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JP6971676B2 - Board processing equipment and board processing method - Google Patents

Board processing equipment and board processing method Download PDF

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Publication number
JP6971676B2
JP6971676B2 JP2017142408A JP2017142408A JP6971676B2 JP 6971676 B2 JP6971676 B2 JP 6971676B2 JP 2017142408 A JP2017142408 A JP 2017142408A JP 2017142408 A JP2017142408 A JP 2017142408A JP 6971676 B2 JP6971676 B2 JP 6971676B2
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substrate
cleaning
polishing
unit
drying
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JP2018037650A (en
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正芳 今井
克彦 徳重
大 小倉
和英 渡辺
淳次 國澤
健 飯泉
充 宮▲崎▼
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Ebara Corp
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Ebara Corp
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Priority to TW106128411A priority Critical patent/TWI757323B/en
Priority to KR1020170106491A priority patent/KR102401528B1/en
Priority to SG10201706944YA priority patent/SG10201706944YA/en
Priority to US15/688,281 priority patent/US10500691B2/en
Priority to CN201710750724.1A priority patent/CN107799436B/en
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L21/00Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
    • H01L21/67Apparatus 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
    • H01L21/67005Apparatus not specifically provided for elsewhere
    • H01L21/67011Apparatus for manufacture or treatment
    • H01L21/67017Apparatus for fluid treatment
    • H01L21/67028Apparatus for fluid treatment for cleaning followed by drying, rinsing, stripping, blasting or the like
    • H01L21/6704Apparatus for fluid treatment for cleaning followed by drying, rinsing, stripping, blasting or the like for wet cleaning or washing
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L21/00Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
    • H01L21/02Manufacture or treatment of semiconductor devices or of parts thereof
    • H01L21/02041Cleaning
    • H01L21/02043Cleaning before device manufacture, i.e. Begin-Of-Line process
    • H01L21/02052Wet cleaning only
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L21/00Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
    • H01L21/02Manufacture or treatment of semiconductor devices or of parts thereof
    • H01L21/04Manufacture or treatment of semiconductor devices or of parts thereof the devices having potential barriers, e.g. a PN junction, depletion layer or carrier concentration layer
    • H01L21/18Manufacture or treatment of semiconductor devices or of parts thereof the devices having potential barriers, e.g. a PN junction, depletion layer or carrier concentration layer the devices having semiconductor bodies comprising elements of Group IV of the Periodic Table or AIIIBV compounds with or without impurities, e.g. doping materials
    • H01L21/30Treatment of semiconductor bodies using processes or apparatus not provided for in groups H01L21/20 - H01L21/26
    • H01L21/302Treatment of semiconductor bodies using processes or apparatus not provided for in groups H01L21/20 - H01L21/26 to change their surface-physical characteristics or shape, e.g. etching, polishing, cutting
    • H01L21/304Mechanical treatment, e.g. grinding, polishing, cutting
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L21/00Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
    • H01L21/67Apparatus 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
    • H01L21/67005Apparatus not specifically provided for elsewhere
    • H01L21/67011Apparatus for manufacture or treatment
    • H01L21/67017Apparatus for fluid treatment
    • H01L21/67028Apparatus for fluid treatment for cleaning followed by drying, rinsing, stripping, blasting or the like
    • H01L21/67034Apparatus for fluid treatment for cleaning followed by drying, rinsing, stripping, blasting or the like for drying
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L21/00Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
    • H01L21/67Apparatus 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
    • H01L21/67005Apparatus not specifically provided for elsewhere
    • H01L21/67011Apparatus for manufacture or treatment
    • H01L21/67092Apparatus for mechanical treatment
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L21/00Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
    • H01L21/67Apparatus 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
    • H01L21/677Apparatus 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 for conveying, e.g. between different workstations
    • H01L21/67739Apparatus 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 for conveying, e.g. between different workstations into and out of processing chamber

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  • Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • Condensed Matter Physics & Semiconductors (AREA)
  • General Physics & Mathematics (AREA)
  • Manufacturing & Machinery (AREA)
  • Computer Hardware Design (AREA)
  • Microelectronics & Electronic Packaging (AREA)
  • Power Engineering (AREA)
  • Cleaning Or Drying Semiconductors (AREA)
  • Mechanical Treatment Of Semiconductor (AREA)
  • Grinding-Machine Dressing And Accessory Apparatuses (AREA)
  • Finish Polishing, Edge Sharpening, And Grinding By Specific Grinding Devices (AREA)

Description

本開示は、基板処理装置および基板処理方法に関する。 The present disclosure relates to a substrate processing apparatus and a substrate processing method.

CMP(Chemical Mechanical Polishing)装置などの基板処理装置は、スラリーを用いて基板を研磨し、その後に基板を洗浄する。しかしながら、基板処理装置内での洗浄では必ずしも洗浄力が十分ではなく、基板処理装置とは別個の基板洗浄装置を用いて基板を洗浄することが多い。そうすると、基板処理の工程数が増加してしまうという問題がある。 A substrate processing apparatus such as a CMP (Chemical Mechanical Polishing) apparatus polishes a substrate using a slurry, and then cleans the substrate. However, the cleaning power in the substrate processing apparatus is not always sufficient, and the substrate is often cleaned using a substrate cleaning apparatus separate from the substrate processing apparatus. Then, there is a problem that the number of substrate processing steps increases.

特開2008−114183号公報Japanese Unexamined Patent Publication No. 2008-114183 特許第3725809号公報Japanese Patent No. 3725809

本開示はこのような問題点に鑑みてなされたものであり、その課題は、少ない工程数で研磨後の基板を十分に洗浄できる基板処理装置および基板処理方法を提供することである。 The present disclosure has been made in view of such problems, and an object thereof is to provide a substrate processing apparatus and a substrate processing method capable of sufficiently cleaning a polished substrate with a small number of steps.

本開示の一態様によれば、研磨液を用いて基板を研磨する研磨部と、前記研磨部で研磨された基板を硫酸および過酸化水素水を用いて洗浄する第1洗浄部と、前記第1洗浄部によって洗浄された基板を塩基性の薬液および過酸化水素水を用いて洗浄する第2洗浄部と、前記第2洗浄部によって洗浄された基板を乾燥させる乾燥部と、を備える基板処理装置が提供される。 According to one aspect of the present disclosure, a polishing unit that polishes a substrate with a polishing liquid, a first cleaning unit that cleans the substrate polished by the polishing unit with sulfuric acid and a hydrogen peroxide solution, and the first cleaning unit. (1) Substrate treatment including a second cleaning section for cleaning the substrate washed by the cleaning section with a basic chemical solution and a hydrogen peroxide solution, and a drying section for drying the substrate washed by the second cleaning section. Equipment is provided.

基板処理装置内に第1洗浄部および第2洗浄部を設ける。そして、硫酸および過酸化水素水を用いた第1洗浄部による洗浄により、研磨液を除去できる。塩基性の薬液および過酸化水素水を用いた第2洗浄部による洗浄により、第1洗浄部で用いられた硫酸に起因する成分を除去できる。これにより、少ない工程数で、研磨後の基板を十分に洗浄できる。 A first cleaning unit and a second cleaning unit are provided in the substrate processing apparatus. Then, the polishing liquid can be removed by cleaning with the first cleaning unit using sulfuric acid and hydrogen peroxide solution. By cleaning with the second cleaning unit using a basic chemical solution and hydrogen peroxide solution, the components due to sulfuric acid used in the first cleaning unit can be removed. As a result, the polished substrate can be sufficiently cleaned with a small number of steps.

前記研磨部によって研磨された後、かつ、前記第1洗浄部によって洗浄される前の前記基板を乾燥させる機構を持たないのが望ましい。
また、前記研磨部によって研磨された基板を乾燥させることなく前記第1洗浄部に搬送する搬送部を備えるのが望ましい。
より望ましくは、前記搬送部によって搬送中の基板に液体を浴びせる第1液体供給機構を備える。
また、当該搬送部は、前記研磨部によって研磨された後、かつ、前記第1洗浄部によって洗浄される前の基板が載置される基板ステーションと、前記基板ステーションに載置された基板に液体を浴びせる第2液体供給機構と、を備えるのが望ましい。
研磨後の基板を乾燥させないことで、第1洗浄部による洗浄時に、効率よく基板上の残渣を除去できる。
It is desirable not to have a mechanism for drying the substrate after being polished by the polishing portion and before being cleaned by the first cleaning portion.
Further, it is desirable to provide a transport section for transporting the substrate polished by the polishing section to the first cleaning section without drying it.
More preferably, it is provided with a first liquid supply mechanism for spraying a liquid on the substrate being transported by the transport unit.
Further, the transport section is a liquid on a substrate station on which a substrate is placed after being polished by the polishing section and before being cleaned by the first cleaning section, and a substrate mounted on the substrate station. It is desirable to have a second liquid supply mechanism for bathing.
By not drying the polished substrate, the residue on the substrate can be efficiently removed during cleaning by the first cleaning unit.

前記第1洗浄部は、開閉可能な第1シャッタが設けられた第1筐体に収納され、前記第2洗浄部は、開閉可能な第2シャッタが設けられた第2筐体に収納され、前記乾燥部は、開閉可能な第3シャッタが設けられた第3筐体に収納されるのが望ましい。
これにより、第1洗浄部で用いられる硫酸や過酸化水素水が第2洗浄部や乾燥部に侵入するのを抑えられるし、第2洗浄部で用いられる塩基性の薬液や過酸化水素水が第1洗浄部や乾燥部に侵入するのを抑えられる。
The first cleaning unit is housed in a first housing provided with a first shutter that can be opened and closed, and the second cleaning unit is housed in a second housing provided with a second shutter that can be opened and closed. It is desirable that the dried portion be housed in a third housing provided with a third shutter that can be opened and closed.
As a result, the sulfuric acid and hydrogen peroxide solution used in the first cleaning section can be suppressed from invading the second cleaning section and the drying section, and the basic chemical solution and hydrogen peroxide solution used in the second cleaning section can be prevented. It is possible to prevent the invasion of the first cleaning part and the drying part.

前記研磨部によって研磨された基板を、塩基性の薬液および過酸化水素水を用いて洗浄する第3洗浄部を備え、前記第1洗浄部は、前記第3洗浄部によって洗浄された基板を洗浄するのが望ましい。
前記第3洗浄部は、塩基性の薬液および過酸化水素水を前記基板に供給しつつ、洗浄部材を前記基板に接触させて洗浄するのが望ましい。
前記第2洗浄部は、塩基性の薬液および過酸化水素水を用いて前記基板を洗浄した後、2流体ジェット洗浄を行うのが望ましい。
これらの構成により、洗浄力がさらに向上する。
A third cleaning unit for cleaning the substrate polished by the polishing unit with a basic chemical solution and a hydrogen peroxide solution is provided, and the first cleaning unit cleans the substrate cleaned by the third cleaning unit. It is desirable to do.
It is desirable that the third cleaning unit cleans the substrate by bringing the cleaning member into contact with the substrate while supplying the basic chemical solution and the hydrogen peroxide solution to the substrate.
It is desirable that the second cleaning unit cleans the substrate with a basic chemical solution and hydrogen peroxide solution, and then performs two-fluid jet cleaning.
With these configurations, the detergency is further improved.

前記研磨部は、セリアを含む研磨液を用いて前記基板を研磨してもよい。
第1洗浄部による洗浄によって、セリアの残留を減らすことができる。
The polishing portion may polish the substrate with a polishing liquid containing ceria.
Cleaning by the first cleaning unit can reduce the residual ceria.

また、本開示の一態様によれば、基板処理装置における研磨部によって、研磨液を用いて基板を研磨する研磨工程と、その後、前記基板処理装置における第1洗浄部によって、前記基板を硫酸および過酸化水素水を用いて洗浄する第1洗浄工程と、その後、前記基板処理装置における第2洗浄部によって、前記基板を塩基性の薬液および過酸化水素水を用いて洗浄する第2洗浄工程と、その後、前記基板処理装置における乾燥部によって、前記基板を乾燥させる乾燥工程と、を備える基板処理方法が提供される。 Further, according to one aspect of the present disclosure, the substrate is subjected to sulfuric acid and sulfuric acid by a polishing step of polishing the substrate with a polishing liquid by a polishing unit in the substrate processing apparatus and then by a first cleaning unit in the substrate processing apparatus. A first cleaning step of cleaning with a hydrogen peroxide solution, and then a second cleaning step of cleaning the substrate with a basic chemical solution and a hydrogen peroxide solution by a second cleaning unit in the substrate processing apparatus. After that, a substrate processing method including a drying step of drying the substrate is provided by a drying unit in the substrate processing apparatus.

基板処理装置内に設けられた第1洗浄部および第2洗浄部によって、硫酸および過酸化水素水を用いた洗浄と、塩基性の薬液および過酸化水素水を用いた洗浄とを行う。これにより、少ない工程数で、研磨後の基板を十分に洗浄できる。 Cleaning with sulfuric acid and hydrogen peroxide solution and cleaning with a basic chemical solution and hydrogen peroxide solution are performed by the first cleaning unit and the second cleaning unit provided in the substrate processing apparatus. As a result, the polished substrate can be sufficiently cleaned with a small number of steps.

前記研磨工程の後、研磨された基板を乾燥させることなく前記研磨部から前記第1洗浄部に前記基板を搬送する搬送工程を備えるのが望ましい。
研磨後の基板を乾燥させないことで、第1洗浄部による洗浄時に、効率よく基板上の残渣を除去できる。
After the polishing step, it is desirable to include a transfer step of transporting the substrate from the polishing portion to the first cleaning portion without drying the polished substrate.
By not drying the polished substrate, the residue on the substrate can be efficiently removed during cleaning by the first cleaning unit.

本発明の一態様によれば、セリウムイオンが付着した基板を硫酸および過酸化水素水を用いて洗浄する第1洗浄工程と、その後、塩基性の薬液および過酸化水素水を用いて前記基板を洗浄する第2洗浄工程と、その後、前記基板を乾燥させる乾燥工程と、を備える基板処理方法が提供される。
硫酸および過酸化水素水を用いて基板を洗浄することにより、セリウムイオンを除去できる。その後に塩基性の薬液および過酸化水素水を用いて基板を洗浄することで硫酸を除去できる。
According to one aspect of the present invention, a first cleaning step of cleaning a substrate to which cerium ions are attached with sulfuric acid and a hydrogen peroxide solution, and then a basic chemical solution and a hydrogen peroxide solution are used to clean the substrate. A substrate processing method comprising a second cleaning step of cleaning and then a drying step of drying the substrate is provided.
Cerium ions can be removed by cleaning the substrate with sulfuric acid and hydrogen peroxide solution. After that, sulfuric acid can be removed by washing the substrate with a basic chemical solution and hydrogen peroxide solution.

前記第1洗浄工程では、セリウム濃度が1.0×1010atms/cm2以上であるセリウムイオンが付着した基板を洗浄し、前記乾燥工程を経た基板のセリウム濃度は、ICP−MS法による測定において検出限界以下であるのが望ましい。 In the first cleaning step, the substrate to which cerium ions having a cerium concentration of 1.0 × 10 10 atms / cm 2 or more are attached is washed, and the cerium concentration of the substrate after the drying step is measured by the ICP-MS method. It is desirable that it is below the detection limit.

前記第1洗浄工程および/または前記第2洗浄工程では、前記基板を加熱してもよい。 In the first cleaning step and / or the second cleaning step, the substrate may be heated.

前記第1洗浄工程の前に、セリウムイオンが付着した前記基板に対して、塩基性の薬液および過酸化水素水を供給する工程、回転するスポンジ部材を接触させる工程、および、気体および液体のジェット流を供給する工程の少なくとも1つの工程を備えるのが望ましい。
このような粗洗浄を行うことで、さらに、一連の基板洗浄工程における洗浄力が向上する。
Prior to the first cleaning step, a step of supplying a basic chemical solution and a hydrogen peroxide solution to the substrate to which cerium ions are attached, a step of contacting a rotating sponge member, and a gas and liquid jet. It is desirable to have at least one step of supplying the stream.
By performing such rough cleaning, the cleaning power in a series of substrate cleaning steps is further improved.

前記第1洗浄工程、前記第2洗浄工程および前記乾燥工程は、洗浄槽内で行われ、前記第1洗浄工程と前記第2洗浄工程との間に、前記洗浄槽の内側を洗浄する工程と、前記第2洗浄工程と前記乾燥工程との間に、前記洗浄槽の内側を洗浄する工程と、を備えるのが望ましい。
これにより、薬液(特に、硫酸と塩基性の薬液)が反応するのを抑制できる。
The first cleaning step, the second cleaning step, and the drying step are performed in a cleaning tank, and a step of cleaning the inside of the cleaning tank between the first cleaning step and the second cleaning step. It is desirable to include a step of cleaning the inside of the cleaning tank between the second cleaning step and the drying step.
As a result, it is possible to suppress the reaction of the chemical solution (particularly, sulfuric acid and the basic chemical solution).

前記第1洗浄工程の前に、セリウムイオンを含むスラリーを用いて前記基板を研磨する研磨工程を備え、前記研磨工程と前記研磨工程との間に、研磨後の基板を乾燥させないのが望ましい。
研磨後の基板を乾燥させないことでウォーターマークの発生懸念、かつ、セリアのウェーハへの固着懸念を抑制し、セリアをより確実に基板上から除去することができる。
It is desirable that a polishing step of polishing the substrate with a slurry containing cerium ions is provided before the first cleaning step, and the polished substrate is not dried between the polishing steps and the polishing step.
By not drying the polished substrate, it is possible to suppress the concern of watermark generation and the concern of ceria sticking to the wafer, and the ceria can be removed from the substrate more reliably.

少ない工程数で、研磨後の基板を十分に洗浄できる。また、トータルでの処理時間を短縮できる。
また、セリアを用いて研磨された基板について、別途、研磨装置から取り出した基板を別置きの洗浄装置で洗浄することなく、同一の研磨装置内で最後まで乾燥させることなく洗浄できるため、洗浄過程において基板が乾燥してしまうことによるウォーターマーク発生懸念を抑制しつつも、セリアを用いて研磨され、かつ、セリアが付着した研磨後の基板を洗浄しセリアをより確実に除去することができる。
さらに、セリウム砥粒は基板との電気的に引き合う力が強く、基板に付着したセリアは単にアルカリ性の薬液や界面活性剤を含む洗浄液で洗浄するだけでは除去できないことが、本発明者らの検討で判明した。本発明によれば、こうしたセリアをより確実に基板上から除去することができる。
The polished substrate can be sufficiently cleaned with a small number of steps. In addition, the total processing time can be shortened.
In addition, for a substrate polished with ceria, the substrate taken out from the polishing device can be cleaned without being separately cleaned with a separate cleaning device, and without being dried to the end in the same polishing device, so that the cleaning process can be performed. In this case, it is possible to more reliably remove the ceria by cleaning the polished substrate which is polished with ceria and has ceria adhered to it, while suppressing the concern that water marks are generated due to the substrate drying.
Furthermore, the present inventors have studied that cerium abrasive grains have a strong electrical attraction to the substrate, and ceria adhering to the substrate cannot be removed by simply cleaning with a cleaning solution containing an alkaline chemical solution or a surfactant. It turned out in. According to the present invention, such ceria can be more reliably removed from the substrate.

基板処理装置の概略構成の一例を模式的に示す図。The figure which shows an example of the schematic structure of the substrate processing apparatus schematically. 洗浄装置31〜34およびその関連部の一例を詳細に示す図。The figure which shows in detail an example of a cleaning apparatus 31-34 and its related part. 基板処理装置の処理動作の一例を示すフローチャート。The flowchart which shows an example of the processing operation of a board processing apparatus. 研磨後および処理後の基板W1,W3,W4におけるディフェクト数を示す表。The table which shows the defect number in the substrate W1, W3, W4 after polishing and processing. 研磨後および処理後の基板W1〜W4におけるセリウムイオン濃度[atms/cm2]を示す表。The table which shows the cerium ion concentration [atms / cm 2 ] in the substrate W1 to W4 after polishing and processing. 処理後の基板W2〜W4におけるセリウムイオン濃度[atms/cm2]を示す表。A table showing the cerium ion concentration [atms / cm 2 ] in the substrates W2 to W4 after the treatment. 研磨後および処理後の基板W1〜W4における硫黄イオン濃度[atms/cm2]を示す表。The table which shows the sulfur ion concentration [atms / cm 2 ] in the substrate W1 to W4 after polishing and processing. 処理後の基板W11および処理後の基板W12,W13におけるディフェクト数(左側の縦軸)および基板W11を基準とする除去率(右側の縦軸)を示す図。The figure which shows the number of defects (the vertical axis on the left side) and the removal rate (the vertical axis on the right side) based on the substrate W11 in the substrate W11 after processing and the substrates W12, W13 after processing. 初めのAPM洗浄後に、乾燥を行った場合と乾燥を行わない場合のディフェクト数および除去率を示す図。The figure which shows the defect number and removal rate in the case of drying and the case of not drying after the first APM washing. 基板処理装置内に設けられ、APM洗浄、SPM洗浄および乾燥を行う洗浄装置を模式的に示す図。The figure which shows schematically the cleaning apparatus provided in the substrate processing apparatus and performing APM cleaning, SPM cleaning, and drying. 図9の洗浄装置にて基板の洗浄を行うプロセスを行う様子を順に示す図。It is a figure which shows the state of performing the process of cleaning a substrate by the cleaning apparatus of FIG. 9 in order. 図9の洗浄装置にて基板の洗浄を行うプロセスを行う様子を順に示す図。It is a figure which shows the state of performing the process of cleaning a substrate by the cleaning apparatus of FIG. 9 in order. 図9の洗浄装置にて基板の洗浄を行うプロセスを行う様子を順に示す図。It is a figure which shows the state of performing the process of cleaning a substrate by the cleaning apparatus of FIG. 9 in order. 図9の洗浄装置にて基板の洗浄を行うプロセスを行う様子を順に示す図。It is a figure which shows the state of performing the process of cleaning a substrate by the cleaning apparatus of FIG. 9 in order. 図9の洗浄装置にて基板の洗浄を行うプロセスを行う様子を順に示す図。It is a figure which shows the state of performing the process of cleaning a substrate by the cleaning apparatus of FIG. 9 in order. 図9の洗浄装置にて基板の洗浄を行うプロセスを行う様子を順に示す図。It is a figure which shows the state of performing the process of cleaning a substrate by the cleaning apparatus of FIG. 9 in order.

以下、本発明に係る実施形態について、図面を参照しながら具体的に説明する。 Hereinafter, embodiments according to the present invention will be specifically described with reference to the drawings.

図1は、基板処理装置の概略構成の一例を模式的に示す図であり、基板処理装置の概略上面図と考えてもよい。基板処理装置は、ロードポート1と、1または複数の研磨部2と、複数の洗浄装置31〜33と、1または複数の乾燥装置4と、搬送部5〜9と、基板ステーション10,11と、制御部12とを備えている。ロードポート1以外の各部は装置13内に収納され得る。 FIG. 1 is a diagram schematically showing an example of a schematic configuration of a substrate processing apparatus, and may be considered as a schematic top view of the substrate processing apparatus. The board processing devices include a load port 1, one or more polishing units 2, a plurality of cleaning devices 31 to 33, one or a plurality of drying devices 4, transfer units 5 to 9, and substrate stations 10 and 11. , The control unit 12 is provided. Each part other than the load port 1 can be housed in the device 13.

ロードポート1は装置13の短辺に隣接して配置され、半導体ウエハなどの基板をストックする基板カセットが載置される。 The load port 1 is arranged adjacent to the short side of the apparatus 13, and a substrate cassette for stocking a substrate such as a semiconductor wafer is placed on the load port 1.

研磨部2は装置13の長辺に沿って並置され、例えばセリア(CeO2)を含むスラリーを用いて基板を研磨する。研磨後の基板にはスラリーが残存することもある。なお、研磨部2は基板の表面を研磨することを想定しているが、基板のベベルを研磨するものであってもよい。 The polishing unit 2 is juxtaposed along the long side of the apparatus 13, and the substrate is polished using , for example, a slurry containing ceria (CeO 2). Slurry may remain on the polished substrate. Although the polishing unit 2 is supposed to polish the surface of the substrate, it may be used to polish the bevel of the substrate.

ここで、スラリー(研磨剤)中の酸化セリウムの平均粒径(D50)は、通常、0.5〜1.5μmとされる。また、酸化セリウムの含有量は、基板用研磨剤全量に対して1〜10質量%である。酸化セリウム砥粒は、従来のシリカ砥粒に比べ研磨特性は優れるものの、比重が大きいため沈降しやすいとの特性がある。パターン凹部の研磨速度が凸部の研磨速度に比べて十分小さい研磨特性が得られる範囲に界面活性剤の添加量及びpHを調整する必要があり、そのため粘度を1.0〜1.4mPa・sの範囲内にし、かつ、界面活性剤の添加量とともに粘度が増加するので、この点も考慮しながら、パターン依存性の少ない平坦化特性を実現するため、研磨時に、界面活性剤を添加した後の研磨剤のpHを5.5〜9として、シリコン酸化膜の研磨速度とシリコン窒化膜の研磨速度の選択比を大きくすることが望ましい。 Here, the average particle size (D 50 ) of cerium oxide in the slurry (abrasive) is usually 0.5 to 1.5 μm. The content of cerium oxide is 1 to 10% by mass with respect to the total amount of the abrasive for the substrate. Although cerium oxide abrasive grains have excellent polishing characteristics as compared with conventional silica abrasive grains, they have a characteristic that they tend to settle because of their high specific gravity. It is necessary to adjust the addition amount and pH of the surfactant within the range where the polishing speed of the concave part of the pattern is sufficiently smaller than the polishing speed of the convex part, and therefore the viscosity is 1.0 to 1.4 mPa · s. The viscosity increases with the amount of the surface active agent added, and the viscosity increases with the amount of the surface active agent added. It is desirable to set the pH of the polishing agent to 5.5 to 9 and increase the selection ratio between the polishing rate of the silicon oxide film and the polishing rate of the silicon nitride film.

洗浄装置31〜33は、装置13における研磨部2とは反対側の長辺に沿って並置され、研磨後の基板を洗浄する。なお、研磨後の基板を乾燥させると、基板に付着した残渣を除去しにくくなるため、基板処理装置は、研磨部2で研磨された後、かつ、洗浄装置31〜33で洗浄される前の基板を乾燥させる機構を持たないのが望ましい。洗浄装置31〜33による洗浄については後に詳述する。 The cleaning devices 31 to 33 are juxtaposed along the long side of the device 13 opposite to the polishing portion 2, and clean the polished substrate. When the polished substrate is dried, it becomes difficult to remove the residue adhering to the substrate. Therefore, the substrate processing device is used after being polished by the polishing unit 2 and before being cleaned by the cleaning devices 31 to 33. It is desirable not to have a mechanism to dry the substrate. The cleaning by the cleaning devices 31 to 33 will be described in detail later.

乾燥装置4は洗浄装置33と隣接して配置され、洗浄後の基板を乾燥する。
搬送部5は、洗浄前の基板用ハンドと、洗浄後の基板用ハンドがあり、ロードポート1と、ロードポート1側の研磨部2と、乾燥装置4との間に配置され、ロードポート1、搬送部6および乾燥装置4にアクセスできる。搬送部5は例えば搬送ロボットであり、ロードポート1から処理前の基板を受け取って搬送部6に受け渡す。また、搬送部5は乾燥済の基板を乾燥装置4から取り出す。
The drying device 4 is arranged adjacent to the cleaning device 33 and dries the washed substrate.
The transport unit 5 has a hand for the substrate before cleaning and a hand for the substrate after cleaning, and is arranged between the load port 1, the polishing unit 2 on the load port 1 side, and the drying device 4, and the load port 1 , The transport unit 6 and the drying device 4 can be accessed. The transport unit 5 is, for example, a transport robot, and receives the unprocessed substrate from the load port 1 and delivers it to the transport unit 6. Further, the transport unit 5 takes out the dried substrate from the drying device 4.

搬送部6は研磨部2に沿って配置され、搬送部5、研磨部2および基板ステーション10にアクセスできる。搬送部6は搬送部5から基板を受け取り、研磨部2に投入する。また、搬送部6は、研磨済の基板を研磨部2から取り出し、搬送部6,7間に設けられた基板ステーション10に載置する。 The transport unit 6 is arranged along the polishing unit 2 and can access the transport unit 5, the polishing unit 2, and the substrate station 10. The transport unit 6 receives the substrate from the transport unit 5 and feeds it into the polishing unit 2. Further, the transport unit 6 takes out the polished substrate from the polishing unit 2 and places it on the substrate station 10 provided between the transport units 6 and 7.

搬送部7は、基板ステーション10および洗浄装置32,33に囲まれた領域に配置され、基板ステーション10,11、洗浄装置32,33にアクセスできる。搬送部7は、研磨されて基板ステーション10に載置された基板を取り出し、基板ステーション11に載置する。また、搬送部7は、洗浄装置32によって洗浄された基板を取り出し、洗浄装置33に投入する。 The transport unit 7 is arranged in an area surrounded by the board station 10 and the cleaning devices 32 and 33, and can access the board stations 10 and 11 and the cleaning devices 32 and 33. The transport unit 7 takes out the substrate that has been polished and placed on the substrate station 10, and places it on the substrate station 11. Further, the transport unit 7 takes out the substrate cleaned by the cleaning device 32 and puts it in the cleaning device 33.

搬送部8は洗浄装置31,32間に配置され、洗浄装置31,32および基板ステーション11にアクセスできる。搬送部8は、基板ステーション11に載置された基板を取り出し、洗浄装置31に投入する。また、搬送部8は洗浄装置31によって洗浄された基板を取り出し、洗浄装置32に投入する。なお、基板ステーション11は洗浄装置32の近辺に配置されるが、具体的な配置例は後述する。また、基板ステーション11内には、基板が乾燥してしまわないように、基板に対して純水を供給するための不図示の純水供給ノズルを設けることができる。 The transport unit 8 is arranged between the cleaning devices 31 and 32, and can access the cleaning devices 31 and 32 and the board station 11. The transport unit 8 takes out the substrate mounted on the substrate station 11 and puts it into the cleaning device 31. Further, the transport unit 8 takes out the substrate cleaned by the cleaning device 31 and puts it in the cleaning device 32. The board station 11 is arranged in the vicinity of the cleaning device 32, and a specific arrangement example will be described later. Further, in the substrate station 11, a pure water supply nozzle (not shown) for supplying pure water to the substrate can be provided so that the substrate does not dry out.

搬送部9は洗浄装置33と乾燥装置4との間に配置され、これらにアクセスできる。搬送部9は、洗浄装置33によって洗浄された基板を取り出し、乾燥装置4に投入する。 The transport unit 9 is arranged between the cleaning device 33 and the drying device 4, and can access them. The transport unit 9 takes out the substrate cleaned by the cleaning device 33 and puts it in the drying device 4.

制御部12は基板処理装置における各部の制御を行う。例えば、制御部12はプロセッサであり、所定のプログラムを実行することによって、研磨部2、洗浄装置31〜33、乾燥装置4、搬送部5〜9の動作を制御する。 The control unit 12 controls each unit in the substrate processing apparatus. For example, the control unit 12 is a processor, and controls the operations of the polishing unit 2, the cleaning devices 31 to 33, the drying device 4, and the transport units 5 to 9 by executing a predetermined program.

この基板処理装置によって基板は次のように処理される。まず、ロードポート1に載置された処理前の基板が、搬送部5によって搬送部6に受け渡される。搬送部6はいずれかの研磨部2に基板を投入し、その研磨部2によって基板が研磨される。研磨後の基板は搬送部6によって基板ステーション10に載置される。 The substrate is processed by this substrate processing apparatus as follows. First, the unprocessed substrate mounted on the load port 1 is delivered to the transport unit 6 by the transport unit 5. The transport unit 6 puts the substrate into one of the polishing units 2, and the polishing unit 2 polishes the substrate. The polished substrate is placed on the substrate station 10 by the transport unit 6.

次いで、搬送部7は基板ステーション10に載置された基板を基板ステーション11を介して搬送部8に受け渡す。搬送部8は基板を洗浄装置31に投入し、洗浄装置31によって基板が洗浄される。洗浄後の基板は搬送部8によって洗浄装置32に投入され、洗浄装置32によって基板が洗浄される。洗浄後の基板は搬送部7によって洗浄装置33に投入され、洗浄装置33によって基板が洗浄される。 Next, the transfer unit 7 transfers the substrate mounted on the substrate station 10 to the transfer unit 8 via the substrate station 11. The transport unit 8 puts the substrate into the cleaning device 31, and the cleaning device 31 cleans the substrate. The washed substrate is put into the cleaning device 32 by the transport unit 8, and the substrate is cleaned by the cleaning device 32. The washed substrate is put into the cleaning device 33 by the transport unit 7, and the substrate is cleaned by the cleaning device 33.

洗浄後の基板は搬送部9によって乾燥装置4に投入され、乾燥装置4によって基板が乾燥される。乾燥後の基板は搬送部5によって取り出される。 The washed substrate is put into the drying device 4 by the transport unit 9, and the substrate is dried by the drying device 4. The dried substrate is taken out by the transport unit 5.

洗浄液の廃液は、それぞれのチャンバーから独立された配管より外部へ排出されることで、他の薬液の雰囲気がチャンバー内に来ることはない。 The waste liquid of the cleaning liquid is discharged to the outside through a pipe independent of each chamber, so that the atmosphere of other chemical liquids does not come into the chamber.

図2は、洗浄装置31〜34およびその関連部の一例を詳細に示す図であり、基板処理装置の概略正面図と考えてもよい。 FIG. 2 is a diagram showing in detail an example of the cleaning apparatus 31 to 34 and related parts thereof, and may be considered as a schematic front view of the substrate processing apparatus.

例えば2台の洗浄装置31が上下に並んで配置される。洗浄装置31は、搬送部8側に開口が設けられた筐体31aと、この開口を開閉可能なシャッタ31bと、筐体31a内に収納された洗浄部31cとを有する。本洗浄部31cは、アンモニア水と過酸化水素水の混合液を用いた洗浄として、APM(Ammonium hydrogen-Peroxide Mixture)洗浄を行う。洗浄部31cは、APM洗浄として混合液を基板に供給するのみでもよいが、混合液を供給しつつロール型スポンジなどの洗浄部材を接触させて物理的な洗浄(スクラブ洗浄)を行ってもよい。筐体31aはアンモニア水や過酸化水素水に対する耐性が高いのが望ましい。また、筐体31a内に独立した排気機構(不図示)が設けられるのが望ましい。 For example, two cleaning devices 31 are arranged side by side. The cleaning device 31 has a housing 31a having an opening on the transport unit 8 side, a shutter 31b capable of opening and closing the opening, and a cleaning unit 31c housed in the housing 31a. The main cleaning unit 31c performs APM (Ammonium hydrogen-Peroxide Mixture) cleaning as cleaning using a mixed solution of ammonium water and hydrogen peroxide solution. The cleaning unit 31c may only supply the mixed solution to the substrate as APM cleaning, but may perform physical cleaning (scrub cleaning) by contacting a cleaning member such as a roll type sponge while supplying the mixed solution. .. It is desirable that the housing 31a has high resistance to ammonia water and hydrogen peroxide water. Further, it is desirable that an independent exhaust mechanism (not shown) is provided in the housing 31a.

例えば2台の洗浄装置32が上下に並んで配置される。洗浄装置32は、搬送部8側および搬送部7側に開口が設けられた筐体32aと、これらの開口を開閉可能なシャッタ32bと、筐体32a内に収納された洗浄部32cとを有する。本洗浄部32cは、硫酸と過酸化水素水の混合液を用いた洗浄として、SPM(Sulfuric-acid and hydrogen-Peroxide mixture)洗浄を行う。筐体32aは硫酸や過酸化水素水に対する耐性が高いのが望ましい。また、筐体32a内に独立した排気機構(不図示)が設けられるのが望ましい。そして、2台の洗浄装置32の間に基板ステーション11が設けられてもよい。 For example, two cleaning devices 32 are arranged side by side. The cleaning device 32 has a housing 32a having openings on the transport unit 8 side and the transport unit 7 side, a shutter 32b capable of opening and closing these openings, and a cleaning unit 32c housed in the housing 32a. .. The main cleaning unit 32c performs SPM (Sulfuric-acid and hydrogen-Peroxide mixture) cleaning as cleaning using a mixed solution of sulfuric acid and hydrogen peroxide solution. It is desirable that the housing 32a has high resistance to sulfuric acid and hydrogen peroxide solution. Further, it is desirable that an independent exhaust mechanism (not shown) is provided in the housing 32a. Then, the board station 11 may be provided between the two cleaning devices 32.

例えば2台の洗浄装置33が上下に並んで配置される。洗浄装置33は、搬送部7側および搬送部9側に開口が設けられた筐体33aと、これらの開口を開閉可能なシャッタ33bと、筐体33a内に収納された洗浄部33cとを有する。本洗浄部33cはアンモニア水と過酸化水素水の混合液を用いた洗浄として、APM洗浄を行う。洗浄部33cは、APM洗浄として混合液を基板に供給するのみでもよいが、混合液を供給しつつペン型スポンジなどの洗浄部材で物理的な洗浄(スクラブ洗浄)を行ってもよいし、APM洗浄後に2流体ジェット洗浄を行ってもよい。筐体33aはアンモニア水や過酸化水素水に対する耐性が高い材料、例えばPVC材が望ましい。また、筐体33a内に独立した排気機構(不図示)が設けられるのが望ましい。 For example, two cleaning devices 33 are arranged side by side. The cleaning device 33 has a housing 33a provided with openings on the transport unit 7 side and the transport unit 9 side, a shutter 33b capable of opening and closing these openings, and a cleaning unit 33c housed in the housing 33a. .. The main cleaning unit 33c performs APM cleaning as cleaning using a mixed solution of ammonia water and hydrogen peroxide water. The cleaning unit 33c may only supply the mixed solution to the substrate as APM cleaning, but may perform physical cleaning (scrub cleaning) with a cleaning member such as a pen-shaped sponge while supplying the mixed solution, or APM. Two-fluid jet cleaning may be performed after cleaning. The housing 33a is preferably made of a material having high resistance to aqueous ammonia or hydrogen peroxide, for example, a PVC material. Further, it is desirable that an independent exhaust mechanism (not shown) is provided in the housing 33a.

例えば2台の乾燥装置4が上下に並んで配置される。乾燥装置4は、搬送部9側および搬送部5(図1参照)側に開口が設けられた筐体4aと、これらの開口を開閉可能なシャッタ4bと、筐体4a内に収納された乾燥部4cとを有する。本乾燥部4cは例えば基板のSRD(Spin Rinse Dry)乾燥を行う。また、筐体4a内に独立した排気機構(不図示)が設けられるのが望ましい。 For example, two drying devices 4 are arranged side by side. The drying device 4 includes a housing 4a having openings on the transport unit 9 side and the transport unit 5 (see FIG. 1) side, a shutter 4b capable of opening and closing these openings, and a drying unit housed in the housing 4a. It has a portion 4c. The drying unit 4c performs, for example, SRD (Spin Rinse Dry) drying of the substrate. Further, it is desirable that an independent exhaust mechanism (not shown) is provided in the housing 4a.

搬送部7は例えば搬送ロボットであり、下ハンド7aおよび上ハンド7bを有する。下ハンド7aは相対的に汚染度が高い基板を搬送し、上ハンド7bは相対的に汚染度が低い基板を搬送する。具体的には、下ハンド7aは、研磨部2によって研磨されて基板ステーション10に載置された未洗浄の基板を取り出し、基板ステーション11に載置する。また、上ハンド7bは、洗浄装置32のいずれかによって洗浄された基板を取り出し、洗浄装置33のいずれかに投入する。 The transport unit 7 is, for example, a transport robot and has a lower hand 7a and an upper hand 7b. The lower hand 7a conveys a substrate having a relatively high degree of contamination, and the upper hand 7b conveys a substrate having a relatively low degree of contamination. Specifically, the lower hand 7a takes out an unwashed substrate that has been polished by the polishing unit 2 and placed on the substrate station 10 and places it on the substrate station 11. Further, the upper hand 7b takes out the substrate cleaned by any of the cleaning devices 32 and puts it in any of the cleaning devices 33.

搬送部8は例えば搬送ロボットであり、下ハンド8aおよび上ハンド8bを有する。下ハンド8aは相対的に汚染度が高い基板を搬送し、上ハンド8bは相対的に汚染度が低い基板を搬送する。具体的には、下ハンド8aは、基板ステーション11に載置された未洗浄の基板を取り出し、洗浄装置31のいずれかに投入する。また、上ハンド8bは、洗浄装置31のいずれかによって洗浄された基板を取り出し、洗浄装置32のいずれかに投入する。 The transport unit 8 is, for example, a transport robot, and has a lower hand 8a and an upper hand 8b. The lower hand 8a conveys a substrate having a relatively high degree of contamination, and the upper hand 8b conveys a substrate having a relatively low degree of contamination. Specifically, the lower hand 8a takes out the uncleaned substrate placed on the substrate station 11 and puts it in any of the cleaning devices 31. Further, the upper hand 8b takes out the substrate cleaned by any of the cleaning devices 31 and puts it in any of the cleaning devices 32.

搬送部9は例えば搬送ロボットであるが、洗浄済の基板を搬送するため、1つのハンド9aを有していればよい。ハンド9aは、洗浄装置33のいずれかによって洗浄された基板を取り出し、乾燥装置4のいずれかに投入する。 The transport unit 9 is, for example, a transport robot, but it suffices to have one hand 9a in order to transport the cleaned substrate. The hand 9a takes out the substrate cleaned by any of the cleaning devices 33 and puts it in any of the drying devices 4.

また、高温APM供給源21、過酸化水素供給源22、高温硫酸供給源23および高温純水供給源24が設けられる。これらは装置13の外部にあってもよい。高温APM供給源21は室温〜80℃程度のAPMを洗浄装置31,33に供給する。過酸化水素供給源22は室温程度の過酸化水素水を洗浄装置32に供給する。高温硫酸供給源23は室温〜80℃程度の硫酸を洗浄装置32に供給する。高温純水供給源24は75〜95℃程度の純水を洗浄装置32に供給することができる。 Further, a high temperature APM supply source 21, a hydrogen peroxide supply source 22, a high temperature sulfuric acid supply source 23, and a high temperature pure water supply source 24 are provided. These may be outside the device 13. The high temperature APM supply source 21 supplies APM at room temperature to about 80 ° C. to the cleaning devices 31 and 33. The hydrogen peroxide supply source 22 supplies hydrogen peroxide solution at room temperature to the cleaning device 32. The high temperature sulfuric acid supply source 23 supplies sulfuric acid at room temperature to about 80 ° C. to the cleaning device 32. The high temperature pure water supply source 24 can supply pure water at about 75 to 95 ° C. to the cleaning device 32.

あるいは、赤外線ヒーター等の外部からの熱供給源を、洗浄装置31〜33のそれぞれの内部に設けて、洗浄装置31〜33の内部を外部からの供給熱で高温にしてこれを維持することで、高温APM供給源21、高温硫酸供給源23および高温純水供給源24からそれぞれ各洗浄装置31〜33に供給される、APM、硫酸および純水の温度をより低い温度、例えば、室温〜40℃程度の温度にすることもできる。このように構成すれば、それぞれの供給源から各洗浄装置31〜33に接続される各配管及び配管継目といった部材の耐薬品性をそれほど確保せずとも使用することができるので装置構成上は有利となる。 Alternatively, an external heat supply source such as an infrared heater is provided inside each of the cleaning devices 31 to 33, and the inside of the cleaning devices 31 to 33 is heated to a high temperature by the heat supplied from the outside to maintain this. The temperature of APM, sulfuric acid and pure water supplied to each cleaning device 31 to 33 from the high temperature APM supply source 21, the high temperature sulfuric acid supply source 23 and the high temperature pure water supply source 24 is set to a lower temperature, for example, room temperature to 40. It can also be set to a temperature of about ° C. With such a configuration, it is possible to use the members such as pipes and pipe joints connected to each cleaning device 31 to 33 from each supply source without ensuring the chemical resistance so much, which is advantageous in terms of device configuration. Will be.

なお、図2に示す基板処理装置は一例にすぎず、洗浄装置31〜33および乾燥装置4の数や配置位置、搬送部7〜9および基板ステーション10,11の構成は適宜設計すればよい。また、洗浄部31c,33cはアンモニア水を用いた洗浄を行うこととしたが、他の塩基性(アルカリ性)の薬液と過酸化水素水を用いて洗浄を行ってもよい。 The substrate processing apparatus shown in FIG. 2 is only an example, and the number and arrangement positions of the cleaning apparatus 31 to 33 and the drying apparatus 4, and the configurations of the transport units 7 to 9 and the substrate stations 10 and 11 may be appropriately designed. Further, although the cleaning units 31c and 33c are to be washed with ammonia water, they may be washed with another basic (alkaline) chemical solution and hydrogen peroxide solution.

図3は、基板処理装置の処理動作の一例を示すフローチャートである。まず研磨部2が基板を研磨する(ステップS1)。基板研磨の際にセリアを含むスラリーが用いられる場合、研磨後の基板上にはセリアが残存していることがある。より具体的には、セリウム濃度が1.0×1010atms/cm2以上となるセリウムイオンが基板の表面および/または裏面に付着することがあり、そのような基板を洗浄することとなる。 FIG. 3 is a flowchart showing an example of the processing operation of the substrate processing apparatus. First, the polishing unit 2 polishes the substrate (step S1). When a slurry containing ceria is used for polishing the substrate, ceria may remain on the polished substrate. More specifically, cerium ions having a cerium concentration of 1.0 × 10 10 atms / cm 2 or more may adhere to the front surface and / or the back surface of the substrate, and such a substrate is washed.

続いて、搬送部6〜9は、研磨後の基板を乾燥させることなく、基板を洗浄装置31のいずれかに投入する(ステップS2)。より具体的には、搬送部6は研磨部2から基板を取り出し、基板ステーション10に載置する。その後、搬送部7における下ハンド7aは基板ステーション10から基板を取り出し、基板ステーション11に載置する。次いで、搬送部8における下ハンド8aが基板ステーション11から基板を取り出すとともに、洗浄装置31におけるシャッタ31bが開き、基板は筐体31aの開口を通って洗浄部31cに受け渡される。その後、シャッタ31bが閉じる。 Subsequently, the transport units 6 to 9 put the substrate into one of the cleaning devices 31 without drying the polished substrate (step S2). More specifically, the transport unit 6 takes out the substrate from the polishing unit 2 and places it on the substrate station 10. After that, the lower hand 7a in the transport unit 7 takes out the substrate from the substrate station 10 and places it on the substrate station 11. Next, the lower hand 8a in the transport unit 8 takes out the substrate from the substrate station 11, the shutter 31b in the cleaning device 31 opens, and the substrate is handed over to the cleaning unit 31c through the opening of the housing 31a. After that, the shutter 31b closes.

基板の乾燥を防ぐため、搬送部6〜8による基板搬送中あるいは基板ステーション10において、純水などの液体シャワーを基板に浴びせるのが望ましい。特に、搬送部6,7や基板ステーション10上に基板が滞在する時間が長いため、搬送部6,7による基板搬送中の基板や基板ステーション10上の基板にシャワーを浴びせる液体供給機構(不図示)を設けるのが有効である。一方、搬送部8など基板の滞在時間が短い場合には、なくてもよい。 In order to prevent the substrate from drying, it is desirable to shower the substrate with a liquid shower such as pure water during the transfer of the substrate by the transport units 6 to 8 or at the substrate station 10. In particular, since the substrate stays on the transport units 6 and 7 and the substrate station 10 for a long time, the liquid supply mechanism (not shown) for showering the substrate being transported by the transport units 6 and 7 and the substrate on the substrate station 10 with a shower. ) Is effective. On the other hand, if the staying time of the substrate such as the transport unit 8 is short, it may not be necessary.

洗浄装置31は基板をスプレーノズルよりAPMを吐出し洗浄する(ステップS3)。この間、洗浄装置31におけるシャッタ31bは閉じている。これにより、洗浄装置31で用いられるAPMが他の装置、特に洗浄装置32や乾燥装置4に混入するのを抑制できる。なお、このAPM洗浄は粗洗浄であり、場合によっては省略可能であるが、取れにくいパーティクルが存在する場合は、ロールやペンシル洗浄、あるいは2流体ジェットを用いて処理も可能である。 The cleaning device 31 discharges APM from the spray nozzle to clean the substrate (step S3). During this time, the shutter 31b in the cleaning device 31 is closed. As a result, it is possible to prevent the APM used in the cleaning device 31 from being mixed with other devices, particularly the cleaning device 32 and the drying device 4. This APM cleaning is a rough cleaning and can be omitted in some cases, but if there are particles that are difficult to remove, it can be treated by rolling or pencil cleaning or by using a two-fluid jet.

洗浄装置31による洗浄が終了すると、搬送部8は基板を洗浄装置31から洗浄装置32のいずれかに搬送する。より具体的には、洗浄が終了すると、洗浄装置31におけるシャッタ31bが開き、搬送部8における上ハンド8bが基板を受け取り、その後シャッタ31bが閉じる。そして、洗浄装置32における搬送部8側のシャッタ32bが開き、筐体32aの開口を通って洗浄部32cに受け渡され、その後シャッタ32bが閉じる。 When the cleaning by the cleaning device 31 is completed, the transport unit 8 transports the substrate from the cleaning device 31 to any of the cleaning devices 32. More specifically, when the cleaning is completed, the shutter 31b in the cleaning device 31 opens, the upper hand 8b in the transport unit 8 receives the substrate, and then the shutter 31b closes. Then, the shutter 32b on the transport unit 8 side of the cleaning device 32 opens, is delivered to the cleaning unit 32c through the opening of the housing 32a, and then the shutter 32b closes.

そして、洗浄装置32は基板をスプレーノズルよりSPMを吐出し洗浄する(ステップS4)。この間、洗浄装置32におけるシャッタ32bは閉じている。これにより、洗浄装置32で用いられるSPMが他の装置、特に洗浄装置31,33や乾燥装置4に混入するのを抑制できる。SPM洗浄によって、パーティクル、スラリーに含まれるセリア、有機物などの残渣が溶解し、その多くを除去できる。特に、研磨後の基板が乾燥しないように搬送することで効率よく残渣を除去できる。 Then, the cleaning device 32 discharges SPM from the spray nozzle to clean the substrate (step S4). During this time, the shutter 32b in the cleaning device 32 is closed. As a result, it is possible to prevent the SPM used in the cleaning device 32 from being mixed with other devices, particularly the cleaning devices 31 and 33 and the drying device 4. By SPM cleaning, residues such as particles, ceria and organic substances contained in the slurry are dissolved, and most of them can be removed. In particular, the residue can be efficiently removed by transporting the polished substrate so that it does not dry out.

なお、洗浄装置32の筐体32aから外部に硫酸が出ないよう、洗浄装置32はSPM洗浄を行った後に、純水を用いて基板を洗浄するのが望ましい。ただし、その場合でも、SPM洗浄後の基板には、硫酸に起因する硫黄成分が残存し得る。 It is desirable that the cleaning device 32 cleans the substrate with pure water after performing SPM cleaning so that sulfuric acid does not come out from the housing 32a of the cleaning device 32. However, even in that case, the sulfur component due to sulfuric acid may remain on the substrate after SPM cleaning.

洗浄装置32による洗浄が終了すると、搬送部7は基板を洗浄装置32から洗浄装置33のいずれかに搬送する。より具体的には、洗浄が終了すると、洗浄装置32における搬送部7側のシャッタ32bが開き、搬送部7における上ハンド7bが基板を受け取り、その後シャッタ32bが閉じる。そして、洗浄装置33における搬送部7側のシャッタ33bが開き、筐体33aの開口を通って洗浄部33cに受け渡され、その後シャッタ33bが閉じる。 When the cleaning by the cleaning device 32 is completed, the transport unit 7 transports the substrate from the cleaning device 32 to any of the cleaning devices 33. More specifically, when the cleaning is completed, the shutter 32b on the transport unit 7 side in the cleaning device 32 opens, the upper hand 7b in the transport unit 7 receives the substrate, and then the shutter 32b closes. Then, the shutter 33b on the transport unit 7 side of the cleaning device 33 opens, is delivered to the cleaning unit 33c through the opening of the housing 33a, and then the shutter 33b closes.

そして、洗浄装置33は基板をスプレーノズルよりAPMを吐出し洗浄する(ステップS5)。この間、洗浄装置33におけるシャッタ33bは閉じている。これにより、洗浄装置33で用いられるAPMが他の装置、特に洗浄装置32や乾燥装置4に混入するのを抑制できる。APM洗浄によって硫黄成分の多くを除去できる。 Then, the cleaning device 33 discharges APM from the spray nozzle to clean the substrate (step S5). During this time, the shutter 33b in the cleaning device 33 is closed. As a result, it is possible to prevent the APM used in the cleaning device 33 from being mixed with other devices, particularly the cleaning device 32 and the drying device 4. Most of the sulfur components can be removed by APM cleaning.

洗浄装置33による洗浄が終了すると、搬送部9は基板を洗浄装置33から乾燥装置4のいずれかに搬送する。より具体的には、洗浄が終了すると、洗浄装置33における搬送部9側のシャッタ33bが開き、搬送部9におけるハンド9aが基板を受け取り、その後シャッタ33bが閉じる。そして、乾燥装置4におけるシャッタ4bが開き、筐体4aの開口を通って乾燥部4cに受け渡され、その後シャッタ4bが閉じる。 When the cleaning by the cleaning device 33 is completed, the transport unit 9 transports the substrate from the cleaning device 33 to any of the drying devices 4. More specifically, when the cleaning is completed, the shutter 33b on the transport unit 9 side of the cleaning device 33 opens, the hand 9a in the transport unit 9 receives the substrate, and then the shutter 33b closes. Then, the shutter 4b in the drying device 4 opens, is passed to the drying unit 4c through the opening of the housing 4a, and then the shutter 4b closes.

そして、乾燥装置4は基板を乾燥する(ステップS6)。乾燥装置4による乾燥が終了すると、搬送部5は基板を乾燥装置4から取り出す。より具体的には、乾燥が終了すると、乾燥装置4における搬送部5側のシャッタ4bが開き、搬送部5における洗浄後の基板用ハンドが基板を受け取り、その後シャッタ4bが閉じる。 Then, the drying device 4 dries the substrate (step S6). When the drying by the drying device 4 is completed, the transport unit 5 takes out the substrate from the drying device 4. More specifically, when the drying is completed, the shutter 4b on the transport unit 5 side of the drying device 4 opens, the washed substrate hand in the transport unit 5 receives the substrate, and then the shutter 4b closes.

このように、本実施形態では、基板処理装置内でSPM洗浄を行い、次いでAPM洗浄を行うことで、少ない工程で効率よく基板を洗浄でき、かつ、トータルでの処理時間を短縮できる。すなわち、基板処理装置内に研磨部2および洗浄装置32,33を設けることで、研磨後の基板を乾燥させずにSPM洗浄でき、スラリーに含まれるセリアなどの残渣を十分に除去できる。また、SPM洗浄後にAPM洗浄を行うことで、SPM洗浄で用いられる硫酸に起因する硫黄成分を除去できる。また、SPM洗浄を行う洗浄部32cを筐体32a内に収納し、APM洗浄を行う洗浄部31c,33cをそれぞれ筐体31a,33a内に収納することで、雰囲気を洗浄部31c〜33cどうしで互いに独立させることができ、例えばSPMの硫黄成分が他の処理チャンバーに移ることはほとんどない。 As described above, in the present embodiment, by performing SPM cleaning in the substrate processing apparatus and then performing APM cleaning, the substrate can be efficiently cleaned with a small number of steps, and the total processing time can be shortened. That is, by providing the polishing unit 2 and the cleaning devices 32 and 33 in the substrate processing apparatus, SPM cleaning can be performed without drying the polished substrate, and the residue such as ceria contained in the slurry can be sufficiently removed. Further, by performing APM cleaning after SPM cleaning, the sulfur component caused by sulfuric acid used in SPM cleaning can be removed. Further, by storing the cleaning unit 32c for SPM cleaning in the housing 32a and the cleaning units 31c and 33c for APM cleaning in the housings 31a and 33a, respectively, the atmosphere can be created between the cleaning units 31c to 33c. They can be made independent of each other, for example, the sulfur component of SPM is hardly transferred to other processing chambers.

[実験1]
SPM洗浄の後にAPM洗浄を行うことが有効であることを確認するために、4枚の基板W1〜W4に対して次の処理を行った。
[Experiment 1]
In order to confirm that it is effective to perform APM cleaning after SPM cleaning, the following treatment was performed on the four substrates W1 to W4.

(1)基板W1
セリアを含むスラリーを用い、約70hPaの圧力で60秒間、基板W1の表面を研磨した。次いで、純水を供給しつつ、ロール型スポンジを用いて60秒間、物理洗浄を行った。このように、基板W1は研磨後にSPM洗浄もAPM洗浄も行われていない。
(1) Substrate W1
The surface of the substrate W1 was polished for 60 seconds at a pressure of about 70 hPa using a slurry containing ceria. Then, while supplying pure water, physical cleaning was performed for 60 seconds using a roll-type sponge. As described above, the substrate W1 is not subjected to SPM cleaning or APM cleaning after polishing.

(2)基板W2
上記(1)と同様の処理を行った後、基板W2を回転させつつ、硫酸(濃度96%、高温)と過酸化水素水(濃度30%、室温)の混合液を60秒間供給して基板W2を洗浄した。このように、基板W2は研磨後にSPM洗浄のみが行われた。
(2) Substrate W2
After performing the same treatment as in (1) above, while rotating the substrate W2, a mixed solution of sulfuric acid (concentration 96%, high temperature) and hydrogen peroxide solution (concentration 30%, room temperature) is supplied for 60 seconds to the substrate. W2 was washed. As described above, the substrate W2 was only cleaned by SPM after polishing.

(3)基板W3
上記(2)と同様の処理を行った後、基板W3を回転させつつ、アンモニア水、過酸化水素水および純水の混合物を30秒間供給して基板W3を洗浄した。このように、基板W3は研磨後にSPM洗浄および引き続いてAPM洗浄が行われた。
(3) Substrate W3
After performing the same treatment as in (2) above, the substrate W3 was washed by supplying a mixture of ammonia water, hydrogen peroxide solution and pure water for 30 seconds while rotating the substrate W3. As described above, the substrate W3 was subjected to SPM cleaning and subsequently APM cleaning after polishing.

(4)基板W4
上記(1)と同様の処理を行った後、基板W4を回転させつつ、アンモニア水、過酸化水素水および純水の混合物を60秒間供給して基板W4を洗浄した。このように、基板W4は研磨後にAPM洗浄のみが行われた。
(4) Substrate W4
After performing the same treatment as in (1) above, the substrate W4 was washed by supplying a mixture of ammonia water, hydrogen peroxide solution and pure water for 60 seconds while rotating the substrate W4. As described above, the substrate W4 was only APM washed after polishing.

図4は、研磨後および処理後の基板W1,W3,W4におけるディフェクト数を示す表である。図示のように、研磨後の基板W1,W3,W4には8,000〜10,000程度のディフェクトが存在した。APM洗浄のみを行った基板W4では、処理後のディフェクト数は約8,500であり6%程度しかディフェクトは減っていない。これに対し、SPM洗浄およびAPM洗浄を行った基板W3では、処理後のディフェクト数は約2,500であり75%程度のディフェクトが減らすことができた。 FIG. 4 is a table showing the number of defects in the substrates W1, W3, and W4 after polishing and processing. As shown in the figure, the polished substrates W1, W3, and W4 had a defect of about 8,000 to 10,000. In the substrate W4 that has been subjected to only APM cleaning, the number of defects after processing is about 8,500, and the defects are reduced by only about 6%. On the other hand, in the substrate W3 subjected to SPM cleaning and APM cleaning, the number of defects after the treatment was about 2,500, and the defects could be reduced by about 75%.

図5Aは、研磨後および処理後の基板W1〜W4におけるセリウムイオン濃度[atms/cm2]を示す表である。同図は基板W1〜W4のそれぞれにおける座標(0,0)、(0,120)、(120,0)、(0,−120)、(−120,0)の5点をTXRF(Total Reflection X-ray Fluorescence)法によって測定した結果である。 FIG. 5A is a table showing the cerium ion concentration [atms / cm 2 ] in the substrates W1 to W4 after polishing and treatment. In the figure, the five points of coordinates (0,0), (0,120), (120,0), (0, -120), and (-120,0) on the substrates W1 to W4 are TXRF (Total Reflection). It is the result measured by the X-ray Fluorescence) method.

研磨後の基板W1のセリウムイオン濃度は8*1011[atms/cm2]程度であった。APM洗浄のみを行った基板W4ではセリウムイオン濃度が3*1010[atms/cm2]程度であったのに対し、SPM洗浄を行った基板W2,W3では検出限界(2*1010[atms/cm2])以下まで減らすことができた。 The cerium ion concentration of the substrate W1 after polishing was about 8 * 10 11 [atms / cm 2]. The cerium ion concentration was about 3 * 10 10 [atms / cm 2 ] on the substrate W4 that was only APM-cleaned, whereas the detection limit (2 * 10 10 [atms / cm 2] was on the substrates W2 and W3 that were SPM-cleaned. / Cm 2 ]) It was possible to reduce it to the following.

図5Bは、処理後の基板W2〜W4におけるセリウムイオン濃度[atms/cm2]を示す表である。同図はICP−MS(Inductively Coupled Plasma Mass Spectrometry)法による測定結果である。ICP−MS法による測定においても、APM洗浄のみを行った基板W4ではセリウムイオン濃度は5.7*1010[atms/cm2]程度であったのに対し、SPM洗浄を行った基板W2,W3では検出限界(5*109[atms/cm2])以下まで減らすことができた。 FIG. 5B is a table showing the cerium ion concentration [atms / cm 2 ] in the substrates W2 to W4 after the treatment. The figure shows the measurement results by the ICP-MS (Inductively Coupled Plasma Mass Spectrometry) method. In the measurement by the ICP-MS method, the cerium ion concentration was about 5.7 * 10 10 [atms / cm 2 ] in the substrate W4 that was only APM-cleaned, whereas the substrate W2 that was SPM-cleaned was In W3 detection limit (5 * 10 9 [atms / cm 2]) could be reduced to below.

このように、セリウムイオンを除去するには、SPM洗浄が有効であることが分かる。 As described above, it can be seen that SPM cleaning is effective for removing cerium ions.

図6は、研磨後および処理後の基板W1〜W4における硫黄イオン濃度[atms/cm2]を示す表である。同図は基板W1〜W4のそれぞれにおける座標(0,0)、(0,120)、(120,0)、(0,−120)、(−120,0)の5点をTXRF(Total Reflection X-ray Fluorescence)法によって測定した結果である。 FIG. 6 is a table showing sulfur ion concentrations [atms / cm 2 ] in the substrates W1 to W4 after polishing and treatment. In the figure, the five points of coordinates (0,0), (0,120), (120,0), (0, -120), and (-120,0) on the substrates W1 to W4 are TXRF (Total Reflection). It is the result measured by the X-ray Fluorescence) method.

研磨後の基板W1の硫黄イオン濃度は5.0*1012[atms/cm2]程度であったが、SPM洗浄のみを行った基板W2では硫黄イオン濃度が3.6*1013[atms/cm2]まで上昇した。SPM洗浄を行っていない基板W4では4.6*1012[atms/cm2]程度であったことから、SPM洗浄に用いた硫酸に起因する硫黄イオンが基板W2に残留していると考えられる。そして、SPM洗浄後にAPM洗浄を行った基板W3では硫黄イオン濃度を6.4*1012[atms/cm2]程度まで減らすことができた。 The sulfur ion concentration of the substrate W1 after polishing was about 5.0 * 10 12 [atms / cm 2 ], but the sulfur ion concentration of the substrate W2 only subjected to SPM cleaning was 3.6 * 10 13 [atms / cm /]. It rose to cm 2]. Since the substrate W4 without SPM cleaning was about 4.6 * 10 12 [atms / cm 2 ], it is considered that sulfur ions caused by sulfuric acid used for SPM cleaning remain on the substrate W2. .. The sulfur ion concentration of the substrate W3 that had been APM washed after SPM washing could be reduced to about 6.4 * 10 12 [atms / cm 2].

このように、SPM洗浄に起因する硫黄イオンを除去するには、APM洗浄が有効であることが分かる。 As described above, it can be seen that APM cleaning is effective for removing sulfur ions caused by SPM cleaning.

以上から、スラリーに含まれるセリウムイオンをSPM洗浄で除去でき、かつ、SPM洗浄による硫黄イオンをAPM洗浄で除去できることが確認できた。 From the above, it was confirmed that the cerium ions contained in the slurry can be removed by SPM washing and the sulfur ions by SPM washing can be removed by APM washing.

なお、上記(2)において、SPM洗浄に代えて硫酸のみを用いた洗浄では、ディフェクトの数がそれほど減らないことを別の実験で確認できている。また、上記(2)において、アンモニア水、過酸化水素水および純水の混合物を30秒間供給した場合と60秒間供給した場合とで、大差がないことを別の実験で確認できている。 In addition, in the above (2), it has been confirmed in another experiment that the number of defects is not so reduced in the washing using only sulfuric acid instead of the SPM washing. Further, in the above (2), it has been confirmed in another experiment that there is no big difference between the case where the mixture of ammonia water, hydrogen peroxide solution and pure water is supplied for 30 seconds and the case where the mixture is supplied for 60 seconds.

[実験2]
初めにAPM洗浄を行い、続いてSPM洗浄およびAPM洗浄を行うことがさらに有効であることを確認するために、3枚の基板W11〜W13に対して次の処理を行った。
[Experiment 2]
In order to confirm that it is more effective to first perform APM cleaning and then perform SPM cleaning and APM cleaning, the following treatments were performed on the three substrates W11 to W13.

(1)基板W11
セリアを含むスラリーを用い、約70hPaの平均圧力で60秒間、基板W11の表面を研磨した。次いで、アンモニア水、過酸化水素水および純水の混合物を供給しつつ、ロール型スポンジを用いて60秒間、物理洗浄を行った。このように、基板W11は研磨後にAPM洗浄のみが行われた。
(1) Substrate W11
The surface of the substrate W11 was polished for 60 seconds at an average pressure of about 70 hPa using a slurry containing ceria. Then, while supplying a mixture of aqueous ammonia, hydrogen peroxide and pure water, physical washing was performed for 60 seconds using a roll-type sponge. As described above, the substrate W11 was only APM washed after polishing.

(2)基板W12
セリアを含むスラリーを用い、約70hPaの圧力で60秒間、基板W12の表面を研磨した。次いで、回転数50rpmで基板W12を回転させつつ、硫酸(濃度96%、高温)と過酸化水素水(濃度30%、室温)の混合液を60秒間供給して基板W12を洗浄した。その後、基板W12を回転させつつ、アンモニア水、過酸化水素水および純水の混合物を60秒間供給して基板W12を洗浄した。このように、基板W12は研磨後にSPM洗浄および引き続いてAPM洗浄が行われた。
(2) Substrate W12
The surface of the substrate W12 was polished for 60 seconds at a pressure of about 70 hPa using a slurry containing ceria. Next, while rotating the substrate W12 at a rotation speed of 50 rpm, a mixed solution of sulfuric acid (concentration 96%, high temperature) and hydrogen peroxide solution (concentration 30%, room temperature) was supplied for 60 seconds to wash the substrate W12. Then, while rotating the substrate W12, a mixture of ammonia water, hydrogen peroxide solution and pure water was supplied for 60 seconds to wash the substrate W12. As described above, the substrate W12 was subjected to SPM cleaning and subsequently APM cleaning after polishing.

(3)基板W13
セリアを含むスラリーを用い、約70hPaの平均圧力で60秒間、基板W13の表面を研磨した。次いで、アンモニア水、過酸化水素水および純水の混合物を供給しつつ、ロール型スポンジを用いて60秒間、物理洗浄を行った。その後、基板W13を回転させつつ、硫酸(濃度96%、高温)と過酸化水素水(濃度30%、室温)の混合液を60秒間供給して基板W13を洗浄した。その後、基板W13を回転させつつ、アンモニア水、過酸化水素水および純水の混合物を60秒間供給して基板W13を洗浄した。このように、基板W13は研磨後にAPM洗浄、引き続いてSPM洗浄さらに引き続いてAPM洗浄が行われた。
(3) Substrate W13
The surface of the substrate W13 was polished for 60 seconds at an average pressure of about 70 hPa using a slurry containing ceria. Then, while supplying a mixture of aqueous ammonia, hydrogen peroxide and pure water, physical washing was performed for 60 seconds using a roll-type sponge. Then, while rotating the substrate W13, a mixed solution of sulfuric acid (concentration 96%, high temperature) and hydrogen peroxide solution (concentration 30%, room temperature) was supplied for 60 seconds to wash the substrate W13. Then, while rotating the substrate W13, a mixture of ammonia water, hydrogen peroxide solution and pure water was supplied for 60 seconds to wash the substrate W13. As described above, the substrate W13 was subjected to APM cleaning after polishing, followed by SPM cleaning, and then APM cleaning.

図7は、処理後の基板W11〜W13におけるディフェクト数(棒グラフ、左側の縦軸)および基板W11を基準とする除去率(実線、右側の縦軸)を示す図である。同図の基板W12に示すように、研磨後にSPM洗浄およびAPM洗浄を行うことで、67%程度のディフェクトを除去できた。これに対し、同図の基板W13に示すように、研磨後にAPM洗浄、SPM洗浄およびAPM洗浄を行うことで、92%程度のディフェクトを除去でき、除去率を向上できた。 FIG. 7 is a diagram showing the number of defects (bar graph, vertical axis on the left side) in the substrates W11 to W13 after processing and the removal rate (solid line, vertical axis on the right side) based on the substrate W11. As shown in the substrate W12 in the figure, about 67% of defects could be removed by performing SPM cleaning and APM cleaning after polishing. On the other hand, as shown in the substrate W13 in the figure, by performing APM cleaning, SPM cleaning and APM cleaning after polishing, a defect of about 92% could be removed and the removal rate could be improved.

以上から、初めにAPM洗浄を行い、続いてSPM洗浄およびAPM洗浄を行うことがさらに有効であることが確認できた。 From the above, it was confirmed that it is more effective to perform APM cleaning first, and then SPM cleaning and APM cleaning.

図8は、初めのAPM洗浄後に乾燥を行った場合と乾燥を行わない場合のディフェクト数および除去率を示す図である。(1)APM洗浄処理、乾燥、SPM洗浄処理、APM洗浄処理の順に洗浄した場合(棒グラフ、左側の縦軸)と、(2)APM洗浄処理、SPM洗浄処理、APM洗浄処理の順に洗浄した場合(棒グラフ、右側の縦軸)との比較を示した。(1)APM洗浄処理、乾燥、SPM洗浄処理、APM洗浄処理の順に洗浄した場合と比べると、(2)APM洗浄処理、SPM洗浄処理、APM洗浄処理の順に洗浄した場合のほうが、ディフェクト数が少なく、また、除去率が高いことがわかる。すなわち、この図より、乾燥を行った場合に比べ、乾燥を行わない場合、つまり、CMP後はすべて乾燥しないでAPM洗浄、SPM洗浄およびAPM洗浄を連続処理する場合の方が洗浄効果が上回ることが確認できた。 FIG. 8 is a diagram showing the number of defects and the removal rate when drying is performed after the first APM washing and when drying is not performed. (1) When cleaning in the order of APM cleaning treatment, drying, SPM cleaning treatment, and APM cleaning treatment (bar graph, vertical axis on the left side), and (2) When cleaning in the order of APM cleaning treatment, SPM cleaning treatment, and APM cleaning treatment. A comparison with (bar graph, vertical axis on the right side) is shown. Compared to the case where (1) APM cleaning treatment, drying, SPM cleaning treatment, and APM cleaning treatment are performed in this order, the number of defects is larger when (2) APM cleaning treatment, SPM cleaning treatment, and APM cleaning treatment are performed in this order. It can be seen that the number is small and the removal rate is high. That is, from this figure, the cleaning effect is higher in the case of no drying, that is, in the case of continuous treatment of APM washing, SPM washing and APM washing without drying after CMP, as compared with the case of drying. Was confirmed.

セリウムを含むセリアは基板と電気的に引き合う力が強く、単にアルカリ性の薬液や界面活性剤を含む洗浄液での洗浄では除去が困難であるが、上述した洗浄により洗浄力が向上する。 Ceria containing cerium has a strong electric attraction to the substrate and is difficult to remove by simply cleaning with an alkaline chemical solution or a cleaning solution containing a surfactant, but the cleaning power is improved by the above-mentioned cleaning.

上述した実施形態は、APM洗浄を行う洗浄装置31,33と、SPM洗浄を行う洗浄装置32と、乾燥装置4とを別個に設けるものであったが、APM洗浄、SPM洗浄および乾燥のうちの任意の2以上の処理を1つの装置内でおこなってもよい。次に示す実施形態は、1つの装置内でAPM洗浄、SPM洗浄および乾燥を行う例を示す。 In the above-described embodiment, the cleaning devices 31 and 33 for performing APM cleaning, the cleaning device 32 for performing SPM cleaning, and the drying device 4 are separately provided, but among APM cleaning, SPM cleaning and drying. Any two or more processes may be performed in one device. The following embodiments show examples of performing APM cleaning, SPM cleaning and drying in one device.

図9は、基板処理装置内に設けられ、APM洗浄、SPM洗浄および乾燥を行う洗浄装置を模式的に示す図である。この洗浄装置は、チャック(不図示)と、アーム51と、洗浄槽洗浄シャワー52と、これらを収容する洗浄槽53とを備えている。 FIG. 9 is a diagram schematically showing a cleaning device provided in the substrate processing device and performing APM cleaning, SPM cleaning, and drying. This cleaning device includes a chuck (not shown), an arm 51, a cleaning tank cleaning shower 52, and a cleaning tank 53 accommodating them.

チャックは洗浄対象の基板周縁を保持して回転させる。 The chuck holds and rotates the peripheral edge of the substrate to be cleaned.

アーム51は揺動可能であり、具体的にはアーム51の先端が基板上方に位置する洗浄位置と、基板上方とは離れた退避位置との間を移動可能である。アーム51の先端下側には、下側を向いたAPM供給ノズル61、純水供給ノズル62、H22供給ノズル63およびSPM供給ノズル64が設けられている。アーム51の内部には、一端がAPM供給源(不図示)に接続され、他端がAPM供給ノズル61に接続された配管71が通っている。他の供給ノズルも同様の配管72〜74が通っている。なお、図9では、基板の上方からのみAPM等が供給されるように描いているが、下側にも供給ノズルを設けて基板の下側からもAPM等が供給されるようにしてもよい。 The arm 51 is swingable, and specifically, it can move between a cleaning position where the tip of the arm 51 is located above the substrate and a retracted position away from above the substrate. An APM supply nozzle 61, a pure water supply nozzle 62, an H 2 O 2 supply nozzle 63, and an SPM supply nozzle 64 facing downward are provided on the lower side of the tip of the arm 51. A pipe 71 having one end connected to an APM supply source (not shown) and the other end connected to the APM supply nozzle 61 passes through the inside of the arm 51. Similar pipes 72 to 74 pass through the other supply nozzles. In FIG. 9, the APM and the like are drawn so as to be supplied only from the upper side of the substrate, but a supply nozzle may be provided on the lower side so that the APM and the like are also supplied from the lower side of the substrate. ..

洗浄槽洗浄シャワー52は洗浄槽53の内側上部に設けられ、洗浄槽53の内側に洗浄水(純水など)を供給して洗浄槽53の内側を洗浄する。なお、洗浄槽53には基板を搬入出するための開閉可能な開口(不図示)が設けられている。 The cleaning tank cleaning shower 52 is provided on the inner upper part of the cleaning tank 53, and cleaning water (pure water or the like) is supplied to the inside of the cleaning tank 53 to clean the inside of the cleaning tank 53. The cleaning tank 53 is provided with an opening / closing opening (not shown) for loading / unloading the substrate.

図10A〜図10Fは、図9の洗浄装置にて基板の洗浄を行うプロセスを行う様子を順に示す図である(いずれも配管71〜74は省略)。なお、本洗浄装置での処理に先立って、基板処理装置内でセリアを含むスラリーを用いた基板の研磨が行われ、望ましくは基板を乾燥させることなく本洗浄装置内に基板が搬送され、チャックによって保持される。そして、退避位置にあったアーム51が洗浄位置に移動する。 10A to 10F are views showing the process of cleaning the substrate by the cleaning apparatus of FIG. 9 in order (pipes 71 to 74 are omitted in each case). Prior to the processing in the main cleaning device, the substrate is polished using the slurry containing ceria in the substrate processing device, and preferably the substrate is conveyed into the main cleaning device without drying the substrate, and the chuck is chucked. Held by. Then, the arm 51 that was in the retracted position moves to the cleaning position.

まず、図10Aに示すように、SPM供給ノズル64からSPMを基板に供給する。これにより、基板に付着しているスラリおよび研磨時に発生した有機残渣物が除去(溶融)される。このとき、外部熱源から基板を加熱するようにしてもよい。 このように外部熱源から熱を基板上に供給することで、より確実に基板上から残渣を除去できる。 First, as shown in FIG. 10A, SPM is supplied to the substrate from the SPM supply nozzle 64. As a result, the slurry adhering to the substrate and the organic residue generated during polishing are removed (melted). At this time, the substrate may be heated from an external heat source. By supplying heat from the external heat source onto the substrate in this way, the residue can be more reliably removed from the substrate.

続いて、図10Bに示すように、H22供給ノズル63から過酸化水素水を基板に供給する。これにより、SPMにおける硫酸が基板から除去される。 Subsequently, as shown in FIG. 10B, hydrogen peroxide solution is supplied to the substrate from the H 2 O 2 supply nozzle 63. This removes sulfuric acid in the SPM from the substrate.

続いて、図10Cに示すように、純水供給ノズル62から純水または温水を基板に供給する。これにより、基板がリンスされ、薬液成分が洗い流される。このとき、洗浄槽洗浄シャワー52からも洗浄槽53内部に洗浄水を供給する。これにより、洗浄槽53内部に飛散していたSPMや過酸化水素水も除去される。 Subsequently, as shown in FIG. 10C, pure water or hot water is supplied to the substrate from the pure water supply nozzle 62. As a result, the substrate is rinsed and the chemical solution components are washed away. At this time, the washing water is also supplied from the washing tank washing shower 52 to the inside of the washing tank 53. As a result, the SPM and hydrogen peroxide solution scattered inside the cleaning tank 53 are also removed.

続いて、図10Dに示すように、APM供給ノズル61からAPMを基板に供給する。これにより、SPM洗浄で除去できなかったパーティクルが除去される。このとき、液体と気体の2流体も処理できる機構とするのが望ましい。このとき、外部熱源から基板を加熱するようにしてもよい。このように外部熱源から熱を基板上に供給することで、より確実に基板上から残渣を除去できる。なお、図10Cに示すように洗浄槽53内部を洗浄しておくことで、SPMにおける硫酸とAPMにおけるアンモニアとの反応を抑制できる。 Subsequently, as shown in FIG. 10D, APM is supplied to the substrate from the APM supply nozzle 61. As a result, particles that could not be removed by SPM cleaning are removed. At this time, it is desirable to have a mechanism capable of processing two fluids, a liquid and a gas. At this time, the substrate may be heated from an external heat source. By supplying heat from the external heat source onto the substrate in this way, the residue can be more reliably removed from the substrate. By cleaning the inside of the cleaning tank 53 as shown in FIG. 10C, the reaction between sulfuric acid in SPM and ammonia in APM can be suppressed.

続いて、図10Eに示すように、純水供給ノズル62から純水または温水を基板に供給する。これにより、基板がファイナルリンスされ、薬液成分が除去される。 Subsequently, as shown in FIG. 10E, pure water or hot water is supplied to the substrate from the pure water supply nozzle 62. As a result, the substrate is finally rinsed and the chemical solution component is removed.

続いて、図10Fに示すように、基板を回転させながらスピン乾燥を行い、その後に乾燥した基板を筐体から搬出する。 Subsequently, as shown in FIG. 10F, spin drying is performed while rotating the substrate, and then the dried substrate is carried out from the housing.

なお、図9では、1つのアーム51にAPM供給ノズル61、純水供給ノズル62、H22供給ノズル63およびSPM供給ノズル64が設けられる例を示したが、ノズルの配置は種々考えられる。例えば、純水供給ノズルおよびH22供給ノズルは固定ノズルから供給するようにしてもよい。また、図10Aに示すSPM洗浄に先立って基板を粗洗浄してもよい。粗洗浄は、例えばAPM洗浄でもよいし、気体および液体のジェット流を供給する2流体ジェット洗浄でもよい。あるいは、粗洗浄は回転するロールスポンジを基板に接触させるロール洗浄であってもよい。 Although FIG. 9 shows an example in which the APM supply nozzle 61, the pure water supply nozzle 62, the H 2 O 2 supply nozzle 63, and the SPM supply nozzle 64 are provided on one arm 51, various arrangements of the nozzles can be considered. .. For example, the pure water supply nozzle and the H 2 O 2 supply nozzle may be supplied from a fixed nozzle. Further, the substrate may be roughly washed prior to the SPM cleaning shown in FIG. 10A. The rough cleaning may be, for example, APM cleaning or two-fluid jet cleaning that supplies a jet stream of gas and liquid. Alternatively, the rough cleaning may be a roll cleaning in which a rotating roll sponge is brought into contact with the substrate.

上述した実施形態は、本発明が属する技術分野における通常の知識を有する者が本発明を実施できることを目的として記載されたものである。上記実施形態の種々の変形例は、当業者であれば当然になしうることであり、本発明の技術的思想は他の実施形態にも適用しうることである。したがって、本発明は、記載された実施形態に限定されることはなく、特許請求の範囲によって定義される技術的思想に従った最も広い範囲とすべきである。 The above-described embodiments have been described for the purpose of allowing a person having ordinary knowledge in the technical field to which the present invention belongs to carry out the present invention. Various modifications of the above embodiment can be naturally made by those skilled in the art, and the technical idea of the present invention can be applied to other embodiments. Accordingly, the invention is not limited to the described embodiments and should be the broadest scope according to the technical ideas defined by the claims.

1 ロードポート
2 研磨部
31〜33 洗浄装置
31a,32a,33a 筐体
31b,32b,33b シャッタ
31c,32c,33c 洗浄部
4 乾燥装置
4a 筐体
4b シャッタ
4c 乾燥部
5〜9 搬送部
10,11 基板ステーション
12 制御部
13 装置
21 高温APM供給源
22 過酸化水素供給源
23 高温硫酸供給源
24 高温純水供給源
51 アーム
52 洗浄槽洗浄シャワー
53 洗浄槽
61 APM供給ノズル
62 純水供給ノズル
63 H22供給ノズル
64 SPM供給ノズル
71〜74 配管
1 Load port 2 Polishing unit 31 to 33 Cleaning unit 31a, 32a, 33a Housing unit 31b, 32b, 33b Shutter 31c, 32c, 33c Cleaning unit 4 Drying device 4a Housing unit 4b Shutter 4c Drying unit 5 to 9 Transport unit 10, 11 Board station 12 Control unit 13 Device 21 High temperature APM supply source 22 Hydrogen peroxide supply source 23 High temperature sulfuric acid supply source 24 High temperature pure water supply source 51 Arm 52 Cleaning tank cleaning shower 53 Cleaning tank 61 APM supply nozzle 62 Pure water supply nozzle 63 H 2 O 2 Supply Nozzle 64 SPM Supply Nozzle 71-74 Piping

Claims (17)

研磨液を用いて基板を研磨する研磨部と、
前記研磨部で研磨された基板を基板保持回転機構により保持して回転させつつ硫酸および過酸化水素水をノズルから供給し、次いで、純水を用いて洗浄する第1洗浄部と、
前記第1洗浄部によって洗浄された基板を基板保持回転機構により保持して回転させつつ塩基性の薬液および過酸化水素水を用いて洗浄する第2洗浄部と、
前記第2洗浄部によって洗浄された基板を乾燥させる乾燥部と、を備える基板処理装置。
A polishing part that polishes the substrate with a polishing liquid,
A first cleaning unit, in which sulfuric acid and hydrogen peroxide solution are supplied from a nozzle while the substrate polished by the polishing unit is held and rotated by a substrate holding rotation mechanism, and then cleaned with pure water,
A second cleaning unit that cleans the substrate cleaned by the first cleaning unit with a basic chemical solution and hydrogen peroxide solution while holding and rotating the substrate by the substrate holding rotation mechanism.
A substrate processing apparatus including a drying unit for drying the substrate cleaned by the second cleaning unit.
前記研磨部によって研磨された後、かつ、前記第1洗浄部によって洗浄される前の前記基板を乾燥させる機構を持たない、請求項1に記載の基板処理装置。 The substrate processing apparatus according to claim 1, which does not have a mechanism for drying the substrate after being polished by the polishing portion and before being cleaned by the first cleaning portion. 前記研磨部によって研磨された基板を乾燥させることなく前記第1洗浄部に搬送する搬送部を備える、請求項1または2に記載の基板処理装置。 The substrate processing apparatus according to claim 1 or 2, further comprising a transport unit that transports the substrate polished by the polishing unit to the first cleaning unit without drying. 前記搬送部によって搬送中の基板に液体を浴びせる第1液体供給機構を備える、請求項3に記載の基板処理装置。 The substrate processing apparatus according to claim 3, further comprising a first liquid supply mechanism for spraying a liquid on the substrate being transported by the transport unit. 前記研磨部によって研磨された後、かつ、前記第1洗浄部によって洗浄される前の基板が載置される基板ステーションと、
前記基板ステーションに載置された基板に液体を浴びせる第2液体供給機構と、を備える、請求項1乃至4のいずれかに記載の基板処理装置。
A substrate station on which a substrate is placed after being polished by the polishing portion and before being cleaned by the first cleaning portion.
The substrate processing apparatus according to any one of claims 1 to 4, further comprising a second liquid supply mechanism for basking a substrate mounted on the substrate station with a liquid.
前記第1洗浄部は、開閉可能な第1シャッタが設けられた第1筐体に収納され、
前記第2洗浄部は、開閉可能な第2シャッタが設けられた第2筐体に収納され、
前記乾燥部は、開閉可能な第3シャッタが設けられた第3筐体に収納される、請求項1乃至5のいずれかに記載の基板処理装置。
The first cleaning unit is housed in a first housing provided with a first shutter that can be opened and closed.
The second cleaning unit is housed in a second housing provided with a second shutter that can be opened and closed.
The substrate processing apparatus according to any one of claims 1 to 5, wherein the drying portion is housed in a third housing provided with a third shutter that can be opened and closed.
前記研磨部によって研磨された基板を、塩基性の薬液および過酸化水素水を用いて洗浄する第3洗浄部を備え、
前記第1洗浄部は、前記第3洗浄部によって洗浄された基板を洗浄する、請求項1乃至6のいずれかに記載の基板処理装置。
A third cleaning unit for cleaning the substrate polished by the polishing unit with a basic chemical solution and a hydrogen peroxide solution is provided.
The substrate processing apparatus according to any one of claims 1 to 6, wherein the first cleaning unit cleans the substrate cleaned by the third cleaning unit.
前記第3洗浄部は、塩基性の薬液および過酸化水素水を前記基板に供給しつつ、洗浄部材を前記基板に接触させて洗浄する、請求項7に記載の基板処理装置。 The substrate processing apparatus according to claim 7, wherein the third cleaning unit performs cleaning by bringing a cleaning member into contact with the substrate while supplying a basic chemical solution and a hydrogen peroxide solution to the substrate. 前記第2洗浄部は、塩基性の薬液および過酸化水素水を用いて前記基板を洗浄した後、2流体ジェット洗浄を行う、請求項1乃至8のいずれかに記載の基板処理装置。 The substrate processing apparatus according to any one of claims 1 to 8, wherein the second cleaning unit cleans the substrate with a basic chemical solution and a hydrogen peroxide solution, and then performs two-fluid jet cleaning. 前記研磨部は、セリアを含む研磨液を用いて前記基板を研磨する、請求項1乃至9のいずれかに記載の基板処理装置。 The substrate processing apparatus according to any one of claims 1 to 9, wherein the polishing portion polishes the substrate with a polishing liquid containing ceria. 基板処理装置における研磨部によって、研磨液を用いて基板を研磨する研磨工程と、
その後、前記基板処理装置における第1洗浄部によって、前記基板を基板保持回転機構により保持して回転させつつ硫酸および過酸化水素水を用いて洗浄し、次いで純水を用いて洗浄する第1洗浄工程と、
その後、前記基板処理装置における第2洗浄部によって、前記基板を基板保持回転機構により保持して回転させつつ塩基性の薬液および過酸化水素水を用いて洗浄する第2洗浄工程と、
その後、前記基板処理装置における乾燥部によって、前記基板を乾燥させる乾燥工程と、を備える基板処理方法。
The polishing process of polishing the substrate with the polishing liquid by the polishing part in the substrate processing device,
After that, the first cleaning unit in the substrate processing apparatus holds the substrate by the substrate holding rotation mechanism and rotates it while cleaning it with sulfuric acid and hydrogen peroxide solution , and then cleans it with pure water. Process and
After that, a second cleaning step of cleaning the substrate with a basic chemical solution and a hydrogen peroxide solution while holding and rotating the substrate by the substrate holding rotation mechanism by the second cleaning unit in the substrate processing apparatus.
A substrate processing method comprising a drying step of drying the substrate by a drying unit in the substrate processing apparatus.
前記研磨工程の後、研磨された基板を乾燥させることなく前記研磨部から前記第1洗浄部に前記基板を搬送する搬送工程を備える、請求項11に記載の基板処理方法。 The substrate processing method according to claim 11, further comprising a transfer step of transporting the substrate from the polishing portion to the first cleaning portion without drying the polished substrate after the polishing step. セリウムイオンが付着した基板を基板保持回転機構により保持して回転させつつ硫酸および過酸化水素水をノズルから供給し、次いで、純水を用いて洗浄する第1洗浄工程と、
その後、前記基板を基板保持回転機構により保持して回転させつつ塩基性の薬液および過酸化水素水を用いて前記基板を洗浄する第2洗浄工程と、
その後、前記基板を乾燥させる乾燥工程と、を備える基板処理方法。
A first cleaning step in which sulfuric acid and hydrogen peroxide solution are supplied from a nozzle while the substrate to which cerium ions are attached is held and rotated by a substrate holding rotation mechanism, and then washed with pure water.
After that, a second cleaning step of cleaning the substrate with a basic chemical solution and a hydrogen peroxide solution while holding the substrate by the substrate holding rotation mechanism and rotating the substrate,
After that, a substrate processing method comprising a drying step of drying the substrate.
前記第1洗浄工程および/または前記第2洗浄工程では、前記基板を加熱する、請求項13に記載の基板処理方法。 The substrate processing method according to claim 13, wherein the substrate is heated in the first cleaning step and / or the second cleaning step. 前記第1洗浄工程の前に、セリウムイオンが付着した前記基板に対して、
塩基性の薬液および過酸化水素水を供給する工程、
回転するスポンジ部材を接触させる工程、および、
気体および液体のジェット流を供給する工程
の少なくとも1つの工程を備える、請求項13または14に記載の基板処理方法。
Before the first cleaning step, the substrate to which cerium ions are attached is
The process of supplying a basic chemical solution and hydrogen peroxide solution,
The process of bringing the rotating sponge member into contact, and
13. The substrate processing method according to claim 13, comprising at least one step of supplying a jet stream of gas and liquid.
前記第1洗浄工程、前記第2洗浄工程および前記乾燥工程は、洗浄槽内で行われ、
前記第1洗浄工程と前記第2洗浄工程との間に、前記洗浄槽の内側を洗浄する工程と、
前記第2洗浄工程と前記乾燥工程との間に、前記洗浄槽の内側を洗浄する工程と、を備える、請求項13乃至15のいずれかに記載の基板処理方法。
The first cleaning step, the second cleaning step, and the drying step are performed in a cleaning tank.
Between the first cleaning step and the second cleaning step, a step of cleaning the inside of the cleaning tank and a step of cleaning the inside of the cleaning tank.
The substrate processing method according to any one of claims 13 to 15, further comprising a step of cleaning the inside of the cleaning tank between the second cleaning step and the drying step.
前記第1洗浄工程の前に、セリウムイオンを含むスラリーを用いて前記基板を研磨する研磨工程を備え、
前記研磨工程と前記第2洗浄工程との間に、研磨後の基板を乾燥させない、請求項13乃至16のいずれかに記載の基板処理方法。
Prior to the first cleaning step, a polishing step of polishing the substrate with a slurry containing cerium ions is provided.
The substrate processing method according to any one of claims 13 to 16, wherein the substrate after polishing is not dried between the polishing step and the second cleaning step.
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