JP2004288849A - Electric discharge detector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electric discharge detector which can detect electric discharge in a chamber accurately. <P>SOLUTION: The abnormal discharge detector 10A detects the electric discharge in the chamber 14. The detector comprises a reception antenna 18A arranged outside the chamber 14 to be near a peep 12 formed on the chamber 14 and having a reception characteristic corresponding to the opening dimension of the peep 12, and a reception device 20A which receives electromagnetic waves via the reception antenna 18A. By catching the electromagnetic waves E generated in the chamber 14 with the reception antenna 18A via the peep 12, the existence or non-existence of abnormal discharge in the chamber can be monitored without fail. The reception characteristic of the antenna 18A is set in correspondence with the opening dimension of the peep 12 to allow the antenna to receive electromagnetic waves having frequency bands higher than the cut-off frequency of the peep 12. Thus, the electromagnetic waves coming out of the peep 12 are received precisely to improve accuracy in detecting the electric discharge in the chamber. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

【００１７】
次に、放電検出装置１０Ａの動作を説明する。
いま、チャンバ１４の内部で異常放電が発生したとすると、この放電に伴って電磁波Ｅが発生する。一方、チャンバ１４は、金属製であるため電磁波を通過させない構造になっているが、窓部１２にはガラスが嵌め込まれているので、この開口部から電磁波Ｅが洩れ出す。ここで、図３に示すように、チャンバ内での放電に伴う電磁波のスペクトラムＳＰは、極めて帯域が広く、２０ｋＨｚ程度の音響の領域から可視光の領域まで確認されている。
【００１８】
これに対し、チャンバ１４の窓部１２の遮断周波数ｆｃはその開口寸法によって決定されるので、窓部１２を介してチャンバ１４の外部に漏れ出る電磁波Ｅの帯域は、遮断周波数ｆｃ以上に制限される。しかし、窓部１２の外部に設けられた受信アンテナ１８Ａの受信特性が遮断周波数ｆｃ以上の帯域に設定されているので、窓部１２から漏れ出た遮断周波数ｆｃ以上の帯域の電磁波Ｅは受信アンテナ１８Ａで受信され、受信装置２０Ａに供給される。従って、受信装置２０Ａは、受信アンテナ１８Ａを介して電磁波Ｅを受信し、チャンバ１４の内部で放電が発生した旨を表す信号を生成して出力する。
【００１９】
図４は、受信アンテナの第１の変形例を示し、上述の図１に示す構成において、ループアンテナからなる受信アンテナ１８Ａに代えて、モノポールアンテナからなる受信アンテナ４４を採用した場合の構成を示す図である。この場合、窓部１２は、覗くことを目的としたものではなく、ハーメチックシールなどの気密封止型のコネクタとして機能するものであり、受信アンテナ４４は、その一部をチャンバ１４内に突出させるようにして、窓部１２に固定されている。この例によれば、上述の図１に示す例に比べて、受信アンテナ４４がチャンバ１４内の放電発生位置に近づくので、強い電磁波を捕らえることができ、従って放電の検出能力が向上する。その他の構成は図１と同様であり、図１と同じ部分には同じ符号を付すことにより説明を省略する。
【００２０】
図５は、受信アンテナの第２の変形例を示し、上述の図１に示す構成において、ループアンテナからなる受信アンテナ１８Ａを、窓部１２の金属枠５６に嵌め込まれたガラス板５４内に封止した場合の構成を示し、図３［１］は正面図、図３［２］は図３［１］におけるＩＩＩ−ＩＩＩ線縦断面図である。その他の構成は図１に示す構成と同様である。この変形例では、プラズマを遮蔽するための上述の遮蔽部材は設けられておらず、窓部１２は円形に形成されている。受信アンテナ５２は、ガラス板５４内に封止され、その両端の電極５８，６０に受信装置２０Ａ（図１）の入力部が接続される。この構成によれば、図１に示す構成に比べて受信アンテナ１８Ａがチャンバ１４内の放電発生位置に近づくので、図４に示す例と同様に放電の検出能力が向上する。なお、ガラス板５４内に封止するアンテナはどのような形状であってもよい。
【００２１】
図６は、受信アンテナの第３の変形例を示し、外来の不要な電磁波を遮蔽するためのシールドケース１８２を受信アンテナ１８Ａと一体に備えた構成を示す。その他の構成は図１に示す構成と同様である。この変形例では、ループアンテナからなる受信アンテナ１８Ａは、支持部材１８３によりシールドケース１８２の内部に固定されている。シールドケース１８２は、一方向に向けて開放した概略箱状の形態を有しており、その開口部が窓部１２に対向するようにして、チャンバ１４の外側に装着される。即ち、図１の構成において、受信アンテナ１８Ａをシールドケース１８２で覆ったものと等価になる。この第３の変形例によれば、受信アンテナ１８Ａの周囲は、チャンバ１４の窓部１２を除いてシールドケース１８２で覆われるので、チャンバ１４の内部以外の方向から受信アンテナ１８Ａに到来する不要な電磁波がシールドケース１８２に遮断される。従って、チャンバ１４の内部で発生した電磁波のみを的確に受信することが可能となり、チャンバ１４内の放電を精度よく検出することが可能になる。
【００２２】
（第２の実施形態）
以下、この発明の第２の実施形態を説明する。
図７に、この実施形態に係る放電検出装置１０Ａの構成と、その適用例を示す。同図において、図１に示す構成要素と同一要素には同一符号を付し、その説明を省略する。放電検出装置１０Ｂは、チャンバ１４内で発生する放電を検出するものであって、受信アンテナ１８Ｂおよび受信装置２０Ｂを備えて構成される。受信アンテナ１８Ｂは、ループアンテナであるアンテナ素子１８ＢＡ，１８ＢＢから構成され、チャンバ１４に設けられた窓部１２の近傍であって該チャンバ１４の外部に配置され、窓部１２の開口寸法に応じた受信特性を有している。
【００２３】
具体的には、アンテナ素子１８ＢＡは、窓部１２を導波管としたときの遮断周波数ｆｃに対して受信特性が高域側に設定され、アンテナ素子１８ＢＢは、上述の遮断周波数ｆｃに対して受信特性が低域側に設定されている。即ち、アンテナ素子１８ＢＡの受信特性は、窓部１２の遮断周波数ｆｃ以上の帯域を受信し得るように設定され、アンテナ素子１８ＢＢの受信特性は、遮断周波数ｆｃ以下の帯域を受信し得るように設定されている。また、受信装置２０Ｂは、受信回路２１Ｂ，２２Ｂ、信号演算回路２３Ｂ、データロガー２４Ｂから構成される。
【００２４】
ここで、受信回路２１Ｂは、アンテナ素子１８ＢＡを介して電磁波を受信するものであり、受信回路２２Ｂは、アンテナ素子１８ＢＢを介して電磁波を受信するものである。これら受信回路の出力信号は信号演算回路２３Ｂに供給され、この信号演算回路２３Ｂの演算結果はデータロガー２４Ｂに記憶されるようになっている。アンテナ素子１８ＢＡは図１に示す受信アンテナ１８Ａと等価であり、受信回路２１Ｂは図１に示す受信装置２０Ａと等価である。即ち、この構成例は、上述の図１に示す構成において、新たに、アンテナ素子１８ＢＢ、受信回路２２Ｂ、信号演算回路２３Ｂ、データロガー２４Ｂを備えたものと言える。
【００２５】
次に、放電検出装置１０Ｂの動作を説明する。上述の第１の実施形態では、遮断周波数ｆｃ以上の帯域の電磁波Ｅが受信されたか否かにより、放電の有無を判別するものとしたが、外来の電磁波によるノイズを誤検出する場合があり得る。そこで、この実施形態では、遮断周波数ｆｃ以上の帯域に属する周波数成分ｆＨと、遮断周波数ｆｃ以下の帯域に属する周波数成分ｆＬとをそれぞれ検出することにより、チャンバ内で発生した電磁波ＥＡと外来の電磁波ＥＢとを区別する。ここで、外来の電磁波ＥＢとしてホワイトノイズを想定すると、図８に示すように、このホワイトノイズのスペクトルＳＰＢは、チャンバ内の放電による電磁波のスペクトルＳＰＡと同様に広い帯域を有する。
【００２６】
しかし、チャンバ内で発生した電磁波のうち、窓部１２から外部に漏れ出る電磁波ＥＡは、遮断周波数ｆｃ以上の帯域に制限されるのに対し、外来のホワイトノイズなどの電磁波ＥＢにはこのような制限がない。そこで、アンテナ素子１８ＢＡ，１８ＢＢを介して高域側の周波数成分ｆＨと低域側の周波数ｆＬとをそれぞれ受信することにより、受信された電磁波がチャンバから漏れ出た電磁波ＥＡであるか否かを判別することが可能になる。この判別処理は、信号演算回路２３Ｂで行われ、チャンバから漏れ出た電磁波ＥＡであると判別された場合には、チャンバ内で放電が発生した旨を表す信号を生成し、データロガー２４Ｂに出力する。
【００２７】
図９に、上述の判別処理に用いられるテーブルの一例を示す。このテーブルによれば、遮断周波数ｆｃ以上の帯域に属する周波数成分ｆＨが受信され、且つ遮断周波数ｆｃ以下の帯域に属する周波数成分ｆＬが受信されない場合、チャンバから漏れ出た電磁波によるシグナルを受信したものと判別される。また、周波数成分ｆＨおよび周波数成分ｆＬが共に受信された場合、ノイズを受信したものと判別される。さらに、周波数成分ｆＨが受信されず、且つ周波数成分ｆＬが受信された場合も、ノイズを受信したものと判別される。
【００２８】
即ち、上述の図９に示すテーブルによれば、周波数成分ｆＨを受信した場合のみ、チャンバ内から漏れ出た電磁波によるシグナルと判別される。この判別結果は、データロガー２４Ｂに、放電の検出履歴として記録される。なお、周波数成分ｆＨおよび周波数成分ｆＬの何れも受信されない場合には、電磁波が存在しない状態であるから、判別処理の必要は生じない。
この第２の実施形態によれば、前述の図６に示すシールドケース１８２を用いることなく、外来の電磁波による影響を排除することが可能になり、従ってチャンバ１４の内部で発生した電磁波のみを的確に受信し、チャンバ１４内の放電を精度よく検出することが可能になる。もちろん、この第２の実施形態においても、上述の第１の実施形態で説明したシールドケース１８２を併用してもよい。
【００２９】
（第３の実施形態）
上述の第２の実施形態では、受信アンテナ１８Ｂに、窓部１２の開口寸法に応じた受信特性を持たせるものとしたが、この実施形態では、受信装置側に窓部１２の開口寸法に応じた受信特性を持たせ、同様にチャンバ内で発生した電磁波か否かの判別を行う。
図１０に、この実施形態に係る放電検出装置１０Ｃの構成と、その適用例を示す。同図において、図１に示す構成要素と同一要素には同一符号を付し、その説明を省略する。放電検出装置１０Ｃは、チャンバ１４内で発生する放電を検出するものであって、受信アンテナ１８および受信装置２０Ｃを備えて構成される。受信アンテナ１８Ｂは、ループアンテナから構成され、チャンバ１４に設けられた窓部１２の近傍であって該チャンバ１４の外部に配置される。ただし、この受信アンテナ１８の受信特性は、上述の遮断周波数ｆｃに制限されず、広帯域に設計される。即ち、受信アンテナ１８は、遮断周波数ｆｃの高域側と低域側の双方の周波数成分を含む電磁波を受信可能なように設計されている。
【００３０】
受信装置１０Ｃは、窓部１２の開口寸法に応じた受信特性を有しており、分波器２１Ｃ、高域フィルタ２２Ｃ、受信回路２３Ｃ、低域フィルタ２４Ｃ、受信回路２５Ｃ、信号演算回路２６Ｃ、データロガー２７Ｃから構成される。分波器２１Ｃは、受信アンテナ１８で受信された信号を２つの信号に分波するものであり、この分波器２１Ｃで分波された一方の信号は高域フィルタ２２Ｃに入力され、他方の信号は低域フィルタ２４Ｃに入力される。これら高域フィルタ２２Ｃおよび低域フィルタ２４Ｃを通過した信号は、それぞれ受信回路２３Ｃおよび２５Ｃに入力され、これら受信回路の出力信号は信号演算回路２６Ｃに入力される。信号演算回路２６Ｃおよびデータロガー２７は、上述の第２の実施形態に係る信号演算回路２３Ｂおよびデータロガー２４Ｂと同様の機能を有する。
【００３１】
高域フィルタ２２Ｃは、分波器２１Ｃで分波された一方の信号に含まれ高域側の周波数成分ｆＨを通過させるフィルタ特性を有し、低域フィルタ２４Ｃは、分波器２１Ｃで分波された他方の信号に含まれる低域側の周波数成分ｆＬを通過させるフィルタ特性を有している。これにより、一方の受信回路２３Ｃには、受信アンテナ１８を介して受信された信号のうち、高域側の周波数成分ｆＨが受信され、他方の受信回路２５Ｃには、受信アンテナ１８を介して受信された信号のうち、低域側の周波数成分ｆＬが受信される。
【００３２】
次に、この第３の実施形態の動作を説明する。この実施形態でも、上述の第２の実施形態と同様に、高域側の周波数成分ｆＨと低域側の周波数成分ｆＬをそれぞれ受信することのより、外来の電磁波ＥＢの影響を排除する。具体的に説明する。受信アンテナ１８で受信された信号は、分波器２１Ｃ、高域フィルタ２２Ｃ、受信回路２３Ｃから成る回路系により、高域側の周波数成分ｆＨが検出される。一方、同じく受信アンテナ１８で受信された信号は、分波器２１Ｃ、低域フィルタ２４Ｃ、受信回路２５Ｃから成る回路系により、低域側の周波数成分ｆＬが検出される。これらの検出信号は信号演算回路２６Ｃに与えられ、上述の信号演算回路２３Ｂと同様の判別処理が行われる。即ち、高域側の周波数成分ｆＨが検出され、且つ低域側の周波数成分ｆＬが検出されない場合、チャンバから漏れ出た電磁波によるシグナルを受信したものと判別される。この判別結果は検出履歴としてデータロガー２７Ｃに記録される。
【００３３】
この第３の実施形態によれば、前述の第２の実施形態と同様に、図６に示すシールドケース１８２を用いることなく、外来の電磁波による影響を排除することが可能になり、従ってチャンバ１４の内部で発生した電磁波のみを的確に受信し、チャンバ１４の内部で発生する放電を精度よく検出することが可能になる。もちろん、この第３の実施形態においても、上述のシールドケース１８２を併用してもよい。
また、この第３の実施形態によれば、高域フィルタ２２Ｃおよび低域フィルタ２４Ｃのフィルタ特性を用いて、受信信号が遮断周波数ｆｃに対して高域側か低域側かを識別しているので、アンテナ自体の受信特性を用いる上述の第２の実施形態に比較して、精度よく周波数帯域を識別することができる。従って、遮断周波数ｆｃの近傍の周波数成分を受信して図９に示すテーブルによる判別処理を行うことが可能になり、不要な外来の電磁波成分を一層有効に排除することが可能になる。
【００３４】
以上、この発明の一実施形態を説明したが、この発明は、この実施の形態に限られるものではなく、この発明の要旨を逸脱しない範囲の設計変更等があっても本発明に含まれる。例えば、上述の第１の実施形態では、プラズマを遮蔽するための遮蔽部材に設けられた開口部の寸法を窓部の開口寸法としたが、このような遮蔽部材を設けない場合には、窓部の開口寸法そのものを用いればよい。要するに、チャンバから漏れ出る電磁波が伝搬する導波管として作用する部材に着目して「窓部の開口寸法」を定義すればよい。
また、上述の第３の実施形態では、高域フィルタ２２Ｃおよび低域フィルタ２４Ｃを備えるものとしたが、受信回路２３，２５Ｃ自体の受信特性で代用するように構成してもよい。さらに、第２および第３の実施形態における各信アンテナについても、第１の実施形態での変形例と同様に、窓部をなすガラスなどの絶縁体に封止するものとしてもよい。
【００３５】
【発明の効果】
本発明に係る放電検出装置によれば、チャンバの窓部の近傍に該窓部の開口寸法に応じた受信特性を有する受信アンテナを配置し、該受信アンテナを介して電磁波を受信するようにしたので、窓部から漏れ出る電磁波を受信することができ、従ってチャンバ内で発生する放電を的確に検出することができる。
また、受信アンテナの受信特性を、窓部の遮断周波数に対して高域側に設定したので、窓部から漏れ出る電磁波を受信することができる。
また、受信アンテナを、受信特性が高域側に設定された第１のアンテナ素子と、受信特性が低域側に設定された第２のアンテナ素子とから構成したので、窓部を漏れ出た電磁波と、外来の電磁波とを区別して受信することができる。
また、高域側の第１の周波数成分を受信し且つ低域側の第２の周波数成分を受信しない場合に、放電を検出した旨を表す信号を出力するようにしたので、外来の電磁波の影響を排除して放電の検出を行うことができる。
【００３６】
本発明に係る放電検出装置によれば、チャンバの窓部の近傍に受信アンテナを配置し、受信装置に、チャンバの窓部の開口寸法に応じた受信特性を持たせたので、窓部から漏れ出る電磁波を受信することができ、従ってチャンバ内で発生する放電を的確に検出することができる。
また、分波器と高域フィルタと低域フィルタとを用いて受信装置を構成したので、窓部を漏れ出た電磁波と外来の電磁波とを区別して受信することができる。また、チャンバの内部以外の方向から到来する電磁波を遮蔽するための遮蔽部材をさらに備えたので、外来の電磁波の影響を一層有効に排除することができ、放電の検出を一層的確に行うことができる。
【図面の簡単な説明】
【図１】本発明の第１の実施形態に係る放電検出装置の構成例を示すブロック図である。
【図２】本発明の第１の実施形態に係るチャンバに設けられた窓部の遮断周波数を説明するための図である。
【図３】本発明の第１の実施形態に係る放電検出装置の動作を説明するための図である。
【図４】本発明の第１の実施形態に係る受信アンテナの第１の変形例を示す図である。
【図５】本発明の第１の実施形態に係る受信アンテナの第２の変形例を示す図である。
【図６】本発明の第１の実施形態に係る受信アンテナの第３の変形例を示す図である。
【図７】本発明の第２の実施形態に係る放電検出装置の構成例を示すブロック図である。
【図８】本発明の第２の実施形態に係る放電検出装置の動作を説明するための図である。
【図９】本発明の第２の実施形態に係る放電検出装置の判別処理で用いられるテーブルの一例を示す図である。
【図１０】本発明の第３の実施形態に係る放電検出装置の構成例を示すブロック図である。
【符号の説明】
１０Ａ，１０Ｂ，１０Ｃ；放電検出装置、１２；窓部、１４；チャンバ、１８，１８Ａ，１８Ｂ，４４；受信アンテナ、２０Ａ，２０Ｂ，２０Ｃ；受信装置、２１Ｂ，２２Ｂ，２３Ｃ，２５Ｃ；受信回路、２３Ｂ，２６Ｃ；信号演算回路、２４Ｂ，２７Ｃ；データロガー、２１Ｃ；分波器、２２Ｃ；高域フィルタ、２４Ｃ；低域フィルタ、１８ＢＡ，１８ＢＢ；アンテナ素子、１８２；シールドケース。[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a discharge detection device for detecting a discharge generated inside a chamber such as a plasma etching device.
[0002]
[Prior art]
In plasma etching equipment, a type of semiconductor manufacturing equipment, abnormal discharge phenomena occurring inside the chamber can be visually confirmed from the window of the chamber.If the discharge energy is large, burnout marks can be seen on the semiconductor wafer. There is also. This discharge phenomenon may break the insulation of a part or the whole area of the wafer, and causes a significant decrease in the productivity of the electronic device. Here, the case of the plasma etching apparatus has been described, but since the discharge easily occurs even in a low electric field in a vacuum, the same discharge phenomenon occurs in an ion milling apparatus, an ion implantation apparatus, a sputtering apparatus for forming a metal film, and the like.
However, since the window of the chamber is generally small, it is not possible to see the entire area in the chamber. In addition, since light emission due to discharge often disappears in an instant in the form of a small spot, it is often not visually recognizable. Further, it is impossible to visually observe the electrostatic discharge phenomenon that occurs at this point, in which the wafer charged up during the plasma processing is moved up to the next stage by pushing up the back surface of the wafer with metal pins.
[0003]
In recent years, as a technique for detecting an abnormal discharge generated in the above-described chamber, a technique of attaching an acoustic sensor to an outer wall surface of a plasma etching apparatus and monitoring the sound by a sound generated at the time of discharge, and a technique of using an AC voltage source of about 13 MHz. A technique of monitoring by a change in harmonic current has been disclosed (see Non-Patent Document 1).
[0004]
[Non-patent document 1]
"Ultrasonic TECHNO 2002.5-6", Nippon Kogyo Shuppan Co., Ltd., p41-46
[0005]
[Problems to be solved by the invention]
However, according to the technique of monitoring by sound described above, since the discharge environment is close to a vacuum, the sound wave may not reach the wall depending on the discharge position, and the discharge cannot always be detected. In addition, when a harmonic current is used, a phenomenon that the high-frequency electrode plate is not directly discharged during operation cannot be detected, and a discharge phenomenon during transport other than the plasma state cannot be detected.
[0006]
An object of the present invention is to provide a discharge detection device capable of accurately detecting a discharge in a chamber.
[0007]
[Means for Solving the Problems]
An abnormal discharge detection device according to the present invention is a discharge detection device that detects a discharge generated inside a chamber, the discharge detection device being disposed near a window provided in the chamber and outside the chamber, and A receiving antenna having a receiving characteristic corresponding to an opening dimension of the portion; and a receiving device receiving electromagnetic waves via the receiving antenna. The “window” may be made of, for example, an insulator such as glass. The term “insulator” refers to an electrical insulator, for example, having the same meaning as a dielectric.
[0008]
Here, since the discharge always involves the emission of an electromagnetic wave, if this electromagnetic wave can be detected from the outside, it is possible to know the occurrence of the discharge inside the chamber. However, since the chamber is generally made of metal, the structure is basically such that electromagnetic waves do not leak outside. Then, the present inventor paid attention to a window for internal observation provided in the chamber, and came up with an idea to catch an electromagnetic wave slightly leaking from this window. That is, according to the configuration of the present invention, the electromagnetic wave generated in the chamber is caught by the receiving antenna through the window, and the presence or absence of the occurrence of discharge is monitored. Therefore, the occurrence of discharge can be known from the electromagnetic wave received by the receiving antenna. Here, since the receiving antenna according to the present invention has the receiving characteristic according to the opening size of the window, the receiving antenna can accurately receive the electromagnetic wave passing through the window. In other words, by adjusting the receiving characteristics of the receiving antenna of the present invention to the size of the opening of the window, the electromagnetic waves leaking from the inside of the chamber are accurately received, thereby improving the “accuracy” of the detection.
[0009]
The receiving characteristic of the receiving antenna is set to be higher than a cutoff frequency of the waveguide when the window is a waveguide (claim 2). Thereby, the electromagnetic wave leaked from the window of the chamber is received by the receiving antenna.
A first antenna element whose reception characteristic is set to a higher frequency side with respect to a cutoff frequency of the waveguide when the window portion is a waveguide; And a second antenna element whose reception characteristic is set to a lower band side with respect to the cutoff frequency of the waveguide when (3). Thereby, the electromagnetic wave leaked from the window of the chamber is received by the first antenna element, the electromagnetic wave arriving from outside the chamber is received by the second antenna element, and is received by the first and second antenna elements. The signal by the electromagnetic wave is input to the receiving device.
The receiving device outputs a signal indicating that the discharge has been detected when the high frequency side first frequency component is received and the low frequency side second frequency component is not received (claim 4). ). Thereby, the electromagnetic wave leaked from the chamber can be detected separately from other electromagnetic waves.
[0010]
A discharge detection device according to the present invention is a discharge detection device that detects a discharge generated inside a chamber, and includes a receiving antenna disposed near a window provided in the chamber and outside the chamber. And a receiving device having a receiving characteristic according to an opening size of the window portion and receiving an electromagnetic wave via the receiving antenna. According to this configuration, for example, the presence / absence of discharge is monitored by capturing the electromagnetic wave generated in the chamber through the window with the receiving antenna. At this time, since the receiving device has the receiving characteristic according to the opening size of the window, the electromagnetic wave passing through the window is selectively received by the receiving antenna. Therefore, it is possible to grasp the occurrence of discharge from the electromagnetic wave received by the receiving antenna. In addition, since a high-frequency current is not used for detection, a discharge due to static electricity or the like other than a discharge generated at the electrode can be reliably detected.
[0011]
The receiving device, a demultiplexer for demultiplexing the signal received by the receiving antenna, and one of the signals demultiplexed by the demultiplexer is input, and the high-frequency side including the first frequency component A high-pass filter that passes a frequency component; and a low-pass filter that receives the other signal split by the splitter and passes a low-frequency component including the second frequency component. (Claim 6). The signal received by the receiving antenna is split by the splitter, and is divided into a high-pass filter and a low-pass filter. Then, the first frequency component passed through the high-pass filter and the second frequency component passed through the low-pass filter are input to the receiving device.
The receiving device outputs a signal indicating that the discharge has been detected when receiving the first frequency component and not receiving the second frequency component (claim 7). Thus, the electromagnetic wave leaked from the chamber can be detected separately from other electromagnetic waves.
The discharge detection device further includes a shielding member for shielding electromagnetic waves arriving from directions other than inside the chamber (claim 8). As a result, unnecessary electromagnetic waves arriving from directions other than the inside of the chamber (for example, the chamber itself or the outside of the chamber) are cut off, so that the electromagnetic waves generated due to the discharge can be accurately received, and the S / N ratio can be improved. Can be improved.
[0012]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
(1st Embodiment)
FIG. 1 shows a configuration of a discharge detection device 10A according to an embodiment of the present invention and an application example thereof. In FIG. 1, a chamber 14 constitutes a plasma dry etching apparatus which is a kind of a semiconductor manufacturing apparatus. Inside the chamber 14, an anode 24 on which a semiconductor wafer 22 to be subjected to a dry etching process is placed, and a gas G A cathode 26 also serving as a blowout port is accommodated. A high frequency voltage source 28 and a DC voltage source 30 provided outside the chamber 14 are connected to the anode 24.
[0013]
The gas G is introduced into the chamber through the inlet 32 at the upper end of the chamber I4, passes through the periphery of the wafer 22, and is discharged out of the chamber through the outlet 34 at the lower end of the chamber 14. A high-frequency voltage and a DC voltage are applied to the anode 24 by the high-frequency voltage source 28 and the DC voltage source 30, respectively, to form a high-frequency electric field between the anode 24 and the cathode 26. The gas G is converted into plasma by the electric field, and the semiconductor wafer 22 is etched by the plasma. The window 12 provided in the chamber 14 is for observing the inside of the chamber, and is fitted with an insulator (dielectric) such as glass.
[0014]
In this embodiment, the window 12 has a circular shape, but may have another shape. A mesh-shaped shielding member for shielding the plasma is attached inside the window 12 (that is, inside the chamber 14) in order to prevent the window from being fogged by the plasma. An external observer can visually observe the inside from the window 12 through the mesh-shaped shielding member. In addition, a slit for transmitting electromagnetic waves is formed in the shielding member. In the following description, the slit is referred to as an opening of the window 12, and the size of this opening is referred to as the opening of the window 12. Call it.
[0015]
The discharge detecting device 10A detects a discharge generated in the chamber 14, and includes a receiving antenna 18A and a receiving device 20A. The receiving antenna 18 </ b> A is formed of, for example, a loop antenna, is disposed near the window 12 provided in the chamber 14 and outside the chamber 14, and has a receiving characteristic according to the opening size of the window 12. are doing. Specifically, the receiving characteristics of the receiving antenna 18A are set so as to receive a band equal to or higher than the cutoff frequency fc when the opening of the window 12 is viewed as a waveguide. For example, assuming that the vertical dimension of the opening (slit) of the window portion 12 is a and the horizontal dimension is b, the opening has a width a, a height b, and a long length as shown in FIG. The cutoff frequency fc of this waveguide is represented by the following equation (1). However, in the same equation, “c” represents the speed of light. As an example, in equation (1), if a = 25 [mm], b = 1 [mm], m = 1 and n = 0, the cutoff frequency fc is about 6 × 10 ⁹ [Hz].
[0016]
(Equation 1)

[0017]
Next, the operation of the discharge detection device 10A will be described.
If an abnormal discharge occurs inside the chamber 14, an electromagnetic wave E is generated with the discharge. On the other hand, although the chamber 14 is made of metal and has a structure that does not allow electromagnetic waves to pass therethrough, since the glass is fitted into the window 12, the electromagnetic waves E leak out of this opening. Here, as shown in FIG. 3, the spectrum SP of the electromagnetic wave accompanying the discharge in the chamber has an extremely wide band, and is confirmed from an acoustic region of about 20 kHz to a visible light region.
[0018]
On the other hand, since the cutoff frequency fc of the window 12 of the chamber 14 is determined by the opening size, the band of the electromagnetic wave E leaking out of the chamber 14 through the window 12 is limited to the cutoff frequency fc or higher. You. However, the reception characteristic of the receiving antenna 18A provided outside the window 12 is set to a band equal to or higher than the cut-off frequency fc. It is received at 18A and supplied to the receiving device 20A. Therefore, the receiving device 20A receives the electromagnetic wave E via the receiving antenna 18A, and generates and outputs a signal indicating that a discharge has occurred inside the chamber 14.
[0019]
FIG. 4 shows a first modification of the receiving antenna. In the configuration shown in FIG. 1, a receiving antenna 44 composed of a monopole antenna is used instead of the receiving antenna 18A composed of a loop antenna. FIG. In this case, the window 12 is not intended to be viewed, but functions as an airtightly sealed connector such as a hermetic seal. The receiving antenna 44 projects a part of the receiving antenna 44 into the chamber 14. Thus, it is fixed to the window 12. According to this example, since the receiving antenna 44 approaches the position where the discharge occurs in the chamber 14 as compared with the example shown in FIG. 1 described above, a strong electromagnetic wave can be captured, and therefore, the ability to detect the discharge is improved. Other configurations are the same as those in FIG. 1, and the same parts as those in FIG.
[0020]
FIG. 5 shows a second modification of the receiving antenna. In the configuration shown in FIG. 1 described above, the receiving antenna 18A formed of a loop antenna is sealed in a glass plate 54 fitted in a metal frame 56 of the window 12. FIG. 3A is a front view, and FIG. 3B is a vertical sectional view taken along line III-III in FIG. 3A. Other configurations are the same as those shown in FIG. In this modification, the above-mentioned shielding member for shielding the plasma is not provided, and the window portion 12 is formed in a circular shape. The receiving antenna 52 is sealed in a glass plate 54, and the input section of the receiving device 20A (FIG. 1) is connected to the electrodes 58 and 60 at both ends. According to this configuration, as compared with the configuration shown in FIG. 1, the receiving antenna 18A is closer to the position where the discharge occurs in the chamber 14, so that the discharge detection ability is improved as in the example shown in FIG. The antenna sealed in the glass plate 54 may have any shape.
[0021]
FIG. 6 shows a third modification of the receiving antenna, and shows a configuration in which a shield case 182 for shielding external unnecessary electromagnetic waves is provided integrally with the receiving antenna 18A. Other configurations are the same as those shown in FIG. In this modification, a receiving antenna 18A formed of a loop antenna is fixed inside a shield case 182 by a support member 183. The shield case 182 has a substantially box-like shape opened in one direction, and is mounted on the outside of the chamber 14 with its opening facing the window 12. That is, in the configuration of FIG. 1, this is equivalent to a configuration in which the receiving antenna 18A is covered with the shield case 182. According to the third modification, the surroundings of the receiving antenna 18A are covered with the shield case 182 except for the window portion 12 of the chamber 14, so that it is unnecessary for the receiving antenna 18A to arrive at the receiving antenna 18A from a direction other than the inside of the chamber 14. Electromagnetic waves are blocked by the shield case 182. Therefore, only the electromagnetic waves generated inside the chamber 14 can be accurately received, and the discharge in the chamber 14 can be accurately detected.
[0022]
(Second embodiment)
Hereinafter, a second embodiment of the present invention will be described.
FIG. 7 shows a configuration of a discharge detection device 10A according to this embodiment and an application example thereof. In the figure, the same elements as those shown in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted. The discharge detecting device 10B detects a discharge generated in the chamber 14, and includes a receiving antenna 18B and a receiving device 20B. The receiving antenna 18B includes antenna elements 18BA and 18BB which are loop antennas, is disposed near the window 12 provided in the chamber 14 and outside the chamber 14, and has a size corresponding to the opening size of the window 12. It has receiving characteristics.
[0023]
Specifically, the reception characteristic of the antenna element 18BA is set to a higher frequency side with respect to the cutoff frequency fc when the window portion 12 is a waveguide, and the antenna element 18BB is set to the above cutoff frequency fc. The receiving characteristic is set to the low frequency side. That is, the reception characteristic of the antenna element 18BA is set so as to be able to receive a band equal to or higher than the cut-off frequency fc of the window portion 12, and the reception characteristic of the antenna element 18BB is set so as to be able to receive a band equal to or lower than the cut-off frequency fc. Have been. The receiving device 20B includes receiving circuits 21B and 22B, a signal operation circuit 23B, and a data logger 24B.
[0024]
Here, the receiving circuit 21B receives electromagnetic waves via the antenna element 18BA, and the receiving circuit 22B receives electromagnetic waves via the antenna element 18BB. The output signals of these receiving circuits are supplied to a signal operation circuit 23B, and the operation results of the signal operation circuit 23B are stored in a data logger 24B. The antenna element 18BA is equivalent to the receiving antenna 18A shown in FIG. 1, and the receiving circuit 21B is equivalent to the receiving device 20A shown in FIG. That is, it can be said that this configuration example is different from the configuration shown in FIG. 1 in that an antenna element 18BB, a receiving circuit 22B, a signal operation circuit 23B, and a data logger 24B are newly provided.
[0025]
Next, the operation of the discharge detection device 10B will be described. In the above-described first embodiment, the presence or absence of the discharge is determined based on whether or not the electromagnetic wave E in the band equal to or higher than the cutoff frequency fc is received. However, noise due to an external electromagnetic wave may be erroneously detected. . Therefore, in this embodiment, by detecting the frequency component fH belonging to the band equal to or higher than the cut-off frequency fc and the frequency component fL belonging to the band equal to or lower than the cut-off frequency fc, the electromagnetic wave EA generated in the chamber and the external electromagnetic wave EB is distinguished. Here, assuming white noise as the external electromagnetic wave EB, as shown in FIG. 8, the spectrum SPB of the white noise has a wide band like the spectrum SPA of the electromagnetic wave due to the discharge in the chamber.
[0026]
However, among the electromagnetic waves generated in the chamber, the electromagnetic wave EA leaking to the outside from the window portion 12 is limited to a band equal to or higher than the cut-off frequency fc. There are no restrictions. Therefore, by receiving the high-frequency component fH and the low-frequency fL via the antenna elements 18BA and 18BB, respectively, it is determined whether the received electromagnetic wave is the electromagnetic wave EA leaking from the chamber. It becomes possible to determine. This discrimination processing is performed by the signal operation circuit 23B. If it is determined that the electromagnetic wave EA has leaked from the chamber, a signal indicating that discharge has occurred in the chamber is generated and output to the data logger 24B. I do.
[0027]
FIG. 9 shows an example of a table used in the above-described determination processing. According to this table, when the frequency component fH belonging to the band equal to or higher than the cut-off frequency fc is received and the frequency component fL belonging to the band equal to or lower than the cut-off frequency fc is not received, the signal due to the electromagnetic wave leaking from the chamber is received. Is determined. When both the frequency component fH and the frequency component fL are received, it is determined that noise has been received. Further, when the frequency component fH is not received and the frequency component fL is received, it is also determined that noise has been received.
[0028]
That is, according to the table shown in FIG. 9 described above, only when the frequency component fH is received, it is determined that the signal is a signal due to the electromagnetic wave leaking from the chamber. This determination result is recorded in the data logger 24B as a discharge detection history. When neither the frequency component fH nor the frequency component fL is received, there is no electromagnetic wave, so that there is no need for the determination process.
According to the second embodiment, it is possible to eliminate the influence of an external electromagnetic wave without using the shield case 182 shown in FIG. 6 described above. Therefore, only the electromagnetic wave generated inside the chamber 14 can be accurately detected. And the discharge in the chamber 14 can be accurately detected. Of course, also in the second embodiment, the shield case 182 described in the first embodiment may be used together.
[0029]
(Third embodiment)
In the above-described second embodiment, the receiving antenna 18B has the receiving characteristic corresponding to the opening size of the window portion 12. In this embodiment, however, the receiving device side has the receiving characteristic corresponding to the opening size of the window portion 12. In the same manner, it is determined whether or not the electromagnetic wave is generated in the chamber.
FIG. 10 shows a configuration of a discharge detection device 10C according to this embodiment and an application example thereof. In the figure, the same elements as those shown in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted. The discharge detecting device 10C detects a discharge generated in the chamber 14, and includes a receiving antenna 18 and a receiving device 20C. The receiving antenna 18B is formed of a loop antenna, and is arranged near the window 12 provided in the chamber 14 and outside the chamber 14. However, the receiving characteristics of the receiving antenna 18 are not limited to the cutoff frequency fc described above, but are designed to have a wide band. That is, the receiving antenna 18 is designed to be able to receive an electromagnetic wave including frequency components on both the high frequency side and the low frequency side of the cutoff frequency fc.
[0030]
The receiving device 10C has receiving characteristics according to the aperture size of the window portion 12, and includes a duplexer 21C, a high-pass filter 22C, a receiving circuit 23C, a low-pass filter 24C, a receiving circuit 25C, a signal operation circuit 26C, It comprises a data logger 27C. The splitter 21C splits the signal received by the receiving antenna 18 into two signals. One signal split by the splitter 21C is input to the high-pass filter 22C, and the other is split into two signals. The signal is input to the low-pass filter 24C. The signals that have passed through the high-pass filter 22C and the low-pass filter 24C are input to receiving circuits 23C and 25C, respectively, and the output signals of these receiving circuits are input to a signal operation circuit 26C. The signal operation circuit 26C and the data logger 27 have the same functions as the signal operation circuit 23B and the data logger 24B according to the above-described second embodiment.
[0031]
The high-pass filter 22C has a filter characteristic of passing the high-frequency component fH included in one signal demultiplexed by the demultiplexer 21C, and the low-pass filter 24C is demultiplexed by the demultiplexer 21C. And has a filter characteristic of passing the low frequency component fL included in the other signal. Accordingly, one of the receiving circuits 23C receives the high frequency component fH of the signal received via the receiving antenna 18, and the other receiving circuit 25C receives the frequency component fH via the receiving antenna 18. The low frequency component fL of the signal thus received is received.
[0032]
Next, the operation of the third embodiment will be described. In this embodiment, similarly to the above-described second embodiment, by receiving the high-frequency component fH and the low-frequency component fL, the influence of the external electromagnetic wave EB is eliminated. This will be specifically described. In the signal received by the receiving antenna 18, a high-frequency component fH is detected by a circuit system including a duplexer 21C, a high-pass filter 22C, and a receiving circuit 23C. On the other hand, in the signal similarly received by the receiving antenna 18, a low-frequency component fL is detected by a circuit system including the duplexer 21C, the low-pass filter 24C, and the receiving circuit 25C. These detection signals are supplied to the signal operation circuit 26C, and the same discrimination processing as in the signal operation circuit 23B is performed. That is, when the high frequency component fH is detected and the low frequency component fL is not detected, it is determined that a signal due to the electromagnetic wave leaked from the chamber is received. This determination result is recorded on the data logger 27C as a detection history.
[0033]
According to the third embodiment, similarly to the above-described second embodiment, it is possible to eliminate the influence of an external electromagnetic wave without using the shield case 182 shown in FIG. Only the electromagnetic waves generated inside the chamber 14 can be accurately received, and the discharge generated inside the chamber 14 can be accurately detected. Of course, also in the third embodiment, the above-described shield case 182 may be used together.
Further, according to the third embodiment, whether the received signal is on the high band side or the low band side with respect to the cutoff frequency fc is determined using the filter characteristics of the high band filter 22C and the low band filter 24C. Therefore, the frequency band can be identified more accurately than in the above-described second embodiment using the reception characteristics of the antenna itself. Therefore, it is possible to receive a frequency component near the cutoff frequency fc and perform the determination process using the table shown in FIG. 9, and it is possible to more effectively eliminate unnecessary external electromagnetic wave components.
[0034]
As described above, one embodiment of the present invention has been described. However, the present invention is not limited to this embodiment, and the present invention includes any design change or the like without departing from the gist of the present invention. For example, in the above-described first embodiment, the size of the opening provided in the shielding member for shielding the plasma is set to the opening size of the window. The opening size itself of the portion may be used. In short, the “opening size of the window” may be defined by focusing on a member that functions as a waveguide through which the electromagnetic wave leaking from the chamber propagates.
In the third embodiment described above, the high-pass filter 22C and the low-pass filter 24C are provided, but the receiving characteristics of the receiving circuits 23 and 25C themselves may be used instead. Further, each of the signal antennas in the second and third embodiments may be sealed with an insulator such as glass forming a window, as in the modification of the first embodiment.
[0035]
【The invention's effect】
According to the discharge detection device of the present invention, a receiving antenna having a receiving characteristic corresponding to the opening size of the window is arranged near the window of the chamber, and the electromagnetic wave is received via the receiving antenna. Therefore, it is possible to receive the electromagnetic wave leaking from the window, and thus to accurately detect the discharge generated in the chamber.
Further, since the receiving characteristic of the receiving antenna is set to be higher than the cutoff frequency of the window, the electromagnetic wave leaking from the window can be received.
In addition, since the receiving antenna is composed of the first antenna element whose reception characteristic is set to the high frequency side and the second antenna element whose reception characteristic is set to the low frequency side, the window leaked out. Electromagnetic waves and foreign electromagnetic waves can be received separately.
Further, when the first frequency component on the high frequency side is received and the second frequency component on the low frequency side is not received, a signal indicating that a discharge has been detected is output. Discharge can be detected by eliminating the influence.
[0036]
According to the discharge detection device of the present invention, the receiving antenna is arranged near the window of the chamber, and the receiving device has a receiving characteristic according to the opening size of the window of the chamber. The emitted electromagnetic wave can be received, and therefore, the discharge generated in the chamber can be accurately detected.
In addition, since the receiving device is configured using the duplexer, the high-pass filter, and the low-pass filter, the electromagnetic wave leaking out of the window and the external electromagnetic wave can be distinguished and received. Further, since a shielding member for shielding electromagnetic waves arriving from a direction other than the inside of the chamber is further provided, the influence of the external electromagnetic waves can be more effectively eliminated, and the discharge can be detected more accurately. it can.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration example of a discharge detection device according to a first embodiment of the present invention.
FIG. 2 is a diagram for explaining a cutoff frequency of a window provided in a chamber according to the first embodiment of the present invention.
FIG. 3 is a diagram for explaining an operation of the discharge detection device according to the first embodiment of the present invention.
FIG. 4 is a diagram showing a first modification of the receiving antenna according to the first embodiment of the present invention.
FIG. 5 is a diagram showing a second modification of the receiving antenna according to the first embodiment of the present invention.
FIG. 6 is a diagram showing a third modification of the receiving antenna according to the first embodiment of the present invention.
FIG. 7 is a block diagram illustrating a configuration example of a discharge detection device according to a second embodiment of the present invention.
FIG. 8 is a diagram for explaining an operation of the discharge detection device according to the second embodiment of the present invention.
FIG. 9 is a diagram illustrating an example of a table used in a determination process of the discharge detection device according to the second embodiment of the present invention.
FIG. 10 is a block diagram illustrating a configuration example of a discharge detection device according to a third embodiment of the present invention.
[Explanation of symbols]
10A, 10B, 10C; discharge detection device, 12; window, 14; chamber, 18, 18A, 18B, 44; receiving antenna, 20A, 20B, 20C; receiving device, 21B, 22B, 23C, 25C; 23B, 26C; signal operation circuit, 24B, 27C; data logger, 21C; duplexer, 22C; high-pass filter, 24C; low-pass filter, 18BA, 18BB; antenna element, 182;

Claims (8)

A discharge detection device that detects a discharge generated inside the chamber,
A receiving antenna arranged near the window provided in the chamber and outside the chamber, and having a receiving characteristic according to an opening size of the window;
A receiving device for receiving electromagnetic waves via the receiving antenna,
A discharge detection device comprising: The discharge detection according to claim 1, wherein the reception characteristic of the reception antenna is set to a higher frequency side with respect to a cutoff frequency of the waveguide when the window portion is a waveguide. apparatus. The receiving antenna,
A first antenna element whose reception characteristic is set to a higher frequency side with respect to a cutoff frequency of the waveguide when the window portion is a waveguide;
A second antenna element whose reception characteristic is set to a lower band side with respect to a cutoff frequency of the waveguide when the window portion is a waveguide,
The discharge detection device according to claim 1, further comprising: The receiving device outputs the signal indicating that the discharge has been detected when the high frequency side first frequency component is received and the low frequency side second frequency component is not received. The discharge detection device according to claim 3, wherein: A discharge detection device that detects a discharge generated inside the chamber,
A receiving antenna disposed near the window provided in the chamber and outside the chamber;
A receiving device that has a receiving characteristic according to an opening size of the window portion and receives an electromagnetic wave via the receiving antenna,
A discharge detection device comprising: The receiving device,
A duplexer for splitting a signal received by the receiving antenna,
A high-pass filter that receives one of the signals split by the splitter and passes a high-frequency component including the first frequency component;
A low-pass filter that receives the other signal split by the splitter and passes a low-frequency component including the second frequency component;
The discharge detection device according to claim 5, further comprising: The said receiving device outputs the signal which shows that the said discharge was detected, when the said 1st frequency component is received and the said 2nd frequency component is not received, The said Claim 5 or Claim 6 characterized by the above-mentioned. Discharge detection device. The discharge detection device according to any one of claims 1 to 7, further comprising a shielding member for shielding an electromagnetic wave arriving from a direction other than inside the chamber.

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