed on the surface of the substrate 12 to be processed, it is possible to perform a desired substrate processing to the back of the high aspect structure. That is, the microwave plasma processing apparatus 10 is effective for manufacturing a large number of generations of semiconductor devices having different design rules.

  In the plasma processing apparatus 10 according to the present embodiment, the processing gas supply mechanism 31 can be removed as in the plasma processing apparatus 10A shown in FIG. However, in FIG. 5, the same reference numerals are given to the parts described above, and the description thereof is omitted.

In the configuration of FIG. 5, by introducing an oxidizing gas such as O ₂ or a nitriding gas such as a mixed gas of NH ₃ , N ₂ and H ₂ together with an inert gas such as Ar or Kr from the shower plate 14. An oxide film, a nitride film, or an oxynitride film can be formed on the surface of the substrate 12 to be processed.

In this embodiment, since the difference in thermal expansion between the slot plate 16 and the slow wave plate 18 is suppressed to 10% or less, a large amount of heat flux caused by high-density plasma from the processing vessel 11 is applied to the antenna 20. Even if the temperature of the slot plate 16 and the slow wave plate 18 is increased as a result of the supply, no gap is generated between the slot plate 16 and the slow wave plate 18, and abnormal discharge, reflected wave formation, or constant wave is not generated. Problems such as the presence of standing waves can be effectively avoided.
[Second Embodiment]
FIG. 6 shows the configuration of a plasma processing apparatus 10B according to the second embodiment of the present invention. However, in FIG. 6, the part demonstrated previously is attached | subjected the same referential mark, and description is abbreviate | omitted.

  Referring to FIG. 6, in this embodiment, a microwave antenna 20A is used instead of the microwave antenna 20 of FIG. In the microwave antenna 20 </ b> A, the tip 21 b of the central conductor 21 </ b> B of the coaxial waveguide 21 is separated from the slot plate 16 and is coupled to the back of the slow wave plate 18 formed on the slot plate 16. In such a configuration, microwaves are efficiently fed without contacting the central conductor 21 </ b> B with the slot plate 16. In the microwave antenna 20A, the slow wave plate 18 continuously extends behind the slot plate 16, and no contact hole for the central conductor is formed.

  FIGS. 7A to 7D are diagrams showing a process of forming the slow wave plate 18 and the slot plate 16 in the radial line slot antenna 20A used in the plasma processing apparatus 10B.

Referring to FIG. 7A, first, a slow wave plate 18 made of Al ₂ O ₃ , SiO _2, or Si ₃ N ₄ is immersed in an electroless plating solution of Cu in an electroless plating bath Bath1 to obtain a surface. electroless Cu plating layer 16 ₁ of at least one atomic layer is formed.

The electroless plating of FIG. 7 (A) may be further continued, and an electroless plating Cu layer may be deposited on the retardation plate 18 to a desired thickness. However, from the viewpoint of improving adhesion, FIG. the preceding shown in FIG. 7 (a) of said at step electroless Cu plating layer 16 ₁ wave retardation plate 18 formed with (B), the immersed in an electroplating solution in an electrolytic plating bath Bath2, the Mu The electrolytic Cu plating layer 16 ₁ is preferably used as an electrode, and the electrolytic Cu plating layer 16 ₂ is preferably formed on the electroless Cu plating layer 16 ₁ in a desired thickness. Desired thickness of the Cu layer 16 _2, in consideration of the skin effect of microwave, preferably set to 6μm or more.

The Cu layers 16 ₁ and 16 ₂ thus formed are covered with the resist film R in the step of FIG. 7C, and this is exposed and developed in the step of FIG. By patterning the Cu layers 16 ₁ and 16 ₂ using R ′ as a mask, the slot plate 16 in which the slots 16a and 16b are formed is obtained. It is also possible to apply a film having a desired pattern and pattern the Cu layer 16 by wet etching using the film as a mask.

  The slot plate 16 formed by such a process is excellent in adhesion because it is formed by filling fine irregularities on the surface of the slow wave plate 18 even though it is made of Cu, and the slot plate 16 and the slow wave plate 18 It is effective in suppressing the formation of gaps between the two.

As described above, the slot plate 16 may be formed by electroless plating. Further in the example of FIG. 7 (A) ~ (D) , it is also possible to use Ni plating layer instead of the electroless Cu plating layer 16 _1.

  Also in the embodiment of FIG. 6, the processing gas supply / supply structure can be removed depending on the use of the plasma processing apparatus.

7A to 7D, the method for forming the slot plate 16 is further applied to the plasma processing apparatus 10 of FIGS. 2A and 2B or the plasma processing apparatus 10A of FIG. The present invention can also be applied to the conventional plasma processing apparatus 100 shown in FIGS.
[Third embodiment]
FIG. 8 is a schematic configuration diagram of a microwave plasma processing apparatus according to an embodiment of the present invention.

  A microwave plasma processing apparatus 40 shown in FIG. 8 is, for example, a plasma CVD apparatus, and performs a plasma CVD process on a semiconductor wafer W as a substrate to be processed in a processing container 42. The processing container 42 is made of, for example, aluminum and has a sealed structure so that it can be evacuated. A mounting table 44 for mounting the semiconductor wafer W is provided in the processing container 42.

  An exhaust port 42a is provided at the bottom of the processing vessel 42, and a vacuum pump (not shown) is connected to maintain the inside of the processing vessel 42 at a predetermined low pressure state.

  A dielectric plate 46 is airtightly attached to the ceiling portion of the processing container 42. In this embodiment, a slow wave plate 48 having at least an upper surface and a lower surface plated is attached on the dielectric plate 46. In this embodiment, since the microwave radiating member is formed by the plating layer of the slow wave plate 48, it is not necessary to provide the antenna member as the microwave radiating member separately from the slow wave plate 48. The plated slow wave plate 48 will be described later.

  The slow wave plate 48 is attached to the support member 50. The support member 50 has a function of supporting the slow wave plate 48 and cooling the slow wave plate 48. That is, a passage 50a through which cooling water flows is formed inside the support member 50, and the slow wave plate 48 is cooled during plasma processing.

  A coaxial waveguide 52 for supplying microwaves is connected to the central portion of the slow wave plate 48. The coaxial waveguide 52 is connected to a waveguide 56 via a coaxial waveguide converter 54, and the waveguide 56 is connected to a microwave generator 58 made of magnetron or the like.

  In the above-described configuration, for example, 2.45 GHz microwave generated by the microwave generator 28 propagates through the waveguide 56 and is supplied to the coaxial waveguide 52 via the coaxial waveguide converter 54. The microwave propagated through the coaxial waveguide 52 is reduced in wavelength by the slow wave plate 48, and then passes through the dielectric plate 46 by the microwave radiation member made of a plating layer formed on the surface of the slow wave plate 48. Are emitted toward the processing space of the processing container 42.

  A plasma gas is supplied to the processing space in the processing container 42, and the plasma gas is turned into plasma by microwaves. The plasma processing is performed on the semiconductor wafer W placed on the mounting table 44 by the plasma.

  Next, the retardation plate 48 in the present embodiment will be described with reference to FIG. FIG. 9 is a cross-sectional view of the slow wave plate 48.

The slow wave plate 48 is formed of a dielectric material such as alumina (AlO ₃ ), silicon nitride (Si ₃ N ₄ ), aluminum nitride (AlN), or quartz, and has a flat disk shape. A projection 48 a to which the coaxial waveguide 52 is connected is formed at the center portion of the slow wave plate 48. The protrusion 48a has an inclined surface 48b that forms a part of a conical shape, and prevents concentration of the electric field due to microwaves. The outer pipe 52a of the coaxial waveguide 52 is connected to the protrusion 48a. The outer tube 52a may be connected to the flat top surface 48c of the protrusion 48a, or may be connected to the inclined surface 48b.

  A through hole 48d into which the inner cable 52b of the coaxial waveguide 52 is inserted is formed at the center of the protrusion 48a. A tapered portion 48e is formed at the end of the through hole 48d on the processing container side, and the end of the inner cable 52b formed in a shape corresponding to the shape of the tapered portion is fitted.

  Here, a metal plating layer 60 of copper, gold, silver, nickel or the like is formed on the surface of the slow wave plate 48. The metal plating layer 60 is formed on the entire surface except for the top surface 48 c of the protrusion 48 a of the slow wave plate 48. In particular, the plating layer 60 formed on the surface of the retardation plate 48 facing the inside of the processing container 42 is etched in a predetermined pattern, and the portion from which the plating layer is removed functions as a slot.

  FIG. 10 is a plan view showing a surface of the slow wave plate 48 in which the slots 32 are formed in the metal plating layer 60. As shown in FIG. 10, each of the slots 32 has an elongated oval shape, and is arranged along three different circumferences P1, P2, and P3. The slot 32 is provided over the entire circumference of each of the circumferences P1, P2, and P3, but only a part thereof is shown in FIG. 10 for simplification. Here, the centers of the circumferences P1, P2, and P3 are deviated (eccentric) from the center of the outer shape of the slow wave plate 48, and their deviation directions (eccentric directions) are different.

  That is, the direction in which the center of the center circumference P2 deviates from the center of the outer shape of the slow wave plate 48 differs from the direction in which the center of the inner circumference P1 deviates from the center of the outer shape of the slow wave plate 48 by 120 degrees. . Further, the direction in which the center of the outer circumference P3 deviates from the center of the outer shape of the slow wave plate 48 differs from the direction in which the center of the central circumference P2 deviates from the center of the outer shape of the slow wave plate 48 by 120 degrees. . Thus, the centers of the circumferences P1, P2, and P3 are shifted in different directions.

  As described above, when the slots 32 are arranged along a plurality of non-concentric circles, the surface wave propagated in the radial direction in the metal plating layer 30 and reflected by the outer peripheral surface returns toward the center of the slow wave plate 48. The center of the slow wave plate 48 is not concentrated. That is, it returns to a certain size range according to the deviation amount of the circumferences P1, P2, and P3. Therefore, according to the arrangement of the slot 62 according to the present embodiment, when the circumferences P1, P2, and P3 are concentric circles, the surface waves are concentrated at one point, thereby causing nonuniformity in the electron density of the plasma space. Compared with the conventional planar antenna member, the non-uniformity is improved, and the plasma density distribution can be made uniform to some extent.

  Although the slots 62 shown in FIG. 10 are arranged in a plurality of non-concentric circles, they may be arranged in a spiral shape or a plurality of concentric circles. Further, the shape of the slot 62 is not limited to a long and narrow ellipse as shown in FIG. 10, and a circular shape, a triangular shape, a square shape, a rectangular shape or the like can be adopted. However, in the case of a polygonal shape, the corners are rounded. It is preferable to prevent the concentration of the electric field. Alternatively, two slots may be arranged close to each other in a T shape to form a slot pair, and a large number of slot pairs may be arranged in a plurality of concentric circles, spirals, or a plurality of non-concentric circles.

  The thickness of the plating layer 60 is preferably thicker than the microwave skin depth δ, and is preferably determined based on the following equation.

δ = (2 / ωσμ ₀ ) ^1/2
Here, ω is the angular frequency, σ is the conductivity, and μ ₀ is the magnetic permeability in vacuum.

When the plating layer 60 is formed by copper plating using a microwave of 2.45 GHz, the conductivity of copper is σ = 6.45 × 10 ⁷ (Ωm) ⁻¹ , and the vacuum permeability μ ₀ = 1.257. Since × 10 ⁻⁶ Hm ⁻¹ and the angular frequency is 2π × 2.45 × 10 ⁹ Hz, the skin depth δ = 1.98 × 10 ⁻⁶ m = 1.98 μm (about 2 μm). Here, since the reduction of the electric field is about 30% at the skin depth of the plating layer, it is preferable to set the margin when the plating layer 60 is made of copper to about 6 μm by setting the margin ratio to 3 times.

  As described above, the slow wave plate 48 according to the present embodiment is provided with the metal plating layer 60, and the metal plating layer 60 functions as an antenna member (microwave radiation member). Therefore, the antenna member is provided separately. There is no need, and the number of parts can be reduced. Further, since the surface of the slow wave plate 48 is entirely covered with the metal plating layer 60 except for the portion for supplying the microwave and the portion for radiating (slot), the microwave leaks out of the slow wave plate 48. Is prevented, and the supplied microwave can be introduced into the processing space of the processing container without loss.

  In addition, since the metal member in which the slot is formed is the metal plating layer 60 having a thickness of about several μm, abnormal discharge in the slot is reduced, and higher power can be input than in the prior art. Throughput is improved. Further, since the slot portion is thin, the reflection of microwaves by the slot is reduced, and the radiation efficiency is improved.

  FIG. 11 is a cross-sectional view showing an example of the connection between the coaxial waveguide 52 and the slow wave plate 48. In the configuration shown in FIG. 11, the tip of the outer tube 52a of the coaxial waveguide 52 has a shape corresponding to the inclined surface 48b of the projection 48a of the slow wave plate 48 and is joined by soldering. Further, the front end portion of the inner cable 52b is also joined to the inner surface of the through hole 48d and the tapered portion 48e by soldering.

  Between the slow wave plate 48 (actually, the plating layer 60 formed on the surface of the slow wave plate 48) and the support member 50, an adhesive material 68 having good heat transfer characteristics is provided, and the slow wave plate 48 is attached to the slow wave plate 48. While firmly fixed to the support member 50, the heat of the slow wave plate 48 is transmitted to the support member 50. Note that the cooling water passage is omitted from the support member 50 shown in FIG. Further, the outer peripheral side surface of the slow wave plate 48 is pressed and fixed by a number of screws 66 penetrating the support member 50 through the metal plate 64. Thereby, reliable electrical contact between the slow wave plate 48 and the support member is maintained.

  FIG. 12 is a cross-sectional view showing an example of the connection between the coaxial waveguide 52 and the slow wave plate 48. In FIG. 12, the same components as those shown in FIG. 11 are denoted by the same reference numerals, and the description thereof is omitted. In the configuration shown in FIG. 12, the distal end of the outer tube 52 a of the coaxial waveguide 52 is configured to be opposed to and contact the top surface 48 c of the protrusion 48 a of the slow wave plate 48. The tip of the inner cable 52b is joined to the inner surface of the through hole 48d and the tapered portion 48e by soldering. In addition, a shield spiral 70 is provided at the tip of the inclined surface 48b of the protrusion 48a to further ensure electrical contact between the support member 50 and the metal plating layer 60 of the slow wave plate 48.

  The plating layer 60 according to the present embodiment can be formed by the same method as the plating layer according to the second embodiment described above. In addition, although the plating layer is formed on the upper surface and the lower surface of the slow wave plate, the plating layer may be formed on the outer peripheral side surface of the slow wave plate. In this way, almost the whole of the slow wave plate is covered with the plating layer, leakage of the microwave is prevented, and abnormal discharge can be prevented in almost the whole of the slow wave plate.

  In the second and third embodiments described above, the metal layer is formed on the surface of the retardation plate by plating, but the present invention is not limited to the plating layer. For example, the metal layer may be formed by depositing metal on the surface of the wave retardation plate by chemical vapor phase synthesis (PVD) or physical vapor phase synthesis (PVD).

(A), (B) is a figure which shows the structure of the plasma processing apparatus using the conventional radial line slot antenna. (A), (B) is a figure which shows the structure of the plasma processing apparatus by 1st Example of this invention. It is a figure which expands and shows a part of radial line slot antenna used with the plasma processing apparatus of FIG. 2 (A), (B). It is a figure which shows the structure of the process gas supply mechanism of the microwave plasma processing apparatus of FIG. 2 (A). It is a figure which shows the modification of the plasma processing apparatus of FIG. 2 (A), (B). It is a figure which shows the structure of the plasma processing apparatus by 2nd Example of this invention. (A)-(D) are figures which show the formation process of the slot plate of the radial line slot antenna used with the plasma processing apparatus of FIG. It is a schematic block diagram of the microwave plasma processing apparatus by 3rd Example of this invention. It is sectional drawing of the slow wave plate shown in FIG. It is a top view which shows the slot of the metal plating layer formed in the slow wave plate shown in FIG. It is sectional drawing which shows an example of the connection of a coaxial waveguide and a slow wave board. It is sectional drawing which shows the other example of a connection of a coaxial waveguide and a slow wave board.

Explanation of symbols

10, 10A, 10B, 100 Plasma processing apparatus 11 Processing vessel 11a Exhaust port 11b Overhang part 11p Plasma gas supply port 11r Processing gas supply port 11A, 11B, 11C Space 11G Decompression and He supply port 12 Substrate 13 Holding table 13A High frequency Power supply 14 Shower plate 14A Plasma excited gas nozzle openings 14B, 14C Plasma gas passage 15 Cover plate 16 Slot plates 16a, 16b Slot openings 16r Low resistance layer 16 ₁ Electroless plating layer 16 ₂ Electrolytic plating tank 17 Metal plate 18 Slow wave plate 18 ₁ ceramic adhesive layer 19 cooling block 19A coolant passage 20 radial line antenna 21 coaxial waveguide 21A outer waveguide 21B inside the feed line 30 process gas supply mechanism 31A processing gas passage 31B process gas nozzle 31C Plastic Diffusion path 31R Processing gas supply port Bath1 Electroless plating bath Bath2 Electroplating bath R Resist film R 'Resist pattern 40 Microwave plasma processing apparatus 42 Processing vessel 44 Mounting table 46 Dielectric plate 48 Slow wave plate 48a Protrusion 48b Inclined surface 48c Top surface 48d Through hole 48e Tapered portion 50 Support member 50a Passage 52 Coaxial waveguide 52a Outer tube 52b Inner cable 54 Coaxial waveguide converter 56 Waveguide 58 Microwave generator 60 Metal plating layer 62 Slot 64 Metal plate 66 Screw 68 Adhesive 70 Shield spiral

Claims (18)

A processing container provided with a mounting table on which a substrate to be processed is mounted;
A microwave generator that generates a microwave and supplies the microwave to the processing container; a delay generator that is provided between the microwave generator and the processing container and that shortens the wavelength of the microwave supplied from the microwave generator. Corrugated sheet,
A microwave radiating member that radiates a microwave whose wavelength is shortened by the slow wave plate to a space in the processing container,
A metal layer is formed on at least an upper surface and a lower surface of the retardation plate;
The said microwave radiation | emission member is comprised from the said metal layer formed in the surface of the said slow wave board, The plasma processing apparatus characterized by the above-mentioned. 2. The microwave plasma processing apparatus according to claim 1, wherein the microwave radiating member has a plurality of slots, and the slots are formed by removing the metal layer by etching. 3. The plasma processing apparatus according to claim 1, wherein a thickness of the metal layer is larger than a skin depth of the microwave generated by the microwave generator. The plasma processing apparatus according to claim 1, wherein the metal layer is a plating layer made of a material selected from the group consisting of copper, gold, silver, and nickel. The plasma processing apparatus according to claim 4, wherein the microwave has a wavelength of 2.45 GHz, the metal layer is a copper plating layer, and the thickness of the copper plating layer is 6 μm or more. The plasma processing apparatus according to claim 1, wherein the metal layer is a metal film deposited by chemical vapor deposition (CVD). The plasma processing apparatus according to claim 1, wherein the metal layer is a metal film deposited by physical vapor deposition (PVD). A coaxial waveguide for supplying the microwave from the microwave generator to the retardation plate;
The plasma processing apparatus according to claim 1, wherein the outer tube and the inner cable of the coaxial waveguide are connected to a central portion of the slow wave plate by soldering. Used in a microwave plasma processing apparatus having a processing vessel for performing plasma processing and a microwave generator for generating and supplying microwaves to the processing vessel. The wavelength of the microwaves supplied from the microwave generators A slow wave plate,
A slow wave plate, wherein at least an upper surface and a lower surface are covered with a metal layer, and a microwave radiation member is constituted by a part of the metal layer. 10. The retardation plate according to claim 9, wherein the microwave radiating member has a plurality of slots, and the slots are formed by removing the metal layer by etching. The retardation plate according to claim 9 or 10, wherein a thickness of the metal layer is larger than a skin depth of the microwave generated by the microwave generator. The retardation plate according to any one of claims 9 to 11, wherein the metal layer is a plating layer made of a material selected from the group consisting of copper, gold, silver, and nickel. 13. The retardation plate according to claim 12, wherein the wavelength of the supplied microwave is 2.45 GHz, the metal plating layer is a copper plating layer, and the thickness of the copper plating layer is 6 μm or more. 14. The projection according to claim 9, further comprising: a protruding portion that is joined by soldering to a coaxial waveguide that supplies the microwave from the microwave generator to the slow wave plate. The retardation plate described in the item. The plasma processing apparatus according to claim 1, wherein an outer peripheral side surface of the slow wave plate is covered with the metal layer. It further has a coaxial waveguide that propagates the microwave from the microwave generator and supplies the microwave to the slow wave plate, and the coaxial waveguide is soldered to the slow wave plate. The plasma processing apparatus according to any one of claims 1 to 8. The retardation plate according to any one of claims 9 to 14, wherein an outer peripheral side surface of the retardation plate is covered with the metal layer. The microwave from the microwave generator is propagated by a coaxial waveguide and supplied to the slow wave plate, and the coaxial waveguide is soldered to the slow wave plate. The retardation plate according to any one of claims 9 to 14 and 17.

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