KR100845885B1 - Large area inductive coupled plasma reactor - Google Patents

Abstract

The present invention relates to an inductively coupled plasma reactor, and more particularly, to an inductively coupled plasma reactor having a very easy structure. The inductively coupled plasma reactor of the present invention includes a vacuum chamber having a susceptor on which a substrate to be processed is placed, and a plurality of linear plasma generating units installed across the top of the vacuum chamber. The plurality of linear plasma generating units are installed along a plurality of linear dielectric tubes arranged in parallel and a plurality of linear dielectric tubes and receive radio frequency power from a main power source to generate induced electromotive force for generating an inductively coupled plasma into the vacuum chamber. It includes an antenna coil for transmitting. According to the large-area inductively coupled plasma reactor of the present invention, a large-area high density plasma can be generated uniformly. In particular, the structural characteristics of the linear plasma generating unit have a structure that is very easy to expand to a large area in accordance with an increase in the size of the substrate which is becoming large, and uniform high density plasma can be generated over a large area. Uniform plasma treatment is possible.

Inductively Coupled Plasma, Antenna Coil, Radio Frequency

Description

LARGE AREA INDUCTIVE COUPLED PLASMA REACTOR}

In order to more fully understand the drawings used in the detailed description of the invention, a brief description of each drawing is provided.

1 is a cross-sectional view of a plasma reactor according to a preferred embodiment of the present invention.

2 is a partial perspective view showing an assembly configuration of an antenna coil, a magnetic core, and a flat plate electrode installed inside a linear plasma generating unit.

3 is a cross-sectional view illustrating an arrangement structure of a plurality of linear plasma generating units and a continuous antenna coil arranged in parallel.

4 is a view for explaining an induction magnetic field by a continuous antenna coil.

5 is a cross-sectional view illustrating an arrangement structure of a plurality of antenna coils wound in parallel with a plurality of linear plasma generating units arranged in parallel.

* Description of the symbols for the main parts of the drawings *

100: inductively coupled plasma reactor 110: vacuum chamber

120: gas supply unit 130: linear plasma generating unit

The present invention relates to an inductively coupled plasma reactor, and more particularly, to an inductively coupled plasma reactor having a very easy structure.

Plasma is a highly ionized gas containing the same number of positive ions and electrons. Plasma discharges are used for gas excitation to generate active gases containing ions, free radicals, atoms, molecules. The active gas is widely used in various fields and is typically used in a variety of semiconductor manufacturing processes such as etching, deposition, cleaning, ashing, and the like.

There are a number of plasma sources for generating plasma, and the representative examples are capacitive coupled plasma and inductive coupled plasma using radio frequency. Capacitively coupled plasma sources have the advantage of high process productivity compared to other plasma sources due to their high capacity for precise capacitive coupling and ion control. Capacitively coupled plasma sources can easily increase ion density with increasing radio frequency power supply and are therefore commonly used to obtain high density plasma. However, increasing radio frequency power increases ion bombardment energy. As a result, in order to prevent damage due to ion bombardment, radio frequency power is limited.

Inductively coupled plasma sources are typically developed using a radio frequency antenna (RF antenna) and a transformer (also called transformer coupled plasma). The development of technology to improve the characteristics of plasma, and to increase the reproducibility and control ability by adding an electromagnet or a permanent magnet or adding a capacitive coupling electrode.

As the radio frequency antenna, a spiral type antenna or a cylinder type antenna is generally used. The radio frequency antenna is disposed outside the plasma reactor and transmits induced electromotive force into the plasma reactor through a dielectric window such as quartz. Inductively coupled plasma using a radio frequency antenna can obtain a high density plasma relatively easily, but the plasma uniformity is affected by the structural characteristics of the antenna. Therefore, efforts have been made to improve the structure of the radio frequency antenna to obtain a uniform high density plasma.

However, in order to obtain a large plasma, it is limited to widen the structure of the antenna or increase the power supplied to the antenna. For example, it is known that a non-uniform plasma is generated in the radiographic state by a standing wave effect. In addition, when high power is applied to the antenna, the capacitive coupling of the radio frequency antenna increases, so that the dielectric window must be thickened, thereby increasing the distance between the radio frequency antenna and the plasma, thereby lowering power transmission efficiency. Losing problems occur.

In the recent semiconductor manufacturing industry, plasma processing technology has been further improved due to various factors such as ultra-miniaturization of semiconductor devices, the enlargement of silicon wafer substrates for manufacturing semiconductor circuits, the enlargement of glass substrates for manufacturing liquid crystal displays, and the emergence of new target materials. This is required. In particular, there is a need for improved plasma sources and plasma processing techniques that have good processing capabilities for large area workpieces.

Accordingly, the present invention has been made to solve the above-mentioned problems, and its object is to increase the uniformity of plasma generation and processing while having a structure that is very easy to expand in large area in accordance with the increase in the size of the substrate to be enlarged. To provide a large area inductively coupled plasma reactor.

One aspect of the present invention for achieving the above technical problem relates to an inductively coupled plasma reactor. The large area inductively coupled plasma reactor of the present invention comprises: a vacuum chamber having a susceptor on which a substrate to be processed is placed; A plurality of linear plasma generating units arranged across the top of the vacuum chamber, the plurality of linear plasma generating units comprising: a plurality of linear dielectric tubes arranged in parallel; An antenna coil is installed along a plurality of linear dielectric tubes and receives radio frequency power from a main power supply and delivers induced electromotive force for generating an inductively coupled plasma into the vacuum chamber.

In one embodiment, each of which is installed inside the plurality of linear dielectric tube, but is installed to surround the antenna coil from the upper side includes a magnetic core for enhancing the strength of the magnetic field induced into the vacuum chamber.

In one embodiment, it is provided along the antenna coil, and includes a flat electrode, which is installed on the bottom of the plurality of linear dielectric tube to be positioned below the antenna coil and connected to ground.

In one embodiment, the antenna coil is wound one or more times zigzag along the interior of the plurality of linear dielectric tubes.

In one embodiment, a gas supply unit for supplying a process gas along a plurality of linear plasma generating units.

In one embodiment, the gas supply unit alternately supplies two or more process gases alternately along a plurality of linear plasma generating units.

In one embodiment, the susceptor is biased by one or more bias power supplies.

DETAILED DESCRIPTION In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the embodiments of the present invention, reference should be made to the accompanying drawings which illustrate preferred embodiments of the present invention and the contents described in the accompanying drawings. The embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited by the embodiments described below. This embodiment is provided to more completely explain the present invention to those skilled in the art. Accordingly, the shape of the elements in the drawings and the like are exaggerated to emphasize a clearer description. In understanding the drawings, it should be noted that like parts are intended to be represented by the same reference numerals as much as possible. And a detailed description of known functions and configurations that are determined to unnecessarily obscure the subject matter of the present invention is omitted.

(Example)

Hereinafter, the large-area inductively coupled plasma reactor of the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view of a plasma reactor according to a preferred embodiment of the present invention, Figure 2 is a partial perspective view showing the assembly configuration of the antenna coil, the magnetic core, and the plate electrode installed in the linear plasma generating unit.

1 and 2, a large area inductively coupled plasma reactor 100 according to a preferred embodiment of the present invention includes a vacuum chamber 110 having a susceptor 112 on which a substrate 114 to be processed is placed. . A plurality of linear plasma generating units 130 are installed across the vacuum chamber 110. The plurality of linear plasma generating units 130 are provided with a plurality of linear dielectric tubes 132 arranged in parallel, and an antenna coil 136 along the plurality of linear dielectric tubes 132.

3 is a cross-sectional view illustrating an arrangement structure of a plurality of linear plasma generating units and a continuous antenna coil arranged in parallel.

Referring to FIG. 3, the antenna coil 136 is wound one or more times in a zigzag fashion along the interior of the plurality of linear dielectric tubes 136, and may be repeatedly wound in a reciprocating manner. You can make a bundle. In addition, as illustrated in FIG. 5, the plurality of antenna coils 136a and 136b may be wound in parallel.

4 is a view for explaining an induction magnetic field by a continuous antenna coil.

Referring to FIG. 4, the antenna coil 136 receives radio frequency power from the main power supply 150 and delivers induced electromotive force for generating inductively coupled plasma into the vacuum chamber 110. An impedance matcher 156 for impedance matching may be configured between the main power supply 150 and the antenna coil 136.

It can be seen that the induced magnetic fields 172 and 174 induced by the coil antenna 136 are alternately generated in the vertical direction between the plurality of linear dielectric tubes 132. In addition, the induced magnetic fields are generated along the plurality of linear dielectric tubes 132 by the induced magnetic fields 172 and 174, thereby generating a large area plasma in the upper portion of the vacuum chamber 110.

Again, referring to FIGS. 1 and 2, the magnetic cores 134 may be installed inside the plurality of linear dielectric tubes 132 to enhance the strength of the magnetic field induced by the antenna coil 136. The magnetic core 134 is installed to surround the antenna coil 134 on the upper side to enhance the strength of the magnetic field induced into the vacuum chamber.

The plate electrode 138 may be installed along the antenna coil 136. The plate electrodes 138 are respectively installed on the inner bottoms of the plurality of linear dielectric tubes 132 so as to be positioned below the antenna coil 136 and are connected to ground. The plate electrode 138 shields electrostatic coupling by the antenna coil 136.

In the large-area inductively coupled plasma reactor 100 of the present invention, a gas supply unit 120 for supplying a process gas along a plurality of linear plasma generating units 130 is configured at an upper portion of the transmission chamber 110. The gas supply unit 120 alternately supplies two or more process gases alternately along the plurality of linear plasma generation units 130.

In detail, the gas supply unit 120 includes first and second gas inlets 122 and 124 and a gas supply separation plate 140. The gas supply separation plate 140 may divide the gas supply unit 120 into the upper space 141 and the lower space 148 to form the first and second gas supply paths 147 and 145. The first gas inlet 122 is connected to the upper space 141, and the second gas inlet 124 is connected to the lower space 148. A gas jet plate 146 is formed between the plurality of linear plasma generating units 130 in contact with the internal space 112 of the vacuum chamber 110. The gas injection plate 146 is provided with a plurality of gas injection holes 144 formed along the plurality of linear plasma generation units 130. Some of the plurality of gas injection holes 144 is the upper space 141 is connected by a plurality of connecting pipes 142, two process gas alternately different between the plurality of linear plasma generating unit 130 Is supplied separately. As such, different process gases may be separately supplied to increase uniformity of the plasma treatment.

In the large-area inductively coupled plasma reactor 100 of the present invention, the bias power supplied to the susceptor 112 may be supplied by one or more bias power supplies. For example, two bias power sources 152 and 154 having different frequencies are supplied to the susceptor 112 through the impedance matcher 158 to further improve plasma ion energy control. The process productivity can be further improved.

Embodiments of the large-area inductively coupled plasma reactor of the present invention described above are merely exemplary, and various modifications and equivalent other embodiments are possible to those skilled in the art to which the present invention pertains. You will know well. Therefore, it is to be understood that the present invention is not limited to the specific forms mentioned in the above description. Therefore, the true technical protection scope of the present invention should be defined by the technical spirit of the appended claims, and the present invention is intended to cover all modifications, equivalents, and substitutes within the spirit and scope of the present invention as defined by the appended claims. It should be understood to include.

According to the large-area inductively coupled plasma reactor of the present invention as described above, a large-area high density plasma can be generated uniformly. In particular, the structural characteristics of the linear plasma generating unit have a structure that is very easy to expand to a large area in accordance with an increase in the size of the substrate which is becoming large, and uniform high density plasma can be generated over a large area. Uniform plasma treatment is possible.

Claims (16)

A vacuum chamber having a susceptor on which the substrate to be processed is placed; A plurality of linear plasma generating units installed across the top of the vacuum chamber, the plurality of linear plasma generating units are: A plurality of linear dielectric tubes arranged in parallel; An antenna coil installed along the plurality of linear dielectric tubes and receiving radio frequency power from a main power supply to transfer induced electromotive force for generation of inductively coupled plasma into the vacuum chamber; And Large area inductively coupled plasma reactors are respectively installed in the plurality of linear dielectric tube, the magnetic coil for strengthening the strength of the magnetic field induced into the vacuum chamber to surround the antenna coil from the upper side. delete The large-area inductively coupled plasma reactor of claim 1, further comprising flat plate electrodes disposed along the antenna coil and installed on the bottom of the plurality of linear dielectric tubes and connected to ground to be positioned below the antenna coil. . The large area inductively coupled plasma reactor of claim 1, wherein the antenna coil is wound at least once in a zigzag fashion along the interior of the plurality of linear dielectric tubes. The large area inductively coupled plasma reactor of claim 1, further comprising a gas supply unit supplying a process gas along the plurality of linear plasma generating units. The large area inductively coupled plasma reactor of claim 5, wherein the gas supply unit separately supplies two or more process gases alternately along the plurality of linear plasma generating units. The large area inductively coupled plasma reactor of claim 1, wherein the susceptor is biased by one or more bias power sources. A vacuum chamber having a susceptor on which the substrate to be processed is placed; A plurality of linear plasma generating units installed across the top of the vacuum chamber, the plurality of linear plasma generating units are: A plurality of linear dielectric tubes arranged in parallel; An antenna coil installed along the plurality of linear dielectric tubes and receiving radio frequency power from a main power supply to transfer induced electromotive force for generation of inductively coupled plasma into the vacuum chamber; And A large area inductively coupled plasma reactor installed along the antenna coil, the flat electrode being respectively installed on the bottom of the plurality of linear dielectric tubes and connected to ground to be positioned below the antenna coil. 9. The large area inductively coupled plasma reactor of claim 8, wherein the antenna coil is wound one or more times zigzag along the interior of the plurality of linear dielectric tubes. The large-area inductively coupled plasma reactor of claim 8, further comprising a gas supply unit supplying a process gas along the plurality of linear plasma generating units. The large area inductively coupled plasma reactor of claim 10, wherein the gas supply unit separately supplies two or more process gases alternately along the plurality of linear plasma generating units. 9. The large area inductively coupled plasma reactor of claim 8, wherein the susceptor is biased by one or more bias power supplies. A vacuum chamber having a susceptor on which the substrate to be processed is placed; A plurality of linear plasma generating units disposed across the upper portion of the vacuum chamber, The plurality of linear plasma generating units comprising: a plurality of linear dielectric tubes arranged in parallel; An antenna coil installed along the plurality of linear dielectric tubes and receiving radio frequency power from a main power supply to transfer induced electromotive force for generation of inductively coupled plasma into the vacuum chamber; Large-area inductively coupled plasma reactor including a gas supply for supplying a process gas along the plurality of linear plasma generating unit. The large-area inductively coupled plasma reactor of claim 13, wherein the antenna coil is wound one or more times zigzag along the interior of the plurality of linear dielectric tubes. The large-area inductively coupled plasma reactor of claim 13, wherein the gas supply unit separately supplies two or more process gases alternately along the plurality of linear plasma generating units. The large area inductively coupled plasma reactor of claim 13, wherein the susceptor is biased by one or more bias power sources.

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