TWI406336B - High-density plasma generator - Google Patents
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- H—ELECTRICITY
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- H01J37/00—Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
- H01J37/32—Gas-filled discharge tubes
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- H01L21/00—Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
- H01L21/67—Apparatus specially adapted for handling semiconductor or electric solid state devices during manufacture or treatment thereof; Apparatus specially adapted for handling wafers during manufacture or treatment of semiconductor or electric solid state devices or components ; Apparatus not specifically provided for elsewhere
- H01L21/67005—Apparatus not specifically provided for elsewhere
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- H01L21/67063—Apparatus for fluid treatment for etching
- H01L21/67069—Apparatus for fluid treatment for etching for drying etching
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- H05H1/00—Generating plasma; Handling plasma
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- H05H1/46—Generating plasma using applied electromagnetic fields, e.g. high frequency or microwave energy
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- H05H1/4652—Radiofrequency discharges using inductive coupling means, e.g. coils
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- H01J2237/00—Discharge tubes exposing object to beam, e.g. for analysis treatment, etching, imaging
- H01J2237/32—Processing objects by plasma generation
- H01J2237/33—Processing objects by plasma generation characterised by the type of processing
- H01J2237/334—Etching
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Abstract
Description
本發明是關於一種電感耦合高密度電漿產生器。更具體地,本發明是關於一種可穩定地蝕刻用以製造高亮度LED晶片的藍寶石晶圓的表面的電感耦合高密度電漿產生器。 The present invention relates to an inductively coupled high density plasma generator. More particularly, the present invention relates to an inductively coupled high density plasma generator that stably etches the surface of a sapphire wafer used to fabricate high brightness LED wafers.
一般來說,電漿產生器分為用於沉積薄膜的PECVD(電漿促進化學氣相沈積法)裝置、藉由蝕刻經沉積薄膜以圖案化經沉積薄膜的蝕刻裝置、濺鍍機、以及灰化裝置。 In general, a plasma generator is classified into a PECVD (plasma-promoted chemical vapor deposition) apparatus for depositing a thin film, an etching apparatus for etching a deposited thin film to pattern a deposited thin film, a sputtering machine, and a ash. Chemical device.
此外,基於射頻功率施加方案的電漿產生器分為CCP(電容耦合電漿)產生器與ICP(感應耦合電漿)產生器。當射頻功率施加於平板電極時,CCP產生器藉由使用垂直地形成於彼此相對且平行的平板電極之間的射頻電場產生電漿,以及ICP產生器藉由使用透過天線引起的感應電場轉換來源材料成電漿而產生電漿。 In addition, plasma generators based on RF power application schemes are classified into CCP (Capacitively Coupled Plasma) generators and ICP (Inductively Coupled Plasma) generators. When RF power is applied to the plate electrode, the CCP generator generates plasma by using an RF electric field that is vertically formed between the opposite and parallel plate electrodes, and the ICP generator converts the source by using an induced electric field caused by the transmission antenna. The material is plasmaized to produce a plasma.
此ICP產生器具有以下的結構。 This ICP generator has the following structure.
ICP產生器包括定義為密閉反應區域的一腔室、設置在該腔室以裝配基板於其上的一基座(susceptor)、用於從基座上端噴灑來源材料的一氣體噴霧平板、以及供給來源材料到氣體噴霧平板的一氣體供給管。 The ICP generator includes a chamber defined as a closed reaction zone, a susceptor disposed thereon to mount the substrate, a gas spray plate for spraying source material from the upper end of the base, and a supply The source material is supplied to a gas supply tube of the gas spray plate.
為了轉換來源材料成為電漿,在腔室蓋上提供一供給射頻功率的射頻天線。此射頻天線是透過饋送電纜連接到射頻功率來源。一匹配器置於射頻天線與射頻功率來源 之間以匹配負載阻抗與來源阻抗。 In order to convert the source material into a plasma, an RF antenna for supplying RF power is provided on the chamber cover. This RF antenna is connected to the RF power source via a feed cable. A matcher is placed in the RF antenna and RF power source Match between load impedance and source impedance.
同時,位在射頻天線下方的腔室蓋是由絕緣材料製成以傳送感應磁場到腔室。此腔室蓋包括減少天線與電漿之間的電容耦合的絕緣材料,所以能量可以透過電感耦合從射頻功率來源傳送到電漿。 At the same time, the chamber cover below the RF antenna is made of an insulating material to transmit an induced magnetic field to the chamber. The chamber cover includes an insulating material that reduces capacitive coupling between the antenna and the plasma so that energy can be transferred from the RF power source to the plasma through inductive coupling.
當射頻功率供給射頻天線時,在垂直方向的時變磁場產生於射頻天線的周圍,以及在水平方向的電場因為該時變磁場而被誘導進入腔室。電子由感應電場加速而與中性氣體碰撞,所以產生離子與自由基以執行基板的蝕刻與沉積製程。此時,為了調整入射到基板的離子能量,除了射頻功率之外偏壓功率亦施加於基座。 When radio frequency power is supplied to the radio frequency antenna, a time-varying magnetic field in the vertical direction is generated around the radio frequency antenna, and an electric field in the horizontal direction is induced into the chamber due to the time-varying magnetic field. The electrons are accelerated by the induced electric field to collide with the neutral gas, so ions and radicals are generated to perform the etching and deposition process of the substrate. At this time, in order to adjust the ion energy incident on the substrate, bias power is applied to the susceptor in addition to the radio frequency power.
除此之外,在基座提供一加熱器或冷卻通道以調整基板的溫度,以及剩餘氣體透過排洩口以真空幫浦排出到外面。 In addition to this, a heater or a cooling passage is provided at the susceptor to adjust the temperature of the substrate, and the remaining gas is discharged to the outside through the discharge port with a vacuum pump.
在下文中,使用具有以上結構的天線系統以產生電漿的製程將被簡要地敘述。當射頻功率施加於天線系統時,電流流經天線系統以致於時變電場產生在天線系統周圍。因此,感應電場藉由時變電場產生在反應室中。電子由感應電場加熱,所以產生與天線電感耦合的電漿。因此,電漿蝕刻裝置可藉由使用當電漿中的電子與中性氣體粒子碰撞所產生的離子或自由基執行電漿蝕刻製程或電漿沉積製程。同時,若射頻功率藉由使用附加射頻功率來源施加於晶圓座(chuck),入射到基板的離子能量可被控制。天線系統的結構將於稍後參考第3圖詳細敘述。 Hereinafter, a process of using an antenna system having the above structure to generate plasma will be briefly described. When RF power is applied to the antenna system, current flows through the antenna system such that a time varying electric field is generated around the antenna system. Therefore, the induced electric field is generated in the reaction chamber by a time-varying electric field. The electrons are heated by the induced electric field, thus producing a plasma that is inductively coupled to the antenna. Therefore, the plasma etching apparatus can perform a plasma etching process or a plasma deposition process by using ions or radicals generated when electrons in the plasma collide with neutral gas particles. At the same time, if RF power is applied to the chuck by using an additional RF power source, the ion energy incident on the substrate can be controlled. The structure of the antenna system will be described later in detail with reference to FIG.
這樣的天線系統被揭露在韓國專利未經審核的申請號2000-0102257(發表於2009年9月),係由本發明的申請人所提交。 Such an antenna system is disclosed in Korean Patent Application No. 2000-0102257 (published in September 2009), filed by the applicant of the present invention.
第12圖是揭露在上述發表中的天線系統之透視圖。 Figure 12 is a perspective view of the antenna system disclosed in the above publication.
如第12圖所示的天線系統150包括四個以多重結構排列的圓形線圈天線。詳細地,天線系統150包括排列在相鄰於反應室的上部部分的第一平面(第1圖的X-Y平面)的第一下部天線151、排列在第一下部天線151內的第一平面上而與第一下部天線151隔開的第二下部天線152、排列在平行於第一平面而由第一平面向上移動的第二平面上(第1圖的X’-Y’平面)的第一上部天線153,以及排列在第一上部天線153內的第二平面上而與第一上部天線153隔開的第二上部天線154。 The antenna system 150 as shown in Fig. 12 includes four circular coil antennas arranged in a multiple structure. In detail, the antenna system 150 includes a first lower antenna 151 arranged in a first plane (XY plane of FIG. 1) adjacent to an upper portion of the reaction chamber, and a first plane arranged in the first lower antenna 151 a second lower antenna 152 spaced apart from the first lower antenna 151, arranged on a second plane parallel to the first plane and moving upward from the first plane (X'-Y' plane of FIG. 1) The first upper antenna 153 and the second upper antenna 154 are arranged on the second plane in the first upper antenna 153 and spaced apart from the first upper antenna 153.
這四個圓形線圈天線151至154對應於絕緣板的邊緣而排列以及平行地連接到一射頻功率來源180。這四個圓形線圈天線151至154分別包括接收射頻功率的功率輸入端子151a至154a以及電性連接到接地外殼160的接地端子151b至151d。 The four circular coil antennas 151 to 154 are arranged corresponding to the edges of the insulating sheets and connected in parallel to a radio frequency power source 180. The four circular coil antennas 151 to 154 respectively include power input terminals 151a to 154a that receive radio frequency power and ground terminals 151b to 151d that are electrically connected to the ground housing 160.
然而,根據具有上述結構的天線系統,功率損耗可能因為圓形線圈與位在反應室外面的接地物件之間的距離而發生,所以電漿密度在載於反應室的基板邊緣可能顯著地降低。 However, according to the antenna system having the above structure, the power loss may occur due to the distance between the circular coil and the grounded object located outside the reaction chamber, so the plasma density may be remarkably lowered at the edge of the substrate carried on the reaction chamber.
除此之外,當用以產生感應電場的線圈的長度因為大尺寸製程設備而增加時,其感應係數也增加,所以電漿效 率減少以及電漿密度是根據介於功率供應零組件與接地功率輸出零組件之間的連接結構不規則地分佈。 In addition, when the length of the coil used to generate the induced electric field increases due to the large-scale process equipment, the inductance is also increased, so the plasma effect The rate reduction and plasma density are irregularly distributed according to the connection structure between the power supply components and the ground power output components.
本發明已解決發生在先前技術中的問題,以及本發明的目的是提供一種高密度電漿產生器,係能夠在蝕刻用以製造高亮度LED晶片的藍寶石晶圓時,藉由使用以感應電場與永久磁鐵的配置為基礎的磁力線產生穩定的高密度電漿以確保穩定性。 The present invention has solved the problems occurring in the prior art, and an object of the present invention is to provide a high-density plasma generator capable of inducing an electric field by using a sapphire wafer for etching a high-brightness LED wafer. The magnetic lines of force based on the configuration of the permanent magnets produce a stable high-density plasma to ensure stability.
本發明的另一目的是提供一種高密度電漿產生器,係能夠藉由限定在一預定區域內透過作為接地的腔室壁而損失的功率以提高線圈的效率。 Another object of the present invention is to provide a high density plasma generator capable of increasing the efficiency of a coil by limiting the power lost through a chamber wall as a ground in a predetermined region.
本發明又另一目的是提供一種高密度電漿產生器,係能夠藉由使用以感應電場與永久磁鐵的配置為基礎的磁力線實現大尺寸製程設備。 Still another object of the present invention is to provide a high-density plasma generator capable of realizing a large-scale process apparatus by using magnetic lines of force based on a configuration of an induced electric field and a permanent magnet.
為了完成以上的目的,提供了一種高密度電漿產生器,係包括具有一產生電漿的空腔的反應室、提供於反應室的上部部分以誘導電場而產生電漿的天線系統、提供於反應室與天線系統之間的電介質絕緣板、以及複數個配置在電介質絕緣板周圍的永久性磁鐵。永久性磁鐵是按順序排列使得相同極性與不同極性是交替地形成在兩個相鄰的永久性磁鐵之間。天線系統包括複數個位在不同於彼此位置的天線零組件。每一天線零組件的天線包括接收射頻功率的功率接收零組件、接地輸出零組件、以及圓形線圈,以及由功率接收零組件與接地輸出零組件所界定的開口。 In order to accomplish the above object, there is provided a high-density plasma generator comprising a reaction chamber having a cavity for generating a plasma, an antenna system provided in an upper portion of the reaction chamber to induce an electric field to generate plasma, and provided in A dielectric insulating plate between the reaction chamber and the antenna system, and a plurality of permanent magnets disposed around the dielectric insulating plate. The permanent magnets are arranged in order such that the same polarity and different polarities are alternately formed between two adjacent permanent magnets. The antenna system includes a plurality of antenna components that are located at positions different from each other. The antenna of each antenna component includes a power receiving component that receives RF power, a ground output component, and a circular coil, and an opening defined by the power receiving component and the grounding output component.
根據本發明,永久性磁鐵分別設置在天線零組件的外部,而以約1毫米至約15毫米的距離分隔彼此。 According to the present invention, the permanent magnets are respectively disposed outside the antenna components, and are separated from each other by a distance of about 1 mm to about 15 mm.
根據本發明,從圓形線圈的水平面至功率接收零組件與接地輸出零組件的垂直距離為約100毫米至約300毫米,以及功率接收零組件是以約15毫米至約25毫米的距離與接地輸出零組件分隔以形成開口。 According to the present invention, the vertical distance from the horizontal plane of the circular coil to the power receiving component to the grounding output component is from about 100 mm to about 300 mm, and the power receiving component is at a distance of about 15 mm to about 25 mm and grounded The output components are separated to form an opening.
根據本發明,天線零組件包括對齊鄰近反應室的上部部分的第一平面的第一下部天線,以及對齊第一下部天線內的第一平面的第二下部天線。 In accordance with the present invention, an antenna assembly includes a first lower antenna aligned with a first plane adjacent an upper portion of the reaction chamber, and a second lower antenna aligned with a first plane within the first lower antenna.
根據本發明,天線零組件包括對齊平行於第一平面且自第一平面向上移動的第二平面的第一上部天線,以及對齊第一上部天線內的第二平面的第二上部天線。 In accordance with the present invention, an antenna assembly includes a first upper antenna aligned parallel to a first plane and moving upwardly from a first plane, and a second upper antenna aligned with a second plane within the first upper antenna.
根據本發明,天線零組件包括對齊平行於第二平面且自第二平面向上移動的第三平面的第三上部天線,以及對齊第三上部天線內的第三平面的第四上部天線。 In accordance with the present invention, an antenna assembly includes a third upper antenna aligned in a third plane parallel to the second plane and moving upward from the second plane, and a fourth upper antenna aligned in a third plane within the third upper antenna.
根據本發明,天線零組件進一步包括對齊第二下部天線內的第一平面的第三下部天線。 In accordance with the present invention, the antenna assembly further includes a third lower antenna aligned with a first plane within the second lower antenna.
根據本發明,天線零組件包括對齊平行於第一平面且自第一平面向上移動的第二平面的第一上部天線、對齊第一上部天線內的第二平面的第二上部天線,以及對齊第二上部天線內的第二平面的第三上部天線。 According to the present invention, an antenna component includes a first upper antenna aligned with a second plane parallel to the first plane and moving upward from the first plane, a second upper antenna aligned with a second plane within the first upper antenna, and an alignment a third upper antenna of the second plane within the upper antenna.
根據本發明,天線零組件包括對齊平行於第二平面且自第二平面向上移動的第三平面的第四上部天線、對齊第 四上部天線內的第三平面的第五上部天線,以及對齊第五上部天線內的第三平面的第六上部天線。 According to the invention, the antenna assembly includes a fourth upper antenna aligned with a third plane that is parallel to the second plane and moves upward from the second plane, alignment a fifth upper antenna of a third plane within the four upper antennas and a sixth upper antenna aligned with a third plane within the fifth upper antenna.
根據本發明,第一下部天線的開口與第二下部天線的開口是以180°的間隔排列在圓形線圈的同心圓上。 According to the invention, the opening of the first lower antenna and the opening of the second lower antenna are arranged at 180° intervals on the concentric circles of the circular coil.
根據本發明,第一下部天線的開口、第二下部天線的開口、第一上部天線的開口以及第二上部天線的開口是以90°的間隔排列在圓形線圈的同心圓上。 According to the invention, the opening of the first lower antenna, the opening of the second lower antenna, the opening of the first upper antenna, and the opening of the second upper antenna are arranged at 90° intervals on the concentric circles of the circular coil.
根據本發明,第一下部天線的開口、第二下部天線的開口、第一上部天線的開口、第二上部天線的開口、第三上部天線的開口以及第四上部天線的開口是以60°的間隔排列在圓形線圈的同心圓上。 According to the present invention, the opening of the first lower antenna, the opening of the second lower antenna, the opening of the first upper antenna, the opening of the second upper antenna, the opening of the third upper antenna, and the opening of the fourth upper antenna are 60° The spacing is arranged on the concentric circles of the circular coil.
根據本發明,第一下部天線的開口、第二下部天下的開口以及第三下部天線的開口是以120°的間隔排列在圓形線圈的同心圓上。 According to the present invention, the opening of the first lower antenna, the opening of the second lower portion, and the opening of the third lower antenna are arranged at 120° intervals on the concentric circles of the circular coil.
根據本發明,第一下部天線的開口、第二下部天線的開口、第三下部天線的開口、第一上部天線的開口、第二上部天線的開口以及第三上部天線的開口是以60°的間隔排列在圓形線圈的同心圓上。 According to the present invention, the opening of the first lower antenna, the opening of the second lower antenna, the opening of the third lower antenna, the opening of the first upper antenna, the opening of the second upper antenna, and the opening of the third upper antenna are 60° The spacing is arranged on the concentric circles of the circular coil.
根據本發明,第一下部天線的開口、第二下部天線的開口、第三下部天線的開口、第一上部天線的開口、第二上部天線的開口、第三上部天線的開口、第四上部天線的開口、第五上部天線的開口以及第六上部天線的開口是以40°的間隔排列在圓形線圈的同心圓上。 According to the present invention, the opening of the first lower antenna, the opening of the second lower antenna, the opening of the third lower antenna, the opening of the first upper antenna, the opening of the second upper antenna, the opening of the third upper antenna, and the fourth upper portion The opening of the antenna, the opening of the fifth upper antenna, and the opening of the sixth upper antenna are arranged at 40° intervals on the concentric circles of the circular coil.
根據本發明,介於第一與第二平面的垂直距離是約5毫米至約20毫米。 According to the invention, the vertical distance between the first and second planes is from about 5 mm to about 20 mm.
根據本發明,介於第二與第三平面的垂直距離是約5毫米至約20毫米。 According to the invention, the vertical distance between the second and third planes is from about 5 mm to about 20 mm.
根據本發明,圓形線圈具有約2毫米至約7毫米的直徑及其是由銅所製成,以及圓形線圈的表面是鍍銀、金或鉑。 According to the invention, the circular coil has a diameter of from about 2 mm to about 7 mm and is made of copper, and the surface of the circular coil is silver plated, gold or platinum.
根據本發明,第一與第二上部天線分別位在對應於第一與第二下部天線的水平面上。 According to the invention, the first and second upper antennas are respectively located on horizontal planes corresponding to the first and second lower antennas.
根據本發明,第三與第四上部天線以及第一與第二上部天線分別位在對應於第一與第二下部天線的水平面上。 According to the present invention, the third and fourth upper antennas and the first and second upper antennas are respectively located on horizontal planes corresponding to the first and second lower antennas.
根據本發明,第一至第三上部天線分別位在對應於第一至第三下部天線的水平面上。 According to the present invention, the first to third upper antennas are respectively located on horizontal planes corresponding to the first to third lower antennas.
根據本發明,第四至第六上部天線以及第一至第三上部天線分別位在對應於第一至第三下部天線的水平面上。 According to the present invention, the fourth to sixth upper antennas and the first to third upper antennas are respectively located on horizontal planes corresponding to the first to third lower antennas.
如上所述,根據本發明的高密度電漿產生器,當透鏡圖案透過電漿蝕刻製程在藍寶石晶圓上形成以製造LED時,均勻的蝕刻效果可以因為穩定的電漿而獲得。 As described above, according to the high-density plasma generator of the present invention, when the lens pattern is formed on a sapphire wafer through a plasma etching process to manufacture an LED, a uniform etching effect can be obtained due to stable plasma.
除此之外,根據本發明,通過腔室壁損失的電漿通量可以藉由推動電漿通量朝向載於反應室的基板而被限定在預定區域內,所以電漿密度可以均勻地分佈在基板的整個面積。 In addition, according to the present invention, the plasma flux lost through the chamber wall can be defined in a predetermined region by pushing the plasma flux toward the substrate carried in the reaction chamber, so that the plasma density can be uniformly distributed. The entire area of the substrate.
進一步地,根據本發明,透過作為接地的腔室壁損失的 功率可因為永久磁鐵的配置而被限定在預定區域內,所以線圈的效率可以被提高。因此,製程設備可透過自動分割而以大尺寸製造,所以產量可以被提高。 Further, according to the present invention, loss through the wall of the chamber as a ground The power can be limited to a predetermined area due to the configuration of the permanent magnet, so the efficiency of the coil can be improved. Therefore, the process equipment can be manufactured in a large size by automatic division, so the yield can be improved.
除此之外,根據本發明,線圈是由具有約2毫米至約7毫米直徑的圓形銅所製成,以及銀、金或鉑是鍍在線圈的表面上,所以功率傳送效率可以被提高以及電漿效率可藉由冷卻由天線產生的熱而增加。 In addition to this, according to the present invention, the coil is made of round copper having a diameter of about 2 mm to about 7 mm, and silver, gold or platinum is plated on the surface of the coil, so power transmission efficiency can be improved. And the plasma efficiency can be increased by cooling the heat generated by the antenna.
在下文中,本發明的例示性實施例將參照附圖描述。 Hereinafter, exemplary embodiments of the present invention will be described with reference to the drawings.
首先,本發明的概念將被描述。 First, the concept of the present invention will be described.
根據本發明,天線系統包括複數個平行於彼此對齊的圓形線圈,其中每一圓形線圈附帶一功率供應零組件與一接地輸出零組件(接地零組件)以及由一功率接地零組件與一接地輸出零組件界定的開口。為了彌補具有開口的圓形天線的電漿均勻性,此圓形天線包括內部圓形線圈與外部圓形線圈,使得內部與外部線圈的開口是以180°的角度彼此對稱。因此,經電漿放電的電漿不會偏頗於一個方向。 In accordance with the present invention, an antenna system includes a plurality of circular coils aligned parallel to each other, wherein each circular coil is provided with a power supply component and a ground output component (ground component) and a power ground component and a The ground defines the opening defined by the component. In order to compensate for the plasma uniformity of the circular antenna having an opening, the circular antenna includes an inner circular coil and an outer circular coil such that the openings of the inner and outer coils are symmetrical to each other at an angle of 180°. Therefore, the plasma discharged by the plasma is not biased in one direction.
本發明中使用的天線系統的天線零組件包括具有開口的內部圓形線圈與具有開口的外部圓形線圈。此天線零組件具有迴路型天線結構,其電流以相同的方向流動。產生感應電場的單一線圈是附帶一功率接收零組件與一接地零組件而在其之間形成一開口,所以在這局部區域的電漿的不均勻性可能增加。在多層結構的情況下,排列 具有開口的一對線圈使得這些開口以90°的角度彼此分隔,以彌補具有功率接收零組件與接地輸出零組件的圓形天線的功率調變,因而確保穩定的電漿均勻性。 The antenna assembly of the antenna system used in the present invention includes an inner circular coil having an opening and an outer circular coil having an opening. This antenna component has a loop-type antenna structure in which current flows in the same direction. A single coil that generates an induced electric field is provided with a power receiving component and a grounding component to form an opening therebetween, so that plasma unevenness in this partial region may increase. In the case of a multi-layer structure, arranged A pair of coils having openings separates the openings from each other at an angle of 90 to compensate for the power modulation of the circular antenna with power receiving components and ground output components, thus ensuring stable plasma uniformity.
為了彌補發生在介於功率接收零組件與接地輸出零組件之間的局部區域的電漿的不均勻性,參考線圈的兩端是垂直向上彎曲的。若多層是透過上述的方式形成,發生在介於產生感應電場的線圈的功率接收零組件與線圈的接地輸出零組件之間的局部區域的電漿的不均勻性可被防止。也就是說,在結構方面,當從載於腔室中的基板的角度來看,此線圈被看作是在平的電介質絕緣版上提供兩個線圈,因此防止來自於複數個感應線圈的感應係數所導致的電漿放電效率的下降。 To compensate for the non-uniformity of the plasma that occurs in a localized region between the power receiving component and the grounded output component, both ends of the reference coil are vertically upwardly curved. If a plurality of layers are formed by the above-described manner, plasma non-uniformity occurring in a local region between the power receiving component of the coil generating the induced electric field and the ground output component of the coil can be prevented. That is to say, in terms of structure, when viewed from the perspective of the substrate carried in the chamber, the coil is considered to provide two coils on a flat dielectric insulating plate, thereby preventing induction from a plurality of induction coils. The decrease in plasma discharge efficiency caused by the coefficient.
以這種方式,其電流以相同方向流動的迴路型天線可以製作成三層結構或四層結構。此三層線圈以60°的角度彼此旋轉而排列,因此彌補在具有開口的圓形天線的區域的功率調變而確保穩定的電漿均勻性。 In this way, the loop type antenna whose current flows in the same direction can be made into a three-layer structure or a four-layer structure. The three-layer coils are arranged to rotate at an angle of 60°, thereby compensating for power modulation in a region of the circular antenna having an opening to ensure stable plasma uniformity.
電漿密度的不均勻性可能因為排出電流的功率接收零組件與接地輸出零組件而局部地發生在具有開口的圓形天線的區域。為了解決上述問題,開口形成在具有雙層結構或三層結構的天線中,使得開口以60°或90°的角度彼此旋轉而分隔設置,因此減少在局部區域的電漿密度的不均勻性。 The non-uniformity of the plasma density may locally occur in the area of the circular antenna with the opening due to the power receiving component of the discharge current and the ground output component. In order to solve the above problem, the openings are formed in an antenna having a two-layer structure or a three-layer structure such that the openings are spaced apart from each other by an angle of 60 or 90, thereby reducing the unevenness of the plasma density in the partial regions.
若包括內部線圈與外部線圈及射頻功率的天線零組件應用於圓形線圈,由施加於線圈的感應磁場所導致的電漿 密度可依據以載於反應室的基板為基礎的內部線圈的直徑而改變,以及外部線圈可彌補電漿均勻性。因為介於圓型線圈與外部接地物件之間的距離導致的功率損耗,電漿密度在載於反應室的基板邊緣可能顯著地降低。為了解決這問題,永久性磁鐵被排列以推動電漿通量朝向載於反應室的基板,以這種方式透過腔室壁損失的電漿通量可被限定在預定區域內。因此,電漿密度可均勻地分佈在基板的整個面積。 If an antenna component including an internal coil and an external coil and RF power is applied to a circular coil, the plasma is caused by an induced magnetic field applied to the coil. The density can vary depending on the diameter of the inner coil based on the substrate carried in the reaction chamber, and the outer coil can compensate for plasma uniformity. Because of the power loss caused by the distance between the circular coil and the external grounded object, the plasma density may be significantly reduced at the edge of the substrate carried in the reaction chamber. To solve this problem, the permanent magnets are arranged to push the plasma flux toward the substrate carried in the reaction chamber, and the plasma flux lost through the chamber wall in this manner can be limited to a predetermined area. Therefore, the plasma density can be uniformly distributed over the entire area of the substrate.
一個功率接收零組件可分成複數個彼此平行連接的功率接收零組件,係為了藉由使用複數個分開的電介質絕緣板同時地蝕刻在一電漿真空室中的複數個基板。當用以產生感應電場的線圈的長度因為大尺寸製程設備而增加時,其感應係數也增加,所以電漿效率減少。為了解決這個問題,永久性磁鐵被排列使得線圈承受該磁場,以及透過作為接地的腔室壁損耗的功率被限定在預定區域內,所以線圈效率可以被提高以及製程設備可透過自動分割而以大尺寸製造。 A power receiving component can be divided into a plurality of power receiving components connected in parallel with one another in order to simultaneously etch a plurality of substrates in a plasma vacuum chamber by using a plurality of separate dielectric insulating plates. When the length of the coil for generating the induced electric field is increased due to the large-sized process equipment, the inductance is also increased, so the plasma efficiency is reduced. In order to solve this problem, the permanent magnets are arranged such that the coil is subjected to the magnetic field, and the power loss through the wall of the chamber as the ground is limited to a predetermined area, so that the coil efficiency can be improved and the process apparatus can be enlarged by automatic division. Size manufacturing.
根據相關技術,其中該線圈包括螺旋形線圈與雙圓形線圈以產生感應電場,一種以螺旋管線圈形式製作的電磁線圈被提供在腔室的外面以彌補在基板邊緣的低電漿密度,所以設備的結構是複雜的以及功率控制是困難的。至於包括複數個分開而平形於彼此的螺旋形線圈之螺旋形天線,即使該螺旋形線圈具有相同的電流方向,在螺旋形線圈周圍形成的磁場可因為螺旋形線圈而彼此加強或抵消,所以在載於反應室的基板的邊緣的電漿密度可 能降低。為此,像是螺旋管線圈的電磁線圈必須被提供以提高電漿密度分佈的均勻性。 According to the related art, wherein the coil includes a spiral coil and a double circular coil to generate an induced electric field, an electromagnetic coil fabricated in the form of a spiral coil is provided outside the chamber to compensate for a low plasma density at the edge of the substrate, The structure of the device is complex and power control is difficult. As for a helical antenna including a plurality of spiral coils that are separated and flattened to each other, even if the spiral coils have the same current direction, the magnetic fields formed around the spiral coils can be reinforced or canceled by each other due to the spiral coils, so The plasma density of the edge of the substrate carried in the reaction chamber can be Can be reduced. To this end, an electromagnetic coil such as a spiral coil must be provided to increase the uniformity of the plasma density distribution.
本發明已解決上述發生在相關技術中的天線的問題。根據本發明,功率接收零組件與接地輸出零組件被排列成相對於載於反應室的基板而面對彼此。除此之外,功率接收零組件可根據製程條件分成複數個平行於彼此配置的功率接收零組件,該線圈可以這種方式產生平行於彼此的感應電場,因此產生電漿。此時,自一圓形線圈的功率接收零組件與接地輸出零組件到最接近該圓形線圈的另一圓形線圈的水平面的垂直距離至少是100毫米至300毫米。在這種情況下,由功率接收零組件與接地輸出零組件的架構而導致的電漿密度分佈的不均勻性可以解決。 The present invention has solved the above-described problems of the antennas occurring in the related art. In accordance with the present invention, the power receiving components and grounding output components are arranged to face each other with respect to the substrate carried in the reaction chamber. In addition to this, the power receiving component can be divided into a plurality of power receiving components arranged in parallel with each other according to process conditions, and the coil can generate induced electric fields parallel to each other in this way, thus generating plasma. At this time, the vertical distance from the power receiving component of a circular coil to the horizontal plane of the other circular coil closest to the circular coil is at least 100 mm to 300 mm. In this case, the unevenness of the plasma density distribution caused by the architecture of the power receiving component and the grounding output component can be solved.
此線圈可以藉由使用具有約2毫米至約7毫米直徑的圓形銅製造。為了提高功率傳送效率,此線圈是鍍銀、金或鉑。此線圈具有冷卻從其產生的熱的功能。 This coil can be fabricated by using round copper having a diameter of from about 2 mm to about 7 mm. To improve power transfer efficiency, the coil is silver plated, gold or platinum. This coil has a function of cooling the heat generated therefrom.
一單層線圈包括內部圓形線圈與外部圓形線圈。當基板已處理時,內部圓形線圈與外部圓形線圈的直徑可依據由載於反應室的基板所導致的均勻性來決定。除此之外,為了根據電漿分佈彌補在基板的邊緣的不均勻性,永久性磁鐵的配置可被調整。 A single layer coil includes an inner circular coil and an outer circular coil. When the substrate has been processed, the diameter of the inner circular coil and the outer circular coil can be determined according to the uniformity caused by the substrate carried in the reaction chamber. In addition to this, in order to compensate for the unevenness at the edge of the substrate according to the plasma distribution, the configuration of the permanent magnet can be adjusted.
當縮短製程時間時,為了提高電漿密度,線圈可具有多層結構。若線圈具有多層結構,其電漿分佈的均勻性相較於具有單層結構的線圈可以被提高。具有多層結構的 線圈除了在縱向以5毫米至20毫米分隔彼此之外,其與具有單層結構的線圈相似地排列。此時,為了減少由圓形線圈的直徑所造成的電容組件的影響,兩線圈相對於基板是垂直地隔開或有角度地排列的,因此提高電漿密度分佈的均勻性而實現加強效果。 When the process time is shortened, the coil may have a multilayer structure in order to increase the plasma density. If the coil has a multilayer structure, the uniformity of plasma distribution can be improved compared to a coil having a single layer structure. Multilayer structure The coils are arranged similarly to the coils having a single layer structure except that they are separated from each other by 5 mm to 20 mm in the longitudinal direction. At this time, in order to reduce the influence of the capacitance component caused by the diameter of the circular coil, the two coils are vertically spaced or angularly arranged with respect to the substrate, thereby improving the uniformity of the plasma density distribution to achieve the reinforcing effect.
為了減少來自於複數個具有多層結構的線圈的電容組件的影響所導致的電位差,線圈的直徑可能隨一參考線圈變化。在這種情況下,該電容組件的影響可以最小化。 In order to reduce the potential difference caused by the influence of a plurality of capacitor components having a plurality of layers of coils, the diameter of the coil may vary with a reference coil. In this case, the effect of the capacitive component can be minimized.
根據相關技術,至少一可變電容器被提供在包括圓形線圈與螺旋形線圈的線圈之間以調整電流,因此形成複數個迴路型天線。 According to the related art, at least one variable capacitor is provided between the coil including the circular coil and the spiral coil to adjust the current, thus forming a plurality of loop type antennas.
然而,根據本發明,永久性磁鐵是不同地排列以獲得具有不同形狀與強度的磁力線。此些永久性磁鐵是圓形地排列而與圓形天線線圈隔開,其中介於兩相鄰永久磁鐵之間的距離是1毫米至15毫米,磁極可以這種方式交替地形成。除此之外,永久性磁鐵是圓形地排列使得該磁場在以一預定距離與載於反應室的基板的邊緣隔開的區域可具有最小的高斯值。若在電漿密度是由感應電場產生之下執行該製程,磁力可能不會在這個製程產生影響。詳細地,因為來自磁力線的製程參數可在製程期間被移除,透過腔室壁損耗的功率可被限定在製程區域內,所以電漿密度的均勻性可被提高。也就是說,電漿密度的均勻性可因為線圈的架構以及磁極的配置而被提高。 However, according to the present invention, the permanent magnets are arranged differently to obtain magnetic lines of force having different shapes and strengths. The permanent magnets are circularly arranged to be spaced apart from the circular antenna coil, wherein the distance between two adjacent permanent magnets is from 1 mm to 15 mm, and the magnetic poles may be alternately formed in this manner. In addition to this, the permanent magnets are arranged circularly such that the magnetic field can have a minimum Gauss value at a predetermined distance from the edge of the substrate carried by the reaction chamber. If the process is performed while the plasma density is generated by the induced electric field, the magnetic force may not affect the process. In detail, since the process parameters from the magnetic lines of force can be removed during the process, the power lost through the chamber walls can be limited to the process area, so the uniformity of the plasma density can be improved. That is to say, the uniformity of the plasma density can be improved due to the structure of the coil and the configuration of the magnetic poles.
在上述條件之下產生的電漿可在低於傳統電漿製程壓力 的壓力下穩定地放電。若本發明被應用在蝕刻用於製造LED的藍寶石晶圓表面的製程,均勻的電漿密度分佈可在幾mT至幾百mT的製程壓力下獲得,所以本發明蝕刻用於製造LED的藍寶石晶圓是非常有效的。 The plasma produced under the above conditions can be lower than the conventional plasma process pressure Stable discharge under pressure. If the present invention is applied to a process for etching the surface of a sapphire wafer for manufacturing an LED, a uniform plasma density distribution can be obtained under a process pressure of several mT to several hundred mT, so the etched crystal of the sapphire used in the manufacture of the LED of the present invention is etched. The circle is very effective.
在下文中,本發明的第一實施例將參照附圖被詳細地描述。 Hereinafter, a first embodiment of the present invention will be described in detail with reference to the accompanying drawings.
本發明提供一種ICP(感應耦合電漿)產生器以蝕刻用於製造高亮度LED晶片的晶圓表面。 The present invention provides an ICP (Inductively Coupled Plasma) generator for etching wafer surfaces used to fabricate high brightness LED wafers.
第1圖係為顯示根據本發明的第一實施例之一高密度電漿產生器的結構之透視圖,第2圖係為顯示如第1圖中所示之天線系統150與永久性磁鐵190間的配置關係之平面圖,以及第3圖係為顯示根據本發明之以永久性磁鐵的配置為基礎的有效磁力分佈之平面圖。 1 is a perspective view showing the structure of a high-density plasma generator according to a first embodiment of the present invention, and FIG. 2 is a view showing an antenna system 150 and a permanent magnet 190 as shown in FIG. A plan view of the interposed configuration relationship, and Fig. 3 is a plan view showing the effective magnetic force distribution based on the configuration of the permanent magnet according to the present invention.
參考第1圖,根據本發明的高密度電漿產生器100包括具有一產生電漿的空腔的反應室110、裝有複數個承受電漿蝕刻製程的基板的基板盤120、提供在反應室110的下部內側部分以支撐基板盤120的晶圓座130、提供在反應室的上部部分以誘導產生電漿的電場的天線系統150、介於反應室110與天線系統150之間的電介質絕緣板140、提供在天線系統150的上部部分的接地外殼160、用以供應射頻功率予天線系統150的射頻功率來源170、用以匹配射頻功率來源170的內部阻抗與射頻供應路徑的阻抗的阻抗匹配器180、以及複數個排列在電介質絕緣板140周圍 的永久性磁鐵190。 Referring to Fig. 1, a high-density plasma generator 100 according to the present invention includes a reaction chamber 110 having a cavity for generating plasma, and a substrate tray 120 containing a plurality of substrates subjected to a plasma etching process, provided in the reaction chamber. The lower inner portion of 110 is a wafer holder 130 supporting the substrate tray 120, an antenna system 150 providing an electric field at the upper portion of the reaction chamber to induce plasma generation, and a dielectric insulating plate interposed between the reaction chamber 110 and the antenna system 150. 140. A grounded housing 160 provided at an upper portion of the antenna system 150, an RF power source 170 for supplying RF power to the antenna system 150, and an impedance matching device for matching the internal impedance of the RF power source 170 with the impedance of the RF supply path. 180, and a plurality of arranged around the dielectric insulating plate 140 Permanent magnet 190.
反應室110具有一圓柱形及其是由產生用以蝕刻基板的電漿的空腔所組成。此反應室110是提供在一側壁,其具有供給製程氣體進入反應室110的氣體進料口114以及引導基板盤120進入反應室110的空腔112的凹槽111。 The reaction chamber 110 has a cylindrical shape and is composed of a cavity that generates plasma for etching the substrate. The reaction chamber 110 is provided on a side wall having a gas feed port 114 for supplying process gas into the reaction chamber 110 and a recess 111 for guiding the substrate tray 120 into the cavity 112 of the reaction chamber 110.
晶圓座110是提供在反應室110的空腔112的下部部分以支撐基板盤120。晶圓座130可提供偏壓射頻功率以允許在反應室110中產生的電漿與基板的表面碰撞。在這種情況下,晶圓座130是電性連接到不同於供應射頻功率予天線系統150的射頻功率來源170的附加射頻功率來源,以作為一射頻電極。 The wafer holder 110 is provided at a lower portion of the cavity 112 of the reaction chamber 110 to support the substrate tray 120. Wafer mount 130 can provide biased RF power to allow plasma generated in reaction chamber 110 to collide with the surface of the substrate. In this case, the wafer holder 130 is electrically coupled to an additional source of RF power that is different from the RF power source 170 that supplies the RF power to the antenna system 150 as an RF electrode.
天線系統150具有線圈結構以及自射頻功率來源170接收射頻功率以在反應室110中誘導磁場以在反應室110中產生電漿。第1圖係為顯示以線圈形式提供在天線系統150的天線配置。 The antenna system 150 has a coil structure and receives radio frequency power from the RF power source 170 to induce a magnetic field in the reaction chamber 110 to generate plasma in the reaction chamber 110. The first figure shows the antenna configuration provided in the antenna system 150 in the form of a coil.
在下文中,藉由使用天線系統150以產生電漿的製程將被簡要地描述。當射頻功率施加於天線系統150時,電流流經天線系統150以致於時變磁場在天線系統150的周圍產生。此時變磁場在反應室110形成感應電場以及電極是藉由感應電場加熱,因此產生與天線感應耦合的電漿。電漿產生器100可藉由使用當電漿中的電子與中性氣體粒子碰撞所產生離子或自由基執行電漿蝕刻製程或電漿沉積製程。同時,若從附加射頻功率來源施加射頻功率於晶圓座130,入射到基板的離子能量可被控制。天線系統 150的詳細結構將於稍後詳細地描述。 Hereinafter, a process for generating a plasma by using the antenna system 150 will be briefly described. When radio frequency power is applied to the antenna system 150, current flows through the antenna system 150 such that a time varying magnetic field is generated around the antenna system 150. At this time, the variable magnetic field forms an induced electric field in the reaction chamber 110 and the electrode is heated by the induced electric field, thereby generating a plasma inductively coupled to the antenna. The plasma generator 100 can perform a plasma etching process or a plasma deposition process by using ions or radicals generated when electrons in the plasma collide with neutral gas particles. At the same time, if RF power is applied to the wafer holder 130 from an additional RF power source, the ion energy incident on the substrate can be controlled. Antenna system The detailed structure of 150 will be described in detail later.
同時,如上所述,感應電場藉由自射頻功率來源170提供的射頻功率在天線系統的周圍形成,以及正電荷與負電荷是以高頻率在天線系統150的表面上交替地充電,所以產生電容式電場。然而,雖然電容式電場可促進ICP產生器中的初始電漿放電,此電容式電場可能因為濺鍍現象而破壞配置在電漿與天線系統150之間的電介質物質,使得電漿均勻性可能會下降。 Meanwhile, as described above, the induced electric field is formed around the antenna system by the radio frequency power supplied from the RF power source 170, and the positive and negative charges are alternately charged on the surface of the antenna system 150 at a high frequency, so that a capacitance is generated. Electric field. However, although the capacitive electric field can promote the initial plasma discharge in the ICP generator, this capacitive electric field may destroy the dielectric material disposed between the plasma and the antenna system 150 due to sputtering, such that plasma uniformity may occur. decline.
電介質絕緣板140是提供以防止電容式電場的不良影響。此電介質絕緣板140是配置在反應室110與天線系統150之間以減少電容式電場以及有效地傳送感應電場到電漿。詳細地,電介質絕緣板140減少在天線系統150與電漿之間的電容耦合,所以射頻功率來源170的能量可透過感應耦合有效地傳送到電漿。電介質絕緣板140具有一圓盤形及其是由陶瓷製成。因此,此電介質絕緣板140稱作“法拉第屏蔽”或“陶瓷窗”。電介質絕緣板140是由接地外殼160的下部凸緣162所支撐以及由固定基架163所固定。 The dielectric insulating plate 140 is provided to prevent adverse effects of the capacitive electric field. The dielectric insulating plate 140 is disposed between the reaction chamber 110 and the antenna system 150 to reduce the capacitive electric field and efficiently transmit the induced electric field to the plasma. In detail, the dielectric insulating plate 140 reduces the capacitive coupling between the antenna system 150 and the plasma so that the energy of the RF power source 170 can be efficiently transferred to the plasma through inductive coupling. The dielectric insulating plate 140 has a disk shape and is made of ceramic. Therefore, this dielectric insulating plate 140 is referred to as a "Faraday shield" or a "ceramic window." The dielectric insulating plate 140 is supported by the lower flange 162 of the grounded housing 160 and fixed by the fixed base 163.
接地外殼160為一圓柱形金屬外殼以及提供在天線系統150的上部部分以防止天線系統150暴露到外界。此接地外殼160提供與天線系統150的天線零組件的接地端子電性連接的一接地區域。 The grounded housing 160 is a cylindrical metal housing and is provided in an upper portion of the antenna system 150 to prevent the antenna system 150 from being exposed to the outside. This grounded housing 160 provides a grounded area that is electrically coupled to the ground terminal of the antenna assembly of the antenna system 150.
雖然沒有顯示在第1圖中,電漿產生器100進一步包括使反應室100處在真空狀態的真空幫浦,及形成於反應室 110以排出經由電漿反應產生在反應室110中的氣體的氣體排洩口。 Although not shown in Fig. 1, the plasma generator 100 further includes a vacuum pump that causes the reaction chamber 100 to be in a vacuum state, and is formed in the reaction chamber. 110 is to discharge a gas discharge port of a gas generated in the reaction chamber 110 via a plasma reaction.
在下文中,提供在天線系統150的天線零組件與永久性磁鐵的配置將參考第1圖至第3圖而描述。 In the following, the configuration of the antenna components and permanent magnets provided in the antenna system 150 will be described with reference to Figs. 1 to 3.
根據第一實施例,天線系統150包括具有一對單層線圈的天線零組件。如第1圖與第2圖所示,根據第一實施例的天線零組件10包括對齊鄰近於反應室110的上部部分的第一平面的第一下部天線11,以及設置在第一平面上的第一下部天線11內的第二下部天線12。每一天線包括連接到射頻功率來源170以接收射頻功率的功率接收零組件18、連接到接地外殼160的接地輸出零組件19、以及圓形線圈,其中開口17是界定在功率接收零組件18與接地輸出零組件19之間。 According to a first embodiment, antenna system 150 includes an antenna component having a pair of single layer coils. As shown in FIGS. 1 and 2, the antenna component 10 according to the first embodiment includes a first lower antenna 11 aligned with a first plane adjacent to an upper portion of the reaction chamber 110, and is disposed on a first plane. The second lower antenna 12 in the first lower antenna 11 is. Each antenna includes a power receiving component 18 coupled to a radio frequency power source 170 for receiving radio frequency power, a ground output component 19 coupled to the grounded housing 160, and a circular coil, wherein the opening 17 is defined in the power receiving component 18 and Ground output between components 19.
詳細地,根據第一實施例的天線零組件10包括一對圓形天線,其中每一天線包括一功率接收零組件18與一接地輸出零組件19。為了提高具有開口17的圓形天線的電漿均勻性,圓形天線是附帶一內部圓形線圈與一外部圓形線圈,以及內部圓形線圈的開口是以180°角度對稱於外部圓形線圈的開口,以這種方式經電漿放電的電漿可能不會偏於一個方向。具有開口的第一下部天線11與具有開口的第二下部天線12可構成迴路型天線,其中電流以相同方向流動。產生感應電場的單一線圈可包括功率接收零組件18與接地輸出零組件19,以這種方式該開口17形成於功率接收零組件18與接地輸出零組件19之間。因此,在這局部區域的電漿的不均勻性可能增加。為了解 決此問題,如第2圖所示,天線零組件包括二開口零組件。詳細地,第一下部天線11的開口是排列在第二下部天線12的開口旋轉180°角度的位置。 In detail, the antenna component 10 according to the first embodiment includes a pair of circular antennas, wherein each antenna includes a power receiving component 18 and a grounding output component 19. In order to improve the plasma uniformity of the circular antenna having the opening 17, the circular antenna is provided with an inner circular coil and an outer circular coil, and the opening of the inner circular coil is symmetrical to the outer circular coil at an angle of 180°. The opening, the plasma discharged through the plasma in this way may not be biased in one direction. The first lower antenna 11 having an opening and the second lower antenna 12 having an opening may constitute a loop type antenna in which current flows in the same direction. A single coil that produces an induced electric field can include a power receiving component 18 and a ground output component 19 in such a manner that the opening 17 is formed between the power receiving component 18 and the grounding output component 19. Therefore, the unevenness of the plasma in this partial region may increase. For understanding To solve this problem, as shown in Figure 2, the antenna assembly includes two open components. In detail, the openings of the first lower antenna 11 are arranged at positions where the opening of the second lower antenna 12 is rotated by an angle of 180°.
除此之外,自第一下部天線11的圓形線圈的水平面至功率接收零組件18與接地輸出零組件19的垂直距離l為約100毫米至約300毫米,以及功率接收零組件18是以約15毫米至約25毫米的距離相對於接地輸出零組件19以形成開口17。若介於功率接收零組件18與接地輸出零組件19之間的距離是在10毫米以內,電漿密度是偏於一個方向。相反地,若介於功率接收零組件18與接地輸出零組件19之間的距離超過30毫米,電漿密度是對稱地彎曲。 In addition, the vertical distance l from the horizontal plane of the circular coil of the first lower antenna 11 to the power receiving component 18 and the ground output component 19 is from about 100 mm to about 300 mm, and the power receiving component 18 is The opening 19 is formed relative to the ground output member 19 at a distance of from about 15 mm to about 25 mm. If the distance between the power receiving component 18 and the ground output component 19 is within 10 millimeters, the plasma density is biased in one direction. Conversely, if the distance between the power receiving component 18 and the ground output component 19 exceeds 30 millimeters, the plasma density is symmetrically curved.
因此,當射頻功率施加於圓形線圈時,藉由施加於該線圈的感應磁場產生的電漿密度可能依據以載於反應室110的基板為基礎的內部線圈的直徑而變化,以及外部線圈可彌補電漿均勻性。然而,根據上述結構,功率損耗可能因為介於圓形線圈與位在反應室110外面的接地物件之間的距離而發生,所以在載於反應室110的基板的邊緣的電漿密度可能顯著地降低。為了彌補電漿密度的下降,永久性磁鐵190被排列以推動電漿通量朝向載於反應室110的基板,以這種方式,透過腔室壁111損耗的電漿通量可被限定在預定區域內。因此,電漿密度可以均勻地分佈在基板的整個面積。 Therefore, when RF power is applied to the circular coil, the plasma density generated by the induced magnetic field applied to the coil may vary depending on the diameter of the internal coil based on the substrate carried in the reaction chamber 110, and the external coil may be Make up for plasma uniformity. However, according to the above structure, the power loss may occur due to the distance between the circular coil and the grounded object located outside the reaction chamber 110, so the plasma density at the edge of the substrate carried in the reaction chamber 110 may be remarkably reduce. In order to compensate for the decrease in plasma density, the permanent magnets 190 are arranged to push the plasma flux toward the substrate carried in the reaction chamber 110, in such a manner that the plasma flux lost through the chamber wall 111 can be limited to a predetermined within the area. Therefore, the plasma density can be uniformly distributed over the entire area of the substrate.
除此之外,一功率接收零組件可分成複數個彼此平行連接的功率接收零組件,係為了藉由使用複數個分開的電 介質絕緣板同時地蝕刻在電漿真空室110中的複數個基板。當用以產生感應電場的線圈的長度因為大尺寸製程設備而增加時,其感應係數也增加,所以電漿效率減少。為了解決這個問題,永久性磁鐵190被排列使得線圈承受該磁場,以及透過作為接地的腔室壁111損耗的功率被限定在預定區域內,所以線圈效率可以被提高以及製程設備可透過自動分割而以大尺寸製造。 In addition, a power receiving component can be divided into a plurality of power receiving components connected in parallel with each other, in order to use a plurality of separate powers. The dielectric insulation plate simultaneously etches a plurality of substrates in the plasma vacuum chamber 110. When the length of the coil for generating the induced electric field is increased due to the large-sized process equipment, the inductance is also increased, so the plasma efficiency is reduced. In order to solve this problem, the permanent magnets 190 are arranged such that the coils are subjected to the magnetic field, and the power loss through the chamber wall 111 as the ground is limited to a predetermined area, so that the coil efficiency can be improved and the process equipment can be automatically divided. Made in large size.
天線零組件10的線圈是由具有約2毫米至約7毫米直徑的圓形銅所製成,以及銀、金或鉑是鍍在線圈的表面上以提高功率傳送效率以及冷卻從天線零組件10產生的熱。 The coil of antenna assembly 10 is made of round copper having a diameter of from about 2 mm to about 7 mm, and silver, gold or platinum is plated on the surface of the coil to improve power transfer efficiency and cooling from antenna assembly 10 The heat generated.
本發明中所用的永久性磁鐵190是不同地排列以獲得具有不同形狀與強度的磁力線。詳細地,此永久性磁鐵是圓形地排列而與圓形天線線圈隔開,其中介於兩相鄰永久磁鐵190之間的距離是1毫米至15毫米,磁極可以這種方式交替地形成。除此之外,永久性磁鐵190是圓形地排列使得該磁場在以一預定距離與載於反應室的基板的邊緣隔開的區域可具有最小的高斯值。若在電漿密度是由感應電場產生之下執行該製程,磁力可能不會在這個製程產生影響。因此,來自磁力線的製程參數可在製程期間被移除,所以透過腔室壁111損耗的功率可被限定在製程區域內,所以電漿密度的均勻性可被提高。也就是說,電漿密度的均勻性可因為線圈的架構以及磁極的配置而被提高。 The permanent magnets 190 used in the present invention are arranged differently to obtain magnetic lines of force having different shapes and strengths. In detail, the permanent magnets are circularly arranged to be spaced apart from the circular antenna coil, wherein the distance between two adjacent permanent magnets 190 is 1 mm to 15 mm, and the magnetic poles may be alternately formed in this manner. In addition, the permanent magnets 190 are circularly arranged such that the magnetic field can have a minimum Gauss value at a predetermined distance from the edge of the substrate carried by the reaction chamber. If the process is performed while the plasma density is generated by the induced electric field, the magnetic force may not affect the process. Therefore, the process parameters from the magnetic lines of force can be removed during the process, so the power lost through the chamber wall 111 can be limited to the process area, so the uniformity of the plasma density can be improved. That is to say, the uniformity of the plasma density can be improved due to the structure of the coil and the configuration of the magnetic poles.
永久性磁鐵190是配置在天線零組件10的外面以及永久性磁鐵190的數量可能依據電介質絕緣板140的外徑或永久 性磁鐵190的大小或磁力而變化。在這方面,本發明不限制永久性磁鐵190的數量與大小。 The permanent magnet 190 is disposed outside of the antenna assembly 10 and the number of permanent magnets 190 may depend on the outer diameter or permanent of the dielectric insulating plate 140. The size or magnetic force of the magnet 190 changes. In this regard, the invention does not limit the number and size of permanent magnets 190.
介於二相鄰永久性磁鐵190之間的距離d是設為1毫米至15毫米,以及永久性磁鐵190是按順序地排列使得相同極性與不同極性是交替地形成在二相鄰的永久性磁鐵190之間。因此,可以獲得如第3圖所示的有效磁力分佈。 The distance d between two adjacent permanent magnets 190 is set to be 1 mm to 15 mm, and the permanent magnets 190 are sequentially arranged such that the same polarity and different polarities are alternately formed in two adjacent permanent Between the magnets 190. Therefore, the effective magnetic force distribution as shown in Fig. 3 can be obtained.
如上所述,根據本發明的第一實施例,如第3圖所示,有效磁力分佈的極限線被提供,所以電漿製程面積可延伸至基板W的外徑之外,所以該製程效率可以被提高。 As described above, according to the first embodiment of the present invention, as shown in FIG. 3, the limit line of the effective magnetic force distribution is provided, so that the plasma process area can be extended beyond the outer diameter of the substrate W, so the process efficiency can be raised.
在下文中,本發明的第二實施例將參照第4圖被描述。 Hereinafter, a second embodiment of the present invention will be described with reference to FIG.
第4圖係為顯示根據本發明的第二實施例之天線零組件的配置之平面圖。 Fig. 4 is a plan view showing the configuration of an antenna component according to a second embodiment of the present invention.
除了天線系統150的天線零組件的結構之外,根據第二實施例的結構是相似於根據第一實施例的結構。因此,為了避免冗餘,接下來的描述將聚焦在天線零組件20的結構。 The structure according to the second embodiment is similar to the structure according to the first embodiment except for the structure of the antenna component of the antenna system 150. Therefore, to avoid redundancy, the following description will focus on the structure of the antenna component 20.
根據本發明的第二實施例,天線零組件20具有相似於相關技術的雙層結構。詳細地,根據本發明的第二實施例的天線零組件20包括排列在相鄰於反應室110的上部部分的第一平面上的第一下部天線、排列在第一下部天線內的第一平面上而與第一下部天線隔開的第二下部天線、排列在平行於第一平面且自第一平面向上移動的第二平 面上的第一上部天線,以及排列在第一上部天線內的第二平面上而與第一上部天線隔開的第二上部天線。 According to the second embodiment of the present invention, the antenna component 20 has a two-layer structure similar to the related art. In detail, the antenna component 20 according to the second embodiment of the present invention includes a first lower antenna arranged in a first plane adjacent to an upper portion of the reaction chamber 110, and a first array arranged in the first lower antenna a second lower antenna spaced apart from the first lower antenna on a plane, and a second flat arranged parallel to the first plane and moving upward from the first plane a first upper antenna on the face and a second upper antenna spaced apart from the first upper antenna on a second plane within the first upper antenna.
因此,如第4圖所示,根據本發明的第二實施例的天線零組件20包括四個開口,也就是說,第一下部天線的開口、第二下部天線的開口、第一上部天線的開口以及第二上部天線的開口,其以90°的間隔排列在圓形線圈的同心圓上。 Therefore, as shown in FIG. 4, the antenna component 20 according to the second embodiment of the present invention includes four openings, that is, an opening of the first lower antenna, an opening of the second lower antenna, and a first upper antenna. The opening and the opening of the second upper antenna are arranged at 90° intervals on the concentric circles of the circular coil.
同時,介於第一與第二平面的垂直距離是約5毫米至約20毫米。也就是說,根據本發明的第二實施例,具有雙層結構的線圈被提供以提高電漿密度以及縮短製程時間。此雙層結構相較於單層結構可提高電漿密度。此時,介於二相鄰天線之間的垂直距離是約5毫米至約20毫米。除此之外,為了減少由圓形線圈的直徑所造成的電容組件的影響,兩線圈相對於基板是垂直地隔開或有角度地排列的,因此提高電漿密度分佈的均勻性而實現加強效果。 At the same time, the vertical distance between the first and second planes is from about 5 mm to about 20 mm. That is, according to the second embodiment of the present invention, a coil having a two-layer structure is provided to increase the plasma density and shorten the process time. This two-layer structure can increase the plasma density compared to a single layer structure. At this time, the vertical distance between two adjacent antennas is about 5 mm to about 20 mm. In addition, in order to reduce the influence of the capacitance component caused by the diameter of the circular coil, the two coils are vertically spaced or angularly arranged with respect to the substrate, thereby improving the uniformity of the plasma density distribution and enhancing effect.
為了減少來自於複數個具有多層結構的線圈的電容組件的影響所導致的電位差,線圈的直徑可能隨一參考線圈變化。在這種情況下,該電容組件的影響可以最小化。 In order to reduce the potential difference caused by the influence of a plurality of capacitor components having a plurality of layers of coils, the diameter of the coil may vary with a reference coil. In this case, the effect of the capacitive component can be minimized.
也就是說,若天線零組件20具有上述的雙層結構,電漿密度分佈可均勻地形成在基板的整個面積。 That is, if the antenna component 20 has the above-described two-layer structure, the plasma density distribution can be uniformly formed over the entire area of the substrate.
在下文中,本發明的第三實施例將參照第5圖被描述。 Hereinafter, a third embodiment of the present invention will be described with reference to FIG.
第5圖係為顯示根據本發明的第三實施例之天線零組件的配置之平面圖。 Fig. 5 is a plan view showing the configuration of an antenna component according to a third embodiment of the present invention.
除了天線系統150的天線零組件的結構之外,根據第三實施例的結構是相似於根據第一實施例的結構。因此,為了避免冗餘,接下來的描述將聚焦在天線零組件30的結構。 The structure according to the third embodiment is similar to the structure according to the first embodiment except for the structure of the antenna component of the antenna system 150. Therefore, to avoid redundancy, the following description will focus on the structure of the antenna component 30.
根據本發明的第三實施例,天線零組件30具有三層結構。詳細地,根據本發明的第三實施例的天線零組件30包括排列在相鄰於反應室110的上部部分的第一平面上的第一下部天線、排列在第一下部天線內的第一平面上而與第一下部天線隔開的第二下部天線、排列在平行於第一平面且自第一平面向上移動的第二平面上的第一上部天線、排列在第一上部天線內的第二平面上而與第一上部天線隔開的第二上部天線、排列在平行於第二平面且自第二平面向上移動的第三平面上的第三上部天線、以及排列在第三上部天線內的第二平面上而與第三上部天線隔開的第四上部天線。 According to the third embodiment of the present invention, the antenna component 30 has a three-layer structure. In detail, the antenna component 30 according to the third embodiment of the present invention includes a first lower antenna arranged in a first plane adjacent to an upper portion of the reaction chamber 110, and a first array arranged in the first lower antenna a second lower antenna spaced apart from the first lower antenna on a plane, a first upper antenna arranged on a second plane parallel to the first plane and moving upward from the first plane, arranged in the first upper antenna a second upper antenna spaced apart from the first upper antenna on the second plane, a third upper antenna arranged on a third plane parallel to the second plane and moving upward from the second plane, and arranged in the third upper portion a fourth upper antenna spaced apart from the third upper antenna in a second plane within the antenna.
因此,如第5圖所示,根據本發明的第三實施例的天線零組件30包括六個開口,其中第一下部天線的開口、第二下部天線的開口、以及第三上部天線的開口是以60°的間隔排列在圓形線圈的同心圓上。 Therefore, as shown in FIG. 5, the antenna component 30 according to the third embodiment of the present invention includes six openings, wherein the opening of the first lower antenna, the opening of the second lower antenna, and the opening of the third upper antenna They are arranged on the concentric circles of the circular coil at intervals of 60°.
若天線零組件30具有上述的三層結構,相較於本發明的第二實施例,其電漿密度分佈可均勻地形成在基板的整個面積。 If the antenna component 30 has the above-described three-layer structure, the plasma density distribution can be uniformly formed over the entire area of the substrate as compared with the second embodiment of the present invention.
若多層是透過上述的方式形成,發生在介於產生感應電場的線圈的功率接收零組件與線圈的接地輸出零組件之間的局部區域的電漿的不均勻性可被防止。也就是說,在結構方面,當從載於腔室中的基板的角度來看,此線圈被看作是在平的電介質絕緣版上提供兩個線圈,因此防止來自於複數個感應線圈的感應係數所導致的電漿放電效率的下降。 If a plurality of layers are formed by the above-described manner, plasma non-uniformity occurring in a local region between the power receiving component of the coil generating the induced electric field and the ground output component of the coil can be prevented. That is to say, in terms of structure, when viewed from the perspective of the substrate carried in the chamber, the coil is considered to provide two coils on a flat dielectric insulating plate, thereby preventing induction from a plurality of induction coils. The decrease in plasma discharge efficiency caused by the coefficient.
在下文中,本發明的第四實施例將參照第6圖被描述。 Hereinafter, a fourth embodiment of the present invention will be described with reference to FIG.
第6圖係為顯示根據本發明的第四實施例之天線零組件的配置之平面圖。 Fig. 6 is a plan view showing the configuration of an antenna component according to a fourth embodiment of the present invention.
除了天線系統150的天線零組件的結構之外,根據第四實施例的結構是相似於根據第一實施例的結構。因此,為了避免冗餘,接下來的描述將聚焦在天線零組件40的結構。 The structure according to the fourth embodiment is similar to the structure according to the first embodiment except for the structure of the antenna component of the antenna system 150. Therefore, to avoid redundancy, the following description will focus on the structure of the antenna component 40.
根據本發明的第四實施例,天線零組件40包括三個單獨的天線。詳細地,根據本發明的第四實施例的天線零組件40包括排列在相鄰於反應室110的上部部分的第一平面上的第一下部天線、排列在第一下部天線內的第一平面上而與第一下部天線隔開的第二下部天線、以及排列在第二下部天線內的第一平面上而與第二下部天線隔開的第三下部天線。 According to a fourth embodiment of the invention, antenna component 40 includes three separate antennas. In detail, the antenna component 40 according to the fourth embodiment of the present invention includes a first lower antenna arranged in a first plane adjacent to an upper portion of the reaction chamber 110, and a first array arranged in the first lower antenna a second lower antenna spaced apart from the first lower antenna on a plane, and a third lower antenna spaced on the first plane in the second lower antenna and spaced apart from the second lower antenna.
因此,如第6圖所示,根據本發明的第四實施例的天線零組件40包括三個開口,其中第一下部天線的開口、第二 下部天線的開口、以及第三下部天線的開口是以120°的間隔排列在圓形線圈的同心圓上。 Therefore, as shown in FIG. 6, the antenna component 40 according to the fourth embodiment of the present invention includes three openings, wherein the opening of the first lower antenna, the second The opening of the lower antenna and the opening of the third lower antenna are arranged at 120° intervals on the concentric circles of the circular coil.
若天線零組件40具有上述的三個單獨的天線,相較於本發明的第一實施例,其電漿密度分佈可均勻地形成在基板的整個面積。 If the antenna component 40 has the above three separate antennas, the plasma density distribution can be uniformly formed over the entire area of the substrate as compared with the first embodiment of the present invention.
在下文中,本發明的第五實施例將參照第7圖至第9圖被描述。 Hereinafter, a fifth embodiment of the present invention will be described with reference to FIGS. 7 to 9.
第7圖係為顯示根據本發明的第五實施例之天線零組件的配置之平面圖,第8a與第8b圖係為顯示用以解釋在天線零組件的單層結構與多層結構之間的差異的實驗結果之攝影圖,以及第9a與第9b圖係為顯示當天線零組件具有單層結構與三層結構時的基板均勻度的測量結果圖。 Figure 7 is a plan view showing the configuration of an antenna component according to a fifth embodiment of the present invention, and Figures 8a and 8b are diagrams for explaining the difference between the single-layer structure and the multilayer structure of the antenna component. The photographic images of the experimental results, and the 9a and 9b graphs are graphs showing the measurement results of the substrate uniformity when the antenna component has a single layer structure and a three layer structure.
除了天線系統150的天線零組件的結構之外,根據第五實施例的結構是相似於根據第一實施例的結構。因此,為了避免冗餘,接下來的描述將聚焦在天線零組件50的結構。 The structure according to the fifth embodiment is similar to the structure according to the first embodiment except for the structure of the antenna component of the antenna system 150. Therefore, to avoid redundancy, the following description will focus on the structure of the antenna component 50.
根據本發明的第五實施例,天線零組件50包括排列在相鄰於反應室110的上部部分的第一平面上的第一下部天線、排列在第一下部天線內的第一平面上而與第一下部天線隔開的第二下部天線、排列在平行於第一平面且自第一平面向上移動的第二平面上的第一上部天線、排列在第一上部天線內的第二平面上而與第一上部天線隔開的第二上部天線、排列在平行於第二平面且自第二平面向 上移動的第三平面上的第三上部天線、以及排列在第三上部天線內的第二平面上而與第三上部天線隔開的第四上部天線。 According to a fifth embodiment of the present invention, the antenna component 50 includes a first lower antenna arranged on a first plane adjacent to an upper portion of the reaction chamber 110, arranged on a first plane within the first lower antenna a second lower antenna spaced apart from the first lower antenna, a first upper antenna arranged on a second plane parallel to the first plane and moving upward from the first plane, and a second array arranged in the first upper antenna a second upper antenna spaced apart from the first upper antenna in a plane, arranged parallel to the second plane and extending from the second plane a third upper antenna on the third plane that moves upward, and a fourth upper antenna that is arranged on the second plane in the third upper antenna and spaced apart from the third upper antenna.
因此,如第7圖所示,根據本發明的第五實施例的天線零組件50包括六個開口,其中第一下部天線的開口、第二下部天線的開口、第一上部天線的開口、第二上部天線的開口、第三上部天線的開口、以及第四上部天線的開口是以60°的間隔排列在圓形線圈的同心圓上。 Therefore, as shown in FIG. 7, the antenna component 50 according to the fifth embodiment of the present invention includes six openings, wherein the opening of the first lower antenna, the opening of the second lower antenna, the opening of the first upper antenna, The opening of the second upper antenna, the opening of the third upper antenna, and the opening of the fourth upper antenna are arranged at 60° intervals on the concentric circles of the circular coil.
介於第一與第二平面的垂直距離是約5毫米至約20毫米。也就是說,根據本發明的第五實施例,具有多層結構的線圈被提供以提高電漿密度以及縮短製程時間。此多層結構相較於單層結構可提高電漿密度。此時,介於二相鄰天線之間的垂直距離是約5毫米至約20毫米。除此之外,為了減少由圓形線圈的直徑所造成的電容組件的影響,兩線圈相對於基板是垂直地隔開或有角度地排列的,因此提高電漿密度分佈的均勻性而實現加強效果。 The vertical distance between the first and second planes is from about 5 mm to about 20 mm. That is, according to the fifth embodiment of the present invention, a coil having a multilayer structure is provided to increase the plasma density and shorten the process time. This multilayer structure can increase the plasma density compared to a single layer structure. At this time, the vertical distance between two adjacent antennas is about 5 mm to about 20 mm. In addition, in order to reduce the influence of the capacitance component caused by the diameter of the circular coil, the two coils are vertically spaced or angularly arranged with respect to the substrate, thereby improving the uniformity of the plasma density distribution and enhancing effect.
也就是說,由第8圖可以看出,若天線零組件50具有上述的三層結構,相較於單層結構,其電漿密度分佈可均勻地形成在基板的整個面積。 That is, as can be seen from Fig. 8, if the antenna component 50 has the above-described three-layer structure, the plasma density distribution can be uniformly formed over the entire area of the substrate as compared with the single-layer structure.
由第9圖所示的實驗結果可以看出,若天線零組件具有單層結構,在基板的中央方向的蝕刻深度變窄,所以基板的均勻性是下降的。然而,若天線零組件具有多層結構,在基板的整個面積的蝕刻深度是均勻的。 As can be seen from the experimental results shown in Fig. 9, if the antenna component has a single layer structure, the etching depth in the center direction of the substrate is narrowed, so the uniformity of the substrate is lowered. However, if the antenna component has a multilayer structure, the etching depth over the entire area of the substrate is uniform.
在下文中,本發明的第六實施例將參照第10圖被描述。 Hereinafter, a sixth embodiment of the present invention will be described with reference to FIG.
第10圖係為顯示根據本發明的第六實施例之天線零組件的配置之平面圖。 Fig. 10 is a plan view showing the configuration of an antenna component according to a sixth embodiment of the present invention.
除了天線系統150的天線零組件的結構之外,根據第六實施例的結構是相似於根據第一實施例的結構。因此,為了避免冗餘,接下來的描述將聚焦在天線零組件60的結構。 The structure according to the sixth embodiment is similar to the structure according to the first embodiment except for the structure of the antenna component of the antenna system 150. Therefore, to avoid redundancy, the following description will focus on the structure of the antenna component 60.
根據本發明的第六實施例,天線零組件60包括排列在相鄰於反應室110的上部部分的第一平面上的第一下部天線、排列在第一下部天線內的第一平面上而與第一下部天線隔開的第二下部天線、排列在第二下部天線內的第一平面上而與第二下部天線隔開的第三下部天線、排列在平行於第一平面且自第一平面向上移動的第二平面上的第一上部天線、排列在第一上部天線內的第二平面上而與第一上部天線隔開的第二上部天線、排列在第二上部天線內的第二平面上而與第二上部天線隔開的第三上部天線、排列在平行於第二平面且自第二平面向上移動的第三平面上的第四上部天線、排列在第四上部天線內的第三平面上而與第四上部天線隔開的第五上部天線、以及排列在第五上部天線內的第三平面上而與第五上部天線隔開的第六上部天線。 According to a sixth embodiment of the present invention, the antenna component 60 includes a first lower antenna arranged on a first plane adjacent to an upper portion of the reaction chamber 110, arranged on a first plane within the first lower antenna And a second lower antenna spaced apart from the first lower antenna, a third lower antenna arranged on the first plane in the second lower antenna and spaced apart from the second lower antenna, arranged parallel to the first plane and a first upper antenna on a second plane in which the first plane moves upward, a second upper antenna arranged on a second plane in the first upper antenna and spaced apart from the first upper antenna, and arranged in the second upper antenna a third upper antenna spaced apart from the second upper antenna on the second plane, a fourth upper antenna arranged on a third plane parallel to the second plane and moving upward from the second plane, arranged in the fourth upper antenna a fifth upper antenna spaced apart from the fourth upper antenna on the third plane, and a sixth upper antenna spaced apart from the fifth upper antenna in a third plane disposed within the fifth upper antenna.
根據第六實施例,介於第一與第二平面的垂直距離是約5毫米至約20毫米,以及介於第二與第三平面的垂直距離是約5毫米至約20毫米。 According to a sixth embodiment, the vertical distance between the first and second planes is from about 5 mm to about 20 mm, and the vertical distance between the second and third planes is from about 5 mm to about 20 mm.
因此,如第10圖所示,根據本發明的第六實施例的天線零組件60包括九個開口,其中第一下部天線的開口、第二下部天線的開口、第三下部天線的開口、第一上部天線的開口、第二上部天線的開口、第三上部天線的開口、第四上部天線的開口、第五上部天線的開口、以及第六上部天線的開口是以40°的間隔排列在圓形線圈的同心圓上。 Therefore, as shown in FIG. 10, the antenna component 60 according to the sixth embodiment of the present invention includes nine openings, wherein the opening of the first lower antenna, the opening of the second lower antenna, the opening of the third lower antenna, The opening of the first upper antenna, the opening of the second upper antenna, the opening of the third upper antenna, the opening of the fourth upper antenna, the opening of the fifth upper antenna, and the opening of the sixth upper antenna are arranged at intervals of 40°. On the concentric circles of the circular coil.
在上述條件之下產生的電漿可在低於傳統電漿製程壓力的壓力下穩定地放電。若本發明被應用在蝕刻用於製造LED的藍寶石晶圓的表面,均勻的電漿密度分佈可在幾mT至幾百mT的製程壓力下獲得,所以本發明蝕刻用於製造LED的藍寶石晶圓是非常有效的。 The plasma produced under the above conditions can be stably discharged at a pressure lower than that of the conventional plasma process. If the present invention is applied to the surface of a sapphire wafer for etching LEDs, a uniform plasma density distribution can be obtained at a process pressure of several mT to several hundred mT, so the present invention etches a sapphire wafer for manufacturing LEDs. It is very effective.
詳細地,由第11圖可以看出,條件2(如第7圖所示的天線結構)展現較條件1(如第4圖所示的天線結構)高的蝕刻深度均勻性。也就是說,條件1的電漿密度的均勻性是高於條件2。除此之外,條件2的蝕刻深度是深於條件1,其是指條件1的電漿密度的均勻性是高於條件2。 In detail, as can be seen from Fig. 11, condition 2 (such as the antenna structure shown in Fig. 7) exhibits a higher etching depth uniformity than condition 1 (such as the antenna structure shown in Fig. 4). That is, the uniformity of the plasma density of Condition 1 is higher than Condition 2. Except for this, the etching depth of Condition 2 is deeper than Condition 1, which means that the uniformity of the plasma density of Condition 1 is higher than Condition 2.
根據本發明,第一與第二下部天線是分別位在與圓形線圈的中央分隔300毫米與200毫米的位置,以及該三個單獨的天線的第一至第三下部天線是分別位在與圓形線圈的中央分隔340毫米、280毫米與160毫米的位置。然而,本發明並不限於此,以及第一至第三天線的位置可能依據反應室的體積而變化。 According to the present invention, the first and second lower antennas are respectively located at positions spaced apart from the center of the circular coil by 300 mm and 200 mm, and the first to third lower antennas of the three separate antennas are respectively located The center of the circular coil is separated by 340 mm, 280 mm and 160 mm. However, the present invention is not limited thereto, and the positions of the first to third antennas may vary depending on the volume of the reaction chamber.
雖然本發明的例示性實施例已被描述,應了解的是本發 明並不限於這些例示性實施例,而是可在未脫離如後附申請專利範圍中所列明之本發明之精神與範疇下,由所屬技術領域具有通常知識者進行各種變更與修改。 Although an exemplary embodiment of the present invention has been described, it should be understood that the present invention The present invention is not limited to the exemplary embodiments, and various changes and modifications can be made by those skilled in the art without departing from the spirit and scope of the invention as set forth in the appended claims.
10、20、30、40、50、60‧‧‧天線零組件 10, 20, 30, 40, 50, 60‧‧‧ antenna components
100‧‧‧高密度電漿產生器 100‧‧‧High-density plasma generator
11‧‧‧第一下部天線 11‧‧‧First lower antenna
110‧‧‧反應室 110‧‧‧Reaction room
111‧‧‧腔室壁 111‧‧‧ chamber wall
112‧‧‧空腔 112‧‧‧ Cavity
114‧‧‧氣體進料口 114‧‧‧ gas inlet
12‧‧‧第二下部天線 12‧‧‧Second lower antenna
120‧‧‧基板盤 120‧‧‧ substrate plate
130‧‧‧晶圓座 130‧‧‧ Wafer Holder
140‧‧‧電介質絕緣板 140‧‧‧Dielectric insulation board
150‧‧‧天線系統 150‧‧‧Antenna system
160‧‧‧接地外殼 160‧‧‧ Grounding enclosure
162‧‧‧凸緣 162‧‧‧Flange
163‧‧‧固定基架 163‧‧‧Fixed pedestal
17‧‧‧開口 17‧‧‧ openings
170‧‧‧射頻功率來源 170‧‧‧RF power source
18‧‧‧功率接收零組件 18‧‧‧Power receiving components
180‧‧‧阻抗匹配器 180‧‧‧impedance matcher
19‧‧‧接地輸出零組件 19‧‧‧ Grounding output components
190‧‧‧永久性磁鐵 190‧‧‧Permanent magnet
d‧‧‧距離 D‧‧‧distance
l‧‧‧垂直距離 l ‧‧‧vertical distance
第1圖係為顯示根據本發明的第一實施例之一高密度電漿產生器的結構之透視圖;第2圖係為顯示如第1圖中所示之天線系統與永久性磁鐵間的配置關係之平面圖;第3圖係為顯示根據本發明之以永久性磁鐵的配置為基礎的有效磁力分佈之平面圖;第4圖係為顯示根據本發明的第二實施例之天線零組件的配置之平面圖;第5圖係為顯示根據本發明的第三實施例之天線零組件的配置之平面圖;第6圖係為顯示根據本發明的第四實施例之天線零組件的配置之平面圖;第7圖係為顯示根據本發明的第五實施例之天線零組件的配置之平面圖;第8a與第8b圖係為顯示用以解釋在天線零組件的單層結構與多層結構之間的差異的實驗結果之攝影圖;第9a與第9b圖係為顯示當天線零組件具有單層結構與三層結構時的基板均勻度的測量結果圖;第10圖係為顯示根據本發明的第六實施例之天線零組件的配置之平面圖;第11a至11c圖係為顯示如第4與第7圖中所示的天線結構的測量結果圖;以及 第12圖係為顯示根據相關技術之天線系統的結構之透視圖。 1 is a perspective view showing the structure of a high-density plasma generator according to a first embodiment of the present invention; and FIG. 2 is a view showing the relationship between the antenna system and the permanent magnet as shown in FIG. A plan view of the configuration relationship; FIG. 3 is a plan view showing an effective magnetic force distribution based on the configuration of the permanent magnet according to the present invention; and FIG. 4 is a view showing the configuration of the antenna component according to the second embodiment of the present invention. FIG. 5 is a plan view showing a configuration of an antenna component according to a third embodiment of the present invention; and FIG. 6 is a plan view showing a configuration of an antenna component according to a fourth embodiment of the present invention; 7 is a plan view showing a configuration of an antenna component according to a fifth embodiment of the present invention; FIGS. 8a and 8b are diagrams for explaining a difference between a single layer structure and a multilayer structure of an antenna component. Photographs of experimental results; Figures 9a and 9b are graphs showing measurement results of substrate uniformity when the antenna component has a single layer structure and a three layer structure; and Fig. 10 is a view showing a sixth embodiment according to the present invention. Disposing a plan view of the antenna components; FIG. 11a to 11c based on the display as a measurement result of FIG. 4 and the antenna structure shown in Fig. 7; and Fig. 12 is a perspective view showing the structure of an antenna system according to the related art.
10‧‧‧天線零組件 10‧‧‧Antenna components
100‧‧‧高密度電漿產生器 100‧‧‧High-density plasma generator
11‧‧‧第一下部天線 11‧‧‧First lower antenna
110‧‧‧反應室 110‧‧‧Reaction room
111‧‧‧腔室壁 111‧‧‧ chamber wall
112‧‧‧空腔 112‧‧‧ Cavity
114‧‧‧氣體進料口 114‧‧‧ gas inlet
12‧‧‧第二下部天線 12‧‧‧Second lower antenna
120‧‧‧基板盤 120‧‧‧ substrate plate
140‧‧‧電介質絕緣板 140‧‧‧Dielectric insulation board
150‧‧‧天線系統 150‧‧‧Antenna system
160‧‧‧接地外殼 160‧‧‧ Grounding enclosure
162‧‧‧凸緣 162‧‧‧Flange
163‧‧‧固定基架 163‧‧‧Fixed pedestal
170‧‧‧射頻功率來源 170‧‧‧RF power source
18‧‧‧功率接收零組件 18‧‧‧Power receiving components
180‧‧‧阻抗匹配器 180‧‧‧impedance matcher
19‧‧‧接地輸出零組件 19‧‧‧ Grounding output components
190‧‧‧永久性磁鐵 190‧‧‧Permanent magnet
l‧‧‧垂直距離 l ‧‧‧vertical distance
Claims (22)
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KR1020100125941A KR101039232B1 (en) | 2010-04-27 | 2010-12-10 | High-density plasma generation apparatus |
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TWI406336B true TWI406336B (en) | 2013-08-21 |
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TW508693B (en) * | 1999-08-31 | 2002-11-01 | Tokyo Electron Limted | Plasma treating apparatus and plasma treating method |
TW521298B (en) * | 2000-03-27 | 2003-02-21 | Lam Res Corp | Method and apparatus for plasma forming inner magnetic bucket to control a volume of a plasma |
EP2151855A1 (en) * | 2007-05-18 | 2010-02-10 | Ulvac, Inc. | Plasma-processing device and method of manufacturing adhesion-preventing member |
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KR100742659B1 (en) * | 2005-04-12 | 2007-07-25 | 한양대학교 산학협력단 | Inductively coupled plasma generating apparatus with magnetic core |
KR100692420B1 (en) * | 2005-12-09 | 2007-03-13 | 주식회사 플라즈마트 | An antenna structure for inductively coupled plasma generator |
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TW508693B (en) * | 1999-08-31 | 2002-11-01 | Tokyo Electron Limted | Plasma treating apparatus and plasma treating method |
TW521298B (en) * | 2000-03-27 | 2003-02-21 | Lam Res Corp | Method and apparatus for plasma forming inner magnetic bucket to control a volume of a plasma |
EP2151855A1 (en) * | 2007-05-18 | 2010-02-10 | Ulvac, Inc. | Plasma-processing device and method of manufacturing adhesion-preventing member |
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