TW201001530A - Electrode structure and substrate processing apparatus - Google Patents

Abstract

An electrode structure capable of adequately increasing an electron density in a processing space at a part facing a circumferential edge portion of a substrate. In a processing chamber of a substrate processing apparatus that performs RIE processing on a wafer, an upper electrode of the electrode structure is disposed to face the wafer placed on a susceptor inside the processing chamber. The upper electrode includes an inner electrode facing a central portion of the wafer and an outer electrode facing the circumferential edge portion of the wafer. The inner and outer electrodes are connected with first and second DC power sources, respectively. The outer electrode has its first secondary electron emission surface extending parallel to the wafer and its second secondary electron emission surface obliquely extending relative to the first secondary electron emission surface.

Description

201001530 VI. TECHNOLOGICAL FIELD The present invention relates to an electrode structure and a substrate processing apparatus, and more particularly to an electrode structure in which a DC power source is connected in a processing chamber disposed in a substrate processing apparatus. [Prior Art] The substrate processing apparatus that is subjected to the plasma treatment includes a processing chamber for accommodating the wafer, a mounting table on which the wafer is placed in the processing chamber, and a shower head that supplies the processing gas to the processing space in the processing chamber. In the substrate processing apparatus, a high-frequency power source is connected to the mounting table, and the mounting table applies high-frequency power to the processing space, and the processing gas supplied to the processing space is excited by high-frequency power to become plasma (cation or electron). Since the plasma distribution in the processing space has a great influence on the result of the electric paddle processing of the wafer, it is preferable to actively control the distribution of the electric paddle, and correspondingly, in order to control the plasma distribution, especially the electron density distribution, the application to the shower head is performed. DC voltage. When a DC voltage is applied to the shower head, the constituent members of the shower head are connected to the DC electrode of the disk-shaped patio electrode plate exposed in the processing space. Here, when a negative DC voltage is applied to the showerhead, the showerhead introduces only the cations in the plasma. Since the DC voltage is different from the high-frequency voltage and the potential does not change with time, the cation is continuously introduced into the shower head. Further, the cation introduced into the shower head releases secondary electrons from the constituent atoms of the shower head. As a result, the portion which is opposed to the shower head of the processing space is increased from -5 to 201001530 (see, for example, Patent Document 1). [Problem to be Solved by the Invention] However, the electron density distribution is affected by the shape of the processing chamber, etc., and it is uneven in the processing space. However, when a patio electrode plate is formed by a conductive plate, even if a DC voltage is applied to the patio electrode plate, since only the electron density of all portions in the processing space facing the shower head is increased, the electron density distribution cannot be released. Evenly. As a result, the electron density decreases in a portion facing the peripheral edge portion of the wafer in the processing space, and the etching rate in the peripheral portion of the wafer is lower than the center portion of the wafer during the etching process. SUMMARY OF THE INVENTION An object of the present invention is to provide an electrode structure and a substrate processing apparatus which can sufficiently increase the electron density in a portion facing a peripheral portion of a substrate in a processing space. (Means for Solving the Problem) In order to achieve the above object, the electrode structure described in the first aspect of the patent application belongs to a processing chamber provided in a substrate processing apparatus that applies plasma treatment to a substrate, and An electrode structure in which the substrate is disposed on the mounting table in the processing chamber, and includes an inner electrode facing the central portion of the substrate, and an outer electrode facing the peripheral portion of the substrate, wherein the inner electrode is connected to the first direct current The power source is connected to the second DC power source of the outer-6-201001530 side electrode, and the outer electrode has a first surface parallel to the substrate and a second surface inclined to the first surface. In the electrode structure according to the first aspect of the invention, the first surface and the second surface are directed to a peripheral portion of the substrate. In order to achieve the above object, the substrate processing apparatus according to the third aspect of the invention is a substrate processing apparatus for applying a plasma treatment to a substrate, characterized in that: a processing chamber for accommodating the substrate is disposed and disposed on the substrate a mounting table on which the substrate is placed in the processing chamber, and an electrode structure disposed in the processing chamber and facing the substrate placed on the mounting table, wherein the electrode structure includes an inner electrode facing the central portion of the substrate, and The first electrode is connected to the inner electrode of the outer surface of the substrate, and the inner electrode is connected to the first direct current power source, and the outer electrode is connected to the second direct current power source. The outer electrode has a first surface parallel to the substrate and is inclined to the first surface. The second side. According to the electrode structure described in the first aspect of the invention, and the substrate processing apparatus according to the third aspect of the patent application, the second DC power source is connected to the side electrode opposite to the peripheral portion of the substrate. Apply a DC voltage. When a direct current voltage is applied to the outer electrode, the outer electrode introduces a cation in the plasma to release secondary electrons. As a result, the electron density can be increased in a portion facing the peripheral portion of the substrate in the processing space. Further, the second electrode of the second DC power source has a first surface which is parallel to the substrate, and the second surface of the 201001530 which is inclined to the first surface. Secondary electrons are released from the first surface and the second surface. Since the second surface is inclined with respect to the first surface, the secondary electrons emitted from the second surface overlap with the secondary electrons emitted from the first surface in a portion facing the peripheral edge portion of the substrate in the processing space. As a result, the electron density can be sufficiently increased in a portion facing the peripheral portion of the substrate in the processing space. According to the electrode structure described in the second paragraph of the patent application, the first surface and the second surface are directed to the peripheral portion of the substrate, so that the secondary electrons released from the first surface and the second surface released from the second surface The electrons overlap directly above the peripheral portion of the substrate. As a result, the electron density can be surely and sufficiently increased directly above the peripheral portion of the substrate. [Embodiment] Hereinafter, embodiments of the present invention will be described with reference to the drawings. Fig. 1 is a cross-sectional view schematically showing the configuration of a substrate processing apparatus according to the present embodiment, and Fig. 2 is an enlarged cross-sectional view schematically showing the configuration of the vicinity of the outer electrode of the upper electrode in Fig. 1 . The substrate processing apparatus is configured to apply a RIE (Reactive Ion Etching) process to a semiconductor wafer as a substrate. In the first and second figures, the substrate processing apparatus 10 is provided with a cylindrical processing chamber 11 and disposed in the processing chamber η as a semiconductor wafer having a diameter of 300 mm (hereinafter referred to as ' The cylindrical susceptor 12 is simply referred to as a "wafer" W mounting table. In the substrate processing apparatus 10, the inner side wall of the processing chamber 11 and the side surface of the receiver -12-201001530 receiver 1 2 are formed to form a flow path outside the gas discharge processing chamber 1 1 of the processing space S to be described later. Exhaust flow path 13 3. On the way of the exhaust flow path 13, an exhaust plate (exhaust ring) 14 is disposed. The exhaust plate 14 is a plate-like member having a plurality of through holes, and functions as a partition plate that partitions the processing chamber 11 into upper and lower portions. The upper portion of the processing chamber 11 (hereinafter referred to as "reaction chamber") 15 partitioned by the exhaust plate 14 generates plasma as will be described later. Further, the lower portion of the processing chamber 11 (hereinafter referred to as "exhaust chamber (manifold)") 16 is connected to the exhaust pipes 17 and 18 of the gas discharged from the processing chamber 11. The venting plate 14 captures or reflects the plasma generated in the reaction chamber 15 to prevent leakage toward the manifold 16. The exhaust pipe 17 is connected to a TMP (Turbo Molecular Pump) (not shown), and the exhaust pipe 18 is connected to a DP (DryPump) (not shown), and the pumps are evacuated in the treatment chamber 1 1 to be depressurized. Specifically, the DP system decompresses the pressure in the processing chamber 1 1 from the atmospheric pressure to the medium vacuum state (for example, 1.3 × 10 〇 Pa (O.lTorr) or less), and the TMP cooperates with the DP to decompress the inside of the processing chamber 1 1 . A high vacuum state (for example, 1.3 M WdpaCl. OxlO^Torr) below the pressure in the medium vacuum state. Further, the pressure in the processing chamber 11 is controlled by an APC valve (not shown). The first high frequency power supply 19 and the second high frequency power supply 20 are connected to the susceptor 12 in the processing chamber 11 via the first integrator 21 and the second integrator 22, and the first high frequency power supply 19 applies a comparison to the susceptor 12. The high frequency is, for example, a high frequency power of 60 MHz, and the second high frequency power source 20 applies a relatively low frequency, for example, 2 MHz high frequency power to the susceptor 12. Accordingly, the susceptor 12 functions as a lower electrode for applying a high-frequency electric force to the processing space S between the susceptor 1 2 and the shower head 30 to be described later. Further, the susceptor 12 is provided with an electrostatic chuck 24 composed of a disk-shaped insulating member having an electrostatic electrode plate 23 therein. When the wafer W is placed on the receiver 12, the wafer W is placed on the electrostatic chuck 24. Further, in the electrostatic chuck 24, a DC power source 25 is electrically connected to the electrostatic electrode plate 23. When a positive DC voltage is applied to the electrostatic electrode plate 23, a negative potential is generated on the surface of the wafer W on the side of the electrostatic chuck 24 (hereinafter referred to as "back surface"), and is on the back side of the electrostatic electrode plate 23 and the wafer W. A potential difference is generated between the Coulomb force or the Johnsonsen-Rahbek force caused by the potential difference, and the wafer W is adsorbed and held in the electrostatic chuck 24 °. Further, on the susceptor 12, the crystal is surrounded by the adsorption and retention. In the form of a circle W, an annular focus ring 26 is placed. The focus ring 26 is made of a conductive member, for example, made of tantalum, which causes the plasma to converge toward the surface of the wafer W, thereby improving the efficiency of the RIE process. Further, an annular refrigerant chamber 27 extending in the circumferential direction is provided inside the susceptor 12, for example. In the refrigerant chamber 27, a low-temperature refrigerant such as cooling water or grease liquid (Galden: registered trademark) is circulated and supplied from a cooling unit (not shown) via a refrigerant pipe 28. The susceptor 12, which is cooled by the low-temperature refrigerant, cools the wafer W and the focus ring 26 via the electrostatic chuck 24. A portion of the upper surface of the electrostatic chuck 24 is held by the wafer W (hereinafter referred to as "adsorption surface"), and a plurality of heat transfer gas supply holes 29 are opened. The plurality of heat transfer gas supply holes 29 are supplied through the heat transfer gas supply holes 29 to supply the helium (H e ) gas as the heat transfer gas to the gap between the adsorption surface and the back surface of the wafer W - 201001530. The helium gas system supplied to the gap between the adsorption surface and the back surface of the wafer w effectively transfers the heat of the wafer W to the electrostatic chuck 24. A shower head 30 is provided on the patio portion of the processing chamber 11. The shower head 30 has an upper surface electrode 31 (electrode structure) that is exposed to the processing space S and is opposed to the wafer W (hereinafter referred to as "mounting wafer W") placed on the susceptor 12, and is insulated. The insulating plate 3 2 composed of the member and the electrode fishing support 33 for supporting the upper electrode 31 via the insulating plate 32 are superposed in the order of the upper electrode 31, the insulating plate 32, and the electrode fishing support 33. The electrode fishing support 33 has a buffer chamber 39 inside. The buffer chamber 39 has a cylindrical space, and is divided into an inner buffer chamber 39a and an outer buffer chamber 39b by an annular seal member such as a serpentine ring 40. A processing gas introduction pipe 4 is connected to the inner buffer chamber 39a, and a processing gas introduction pipe 42 is connected to the outer buffer chamber 39b. The processing gas introduction pipes 4, 42 are paired with the inner buffer chamber 39a and the outer buffer chamber 3, respectively. 9b introduces a process gas. Since the process gas introduction pipes 41 and 42 each have a flow rate controller (MFC) (not shown), the flow rates of the process gases introduced into the inner buffer chamber 39a and the outer buffer chamber 39b are controlled independently. Further, the buffer chamber 39 is communicated with the processing space S via the gas hole 43 of the electrode fishing support 33, the gas hole 44 of the insulating plate 32, and the gas hole 36 of the upper electrode 31, and is introduced into the inner buffer chamber 39a or the outer buffer chamber. The processing gas of 39b is supplied to the processing space S. At this time, the distribution of the processing gas in the processing space -11 - 201001530 S is controlled by adjusting the flow rate of the processing gas introduced into the inner buffer chamber 319a and the outer buffer chamber 319b. In the substrate processing apparatus ○0, when the RIE process is performed on the mounted wafer w, the shower head 30 supplies the processing gas to the processing space S, and the first high-frequency power source 19 passes through the susceptor 12 to the processing space S. A local frequency power of 60 MHz is applied, and the second high frequency power source 20 applies high frequency power of 2 MHz to the susceptor 12. At this time, the processing gas is excited into a plasma by high frequency power of 60 MHz. Further, since the high frequency power of 2 MHz generates a bias voltage in the susceptor 12, cations or electrons in the plasma are introduced to the surface of the wafer W, and the carrier wafer W is subjected to RIE processing. Further, in order to partially control the electron density distribution in the processing space, an inner electrode that divides the upper electrode into a central portion of the wafer and an outer electrode that faces the peripheral portion of the wafer, the inner electrode and the outer side are developed. A method of independently applying a DC voltage of a negative polarity to each of the electrodes has been developed. In this method, a direct current voltage different from that of the inner electrode 施加 is applied to the outer electrode to independently control the electron density of the portion facing the outer electrode in the processing space and the electron density of the portion facing the inner electrode. In the present inventors, the present inventors have found that when the surface of the outer electrode facing the opposing surface of the processing space (hereinafter referred to as "outer electrode surface area") is increased by an experiment by RIE treatment, it faces the outer electrode in the processing space. The electron density of the surface facing portion (hereinafter referred to as the "outer electrode facing portion") is increased, and as a result, the etching rate in the peripheral portion of the wafer is increased (see Fig. 3). Further, the inventors of the present invention found that when the 直流 of the DC voltage applied to the outer electrode is increased, the electron density of the opposing portion of the outer electrode is still increased, and -12-201001530 results in an increase in the etching rate in the peripheral portion of the wafer. Specifically, when the absolute voltage of the DC voltage applied to the inner electrode is maintained, the condensing of the DC voltage applied to the outer electrode is raised to 900 V, and the etching is performed in the peripheral portion of the wafer (see Fig. 4). However, in a conventional substrate processing apparatus, since other processing chamber constituent members exist in an external direction, it is difficult to add the outer side to a predetermined thickness or more. Further, it is difficult to increase the DC voltage applied to the outer electrode by the performance and the like. That is, it is generally difficult to sufficiently increase the electron density in the portion where the peripheral portion of the treatment is opposed. In the substrate processing apparatus 10, the inner electrode 34 and the electrode 34 facing the center portion of the wafer W are placed opposite to the peripheral portion of the wafer W, and the side electrode 35 has a crystal. The first and second electron emission surfaces 35b (the secondary electron emission surface 35a and the outer electrode 35b) which are inclined to the first secondary electron release wafer W are parallel to the first and third sides of the circle W (the first surface) Here, the inner electrode 34 has a diameter-like member, and the plurality of gas electrodes 35 penetrating the thickness direction have an outer diameter of 380 mm and an inner diameter of 300 mm. The inner electrode 34 and The outer electrode 35 is made of a conductive material such as a single crystal germanium. In this case, it is confirmed that the I of the 300V is increased from 300 V _ by about 7%, and the peripheral electrode surface area of the side electrode is increased from the source of the DC power source to In the given space, the wafer i 31 has a carrier and the inner side electrode 35, and the outer electron emission surface 35a faces the second surface. The wafer W 3 00 mm round plate ?L 3 6 is placed in the first direction. The outer electric ring-shaped member is semi-conductive or semi-conductive. 13-201001530 Further, in the upper electrode 31, the first DC power source 3 is connected to the inner electrode 34, and the second DC power source 3 is connected to the outer electrode 35. 8. The inner electrode 34 and the outer electrode 35 are each independently applied with a direct current voltage. In the substrate processing apparatus 10, during the RIE process, the first DC power source 37 and the second DC power source 38 apply a negative DC voltage to the inside electrode 34 and the outside electrode 35 of the upper electrode 31. At this time, the inner electrode 34 or the outer electrode 35 is introduced into the cation in the plasma of the processing space S. The introduced cation imparts energy to the electrons in the constituent atoms in the inner electrode 34 or the outer electrode 35. When the energy imparted exceeds a given enthalpy, the electrons in the constituent atoms act as secondary electrons from the surface of the inner electrode 34. The first secondary electron emission surface 35a and the second secondary electron emission surface 35b of the outer electrode 35 are released. As described above, the inner electrode 34 is a disk-shaped member, and since only the surface parallel to the wafer W is exposed to the processing space S, the secondary electrons released from the surface are placed from the center of the wafer W. The department is almost evenly distributed to the periphery. As a result, the RIE process is fully promoted throughout the placement of the wafer w. As described above, the first secondary electron emission surface 35 a and the second secondary electron emission surface 35 b of the outer electrode 35 are directed to the peripheral portion of the wafer w, so that the first secondary electron The release surface 35a and the secondary electrons released from the second secondary electron emission surface 35b overlap directly above the peripheral portion of the wafer w. As a result, the electron density can be sufficiently extracted right above the peripheral portion on which the wafer W is placed, and the RIE process can be promoted at the peripheral portion of the wafer W. Further, the operation of each of the components of the substrate processing apparatus 10-14-201001530 is controlled by a CPU of a control unit (not shown) provided in the substrate processing apparatus 10. When the upper electrode 31 is used as the electrode structure according to the present embodiment, the second DC power source 38 is connected to the side electrode 35 opposite to the peripheral portion of the wafer W, and a DC voltage is applied thereto. When a DC voltage is applied to the outer electrode 35, the outer electrode 35 introduces a cation in the plasma to release secondary electrons. As a result, the electron density can be increased directly above the peripheral portion of the wafer W placed in the processing space S. Further, the second DC power source 3 8 is connected to the first secondary electron emitting surface 35a that is parallel to the mounting wafer W, and the first secondary electron emission surface 35a is placed toward the wafer W. The second secondary electron emission surface 35b is inclined, and the secondary electrons are released from the first secondary electron emission surface 35a and the second secondary electron emission surface 35b. Since the first secondary electron emission surface 35a and the second secondary electron emission surface 35b are directed to the peripheral portion of the wafer W, the electron density can be sufficiently increased just above the peripheral edge portion on which the wafer W is placed. The peripheral portion of the wafer W is subjected to RIE processing. In the upper electrode 31, since the area of the opposing surface of the wafer W facing the wafer W is not increased, the electron density can be sufficiently increased directly above the peripheral portion of the wafer W, so that it is not necessary to increase the outer side. Electrode 35. As a result, the amount of use of the high-priced single crystal germanium can be eliminated, and the manufacturing cost of the upper electrode 31 can be reduced. Further, in the upper electrode 31, not only the first secondary electron emission surface 35a but also the second secondary electron emission surface 35b is directed to the peripheral portion of the wafer W, but the second secondary electron emission surface 35 b The second secondary electron emission surface 35b may be perpendicular to the first secondary electron emission surface 35a, for example, even if it is not directed to the peripheral portion of the wafer W of the -15-201001530. Even at this time, since the secondary electrons emitted are overlapped in the portion facing the peripheral portion of the wafer W in the processing space S, the portion facing the peripheral portion of the wafer W can be sufficiently improved. Electronic density. Further, the second secondary electron emission surface 35b does not need to be a flat surface, and may be a paraboloid that faces the peripheral portion of the wafer W. In this case, the secondary electrons can be collectively released from the second secondary electron emission surface 35b toward the peripheral portion of the mounting wafer W, and the electron density directly above the peripheral portion of the wafer W can be more sufficiently increased. . Further, in the above-described embodiment, the substrate to which the uranium engraving treatment is applied is the semiconductor wafer W, but is not limited to the substrate to which the etching treatment is applied, and is, for example, an LCD (Liquid Crystal Display) or an FPD (Flat). Glass substrates such as Panel Display can also be used. [Embodiment] Next, an embodiment of the present invention will be described. First, the inventors of the present invention applied RIE processing to the placed wafer W in the substrate processing apparatus 10, and measured the saturation ratio of the peripheral portion of the mounted wafer W in the RIE processing. In the graph of the graph, "Lu" is not shown as -16-201001530. Comparative Examples 1 and 2 Next, the inventors prepare two outer electrodes having only surfaces parallel to the wafer W and having different surface areas. Instead of the outer electrode 35. Then, the substrate processing apparatus 1 替换 replaces the outer electrode 35 with each of the prepared outer electrodes, and performs RIE processing on the mounted wafer W to measure the etching rate of the peripheral portion of the wafer W to be placed in the RIE process. The result is indicated by "♦" in the graph of Fig. 5. The horizontal axis of the graph of Fig. 5 indicates the surface area of the outer electrode. Here, the surface area of the outer electrode corresponds to the total area of the first secondary electron emission surface 35a and the second secondary electron emission surface 35b in the first embodiment, or the wafers in the comparative examples 1, 2 and The area of the W parallel surface. In the graph of Fig. 5, the horizontal axis represents the surface area of the external electrode of Example 1 or Comparative Example when the surface area of the external electrode of Comparative Example 1 is set to 1, and the vertical axis is Comparative Example 1. The etching rate of Example 1 or each comparative example when the etching rate was set to 1. According to the graph of Fig. 5, it can be seen that the second secondary electron emission surface 35b inclined to the first secondary electron emission surface 35a can be efficiently increased in comparison with the surface area for increasing the outer area. The electron density directly above the peripheral portion of W can facilitate the RIE process on the peripheral portion of the wafer W. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a cross-sectional view schematically showing the configuration of a substrate processing apparatus according to an embodiment of the present invention. -17- 201001530 Fig. 2 is an enlarged cross-sectional view showing the configuration of the electrode on the outer side of the upper electrode in Fig. 1 . Fig. 3 is a graph showing the relationship between the surface area of the outer side electrode and the etching rate in the peripheral portion of the wafer in the outer electrode. Fig. 4 is a graph showing the rate of increase in the etching rate when the enthalpy of the DC voltage applied to the outer electrode is increased. Fig. 5 is a graph showing the relationship between the outer electrode surface area and the etching rate in the peripheral portion of the wafer in Example 1 and Comparative Examples 1 and 2 of the present invention. [Description of main component symbols] W: Wafer 1 〇: substrate processing apparatus 1 1 : processing chamber 12 : susceptor 3 1 : upper electrode 3 4 : inner electrode 3 5 : outer electrode 35a : first secondary electron emission surface 3 5b: 2nd secondary electron release surface 3 7 : 1st DC power supply 3 8 : 2nd DC power supply

Claims (1)

201001530 VII. Patent Application No. 1. An electrode structure disposed in a processing chamber provided in a substrate processing apparatus that applies plasma treatment to a substrate, and is opposed to the substrate disposed on the mounting table in the processing chamber, and is characterized in that An inner electrode facing the central portion of the substrate and an outer electrode facing the peripheral portion of the substrate, wherein the inner electrode is connected to the first direct current power source, and the outer electrode is connected to the second direct current power source, and the outer electrode has the same The first surface parallel to the substrate and the second surface inclined to the first surface. The electrode structure according to the first aspect of the invention, wherein the first surface and the second surface are directed to a peripheral portion of the substrate. a substrate processing apparatus for applying a plasma treatment to a substrate, comprising: a processing chamber for accommodating the substrate; a mounting table disposed on the substrate in the processing chamber; and being disposed in the processing An electrode structure facing the substrate placed on the mounting table, wherein the electrode structure includes an inner electrode facing the center portion of the substrate, and an outer electrode facing the peripheral edge portion of the substrate, wherein the inner electrode is connected The first DC power source is connected to the second DC power source, and the outer electrode has a first surface parallel to the substrate and a second surface inclined to the first surface of -19-201001530. 4. The substrate processing apparatus according to claim 3, wherein the first surface and the second surface are directed to a peripheral portion of the substrate. -20-