JP2004247058A - Organic el display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an organic EL device capable of restraining a light-emitting property of an organic EL layer from deterioration. <P>SOLUTION: On the organic EL display device, a plurality of gate signal lines and drain signal lines crossing the gate signal lines are formed on a surface of a plate, and areas surrounded by those gate lines are to be pixel areas. A thin film transistor operating by a scanning signal from the gate signal lines, a pixel electrode to which an image signal is supplied from the drain signal lines through the thin film transistor, an opposing electrode functioning as a standard for the image signal, and the organic EL layer pinched between the pixel electrode and the opposing electrode are formed on each pixel area. Further, the organic EL display device has a bank film at least covering each signal line and formed with the pixel electrode exposed, and the organic EL layer formed on an upper part of the pixel electrode is formed so as not to touch the bank film. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

【００６０】
緑色のエレクトロルミネセンスを示す低分子系の有機エレクトロルミネセント材料の一例として、Ａｌｑ３（８−ｈｙｄｒｏｘｙｑｕｉｎｏｌｉｎｅ ａｌｕｍｉｎｕｍ）がある。この材料は、［化２］に示す分子構造を有する。
【００６１】
【化２】

【００６２】
青色のエレクトロルミネセンスを示す低分子系の有機エレクトロルミネセント材料の一例として、ＰＰＣＰ（１，２，３，４，５−ｐｅｎｔａｐｈｅｎｙｌ−１，３−ｃｙｃｌｏｐｅｎｔａｄｉｅｎｅ）がある。この材料は、［化３］に示す分子構造を有する。
【００６３】
【化３】

【００６４】
画素電極ＰＸに供給される映像信号によって、対向電極ＣＴの間に介在された発光材料層ＦＬＲに電流が流れ、該発光材料層ＦＬＲが該電流値に応じて発光するようになる。この光ＬＬは画素電極ＰＸ、絶縁膜ＩＬ、絶縁膜ＩＮ、絶縁膜ＧＩ、および透明基板ＳＵＢ１を介して観察者側へ照射されるようになる。
【００６５】
《バンク膜の開口部と発光材料層との位置関係》
ここで、上述したように、前記バンク膜ＢＮＫの開口部から露出されている画素電極ＰＸの上面には発光材料層ＦＬＲが重畳されて形成されている。そして、この実施例では、たとえば一画素において一個の独立した発光材料層ＦＬＲが設けられ、この発光材料層ＦＬＲの周辺は前記バンク膜ＢＮＫの開口部の側壁面との間に僅かな隙間を有し、該バンク膜ＢＮＫの開口部の側壁面と接触することなく形成されている。
【００６６】
仮に、発光材料層ＦＬＲの一部がバンク膜ＢＮＫに接触されて形成された場合、それらの各材料同士が化学的に反応し、長時間経過の後に、発光材料層ＦＬＲの発光劣化を引き起こしてしまうからである。
【００６７】
すなわち、発光材料層ＦＬＲは、その縦横の各長さがバンク膜ＢＮＫの開口部の縦横の各長さよりも小さく設定されているとともに、その中心は該バンク膜ＢＮＫの開口部の中心とほぼ一致づけられて形成されている。
【００６８】
この場合、バンク膜ＢＮＫの開口部はフォトリソグラフィ技術による選択エッチング方法で形成するのが通常であるため、その性質上、精度よく該開口部の縦横の寸法を設定することができる。しかし、発光材料層ＦＬＲは、金属板に孔が形成された蒸着マスクを介在させ、該孔を通して飛散される発光材料の蒸着によって形成するのが通常であるため、たとえば該蒸着マスクに撓み等が発生している場合に、その縦横の寸法が所定通りに形成されない場合がある。
【００６９】
しかし、本実施例では、該蒸着マスクとして工夫をこらしたものを用いていることから、寸法も含めて該蒸着マスクの孔のパターンどおりに形成することができ、発光材料層ＦＬＲのバンク膜ＢＮＫとの接触に起因する発光劣化を回避することができる。この蒸着マスクについては後に詳述する。
【００７０】
後述の蒸着マスクによる有機エレクトロルミネセント材料の蒸着では、これによって形成される発光材料層ＦＬＲの位置を精度よく制御できる。そのため、この利点を反映させた有機ＥＬ表示装置の平面構造の一例においては、画素内における発光材料層ＦＬＲとバンク膜ＢＮＫとの重なりを低減し、又は無くすことができる。このような構造は、特に有機材料で形成されたバンク膜ＢＮＫからの脱水や脱ガスによる発光材料層ＦＬＲの劣化とこれに生じる非発光領域の成長を抑える上で効果的である。このような画素の構造の一例は、これに形成された発光材料層ＦＬＲの輪郭とバンク膜ＢＮＫの開口の輪郭、及びこの画素の両側に設けられた互いに隣接する一対のゲート信号線ＧＬ並びにこの画素の両側に設けられた互いに隣接する一対のドレイン信号線ＤＬ（ゲート信号線ＧＬの延伸方向に交差して延びる）とにより次のように記される。
【００７１】
前記発光材料層ＦＬＲの輪郭は、（１）前記バンク膜ＢＮＫ開口の前記一対のゲート信号線ＧＬに沿う縁の少なくとも一方から離れ、且つ、（２）前記バンク膜ＢＮＫ開口の前記一対のドレイン信号線ＤＬに沿う縁の少なくとも一方から離れている。基板ＳＵＢ１に対する蒸着マスクの不測の位置ずれから、発光材料層ＦＬＲの一部分がバンク膜ＢＮＫと重なることはあるとしても、その領域の低減に応じた非発光領域の成長抑止が期待される。
【００７２】
発光材料層ＦＬＲの外郭とバンク膜ＢＮＫの縁とを隔てる空間には、対向電極ＣＴを形成する導電性材料が充填される。対向電極ＣＴは、発光材料層ＦＬＲからの光を基板ＳＵＢ１に向けて伝播させる場合、発光材料層ＦＬＲより反射率の高い金属又は合金等の無機材料で形成される。また、発光材料層ＦＬＲからの光を対向電極ＣＴに向けて伝播させる場合、対向電極ＣＴは、発光材料層ＦＬＲより光透過率の高い無機材料（金属や合金の薄膜、又はＩＴＯ，ＩＺＯ等に代表される導電性酸化物の膜）で形成される。いずれの場合も、対向電極ＣＴを形成する導電性材料は、その内部におけるバンク膜ＢＮＫから生じる水分や不純物の拡散を抑え、これらの発光材料層ＦＬＲへの到達を阻む。
【００７３】
発光材料層ＦＬＲの外郭をバンク膜ＢＮＫから離した上述の画素構造では、バンク膜ＢＮＫによる画素電極ＰＸと対向電極ＣＴとの電気的な分離が難しくなる。このような事情に対し、本発明による有機ＥＬ表示装置の断面構造の一例では、発光材料層ＦＬＲが画素電極ＰＸと対向電極ＣＴとを電気的に分離する。このような画素の構造は、図３に示す画素の断面構造を図１に示す画素の平面構造を参照して以下の如く記述される。
【００７４】
（１）前記画素に設けられた前記画素電極ＰＸの輪郭（縁）は、この画素に設けられた前記発光材料層ＦＬＲの輪郭（外郭）の内部に納められる。このように画素電極ＰＸの上面を発光材料層ＦＬＲで覆う画素構造は、この発光材料層ＦＬＲの輪郭（外郭）が、この画素に設けられた前記バンク膜ＢＮＫ開口の内部に収まるように形成されたときに推奨される。
【００７５】
前記画素電極ＰＸが、絶縁層ＩＬ上に形成され且つこの絶縁層ＩＬの下側に設けられたスイッチング素子からの電流又は電荷の出力を絶縁層ＩＬに設けられたスルーホールＴＨ３を通して受けるとき、（２）このスルーホールＴＨ３は、前記画素電極ＰＸ上に形成される前記発光材料層ＦＬＲの輪郭（外郭）の内部にて、この画素電極ＰＸに接続する。この構造も、この発光材料層ＦＬＲの輪郭が、この画素に設けられた前記バンク膜ＢＮＫ開口の内部に収まるように形成されたときに推奨される。
【００７６】
以上に記した画素電極ＰＸと発光材料層ＦＬＲとの配置は、発光材料層ＦＬＲを人為的にバンク膜ＢＮＫ開口の少なくとも一辺に重ならせる場合、不要となる。この場合、画素電極ＰＸを発光材料層ＦＬＲのバンク膜ＢＮＫに重なる部分の輪郭から突出させてもよく、スルーホールＴＨ３が画素電極ＰＸに接する位置を、発光材料層ＦＬＲのバンク膜ＢＮＫに重なる部分の下側に移しても又はその輪郭からバンク膜ＢＮＫの下側に突出させてもよい。
【００７７】
図４は、バンク膜ＢＮＫの開口部と発光材料層ＦＬＲとの位置関係の他の実施例を示す図であり、図１と対応した図となっている。
【００７８】
図１と比較して異なる構成は、発光材料層ＦＬＲの形成の際の前記蒸着マスクがその所定配置から若干ずれてしまい、該発光材料層ＦＬＲがバンク膜ＢＮＫの開口部に対して同様にずれて形成されていることにある。
【００７９】
図４の場合において、前記蒸着マスクはｘ方向のみにずれ、この結果、発光材料層ＦＬＲもｘ方向のみにずれた場合を示しているが、ｙ方向のみに、あるいはｘ方向およびｙ方向の各方向にずれたものであってもよい。
【００８０】
このようにした場合、発光材料層ＦＬＲの各四辺のうち一辺あるいは二辺がバンク膜ＢＮＫに接触することになるが、三辺あるいは四辺がバンク膜ＢＮＫに接触した場合と比較して該発光材料層ＦＬＲの劣化が少ないからである。
【００８１】
このように形成されるためには、精度よい蒸着マスクを用いることによって、発光材料層ＦＬＲを、その面積がバンク膜ＢＮＫの開口部の面積よりも小さく形成するように設定することによってなされる。
【００８２】
また、図５は、バンク膜ＢＮＫの開口部と発光材料層ＦＬＲとの位置関係の他の実施例を示す図であり、図１と対応した図となっている。
【００８３】
この実施例では、赤、青、緑のいずれかの発光材料層ＦＬＲは、たとえばｙ方向に並設される各画素領域に共通に形成されている。このため、該発光材料層ＦＬＲはｙ方向に隣接される他の画素領域の間に配置されるバンク膜ＢＮＫを跨って形成されることになる。
【００８４】
そして、該発光材料層ＦＬＲの幅（各ｙ方向辺との長さ）は、バンク膜ＢＮＫの開口部の幅（各ｙ方向辺との長さ）よりも小さく設定されている。
【００８５】
この場合においても、該発光材料層ＦＬＲの二辺はバンク膜ＢＮＫと接触することになるが、他の残りの二辺はバンク膜ＢＮＫとの接触を回避でき、該発光材料層ＦＬＲの発光劣化を極力避けることができる。
【００８６】
さらに、図６は、バンク膜ＢＮＫの開口部と発光材料層ＦＬＲとの位置関係の他の実施例を示す図であり、図５と対応した図となっている。
【００８７】
図５と比較して異なる構成は、発光材料層ＦＬＲがｘ方向に位置ずれを起して形成されていることにある。
【００８８】
この場合、発光材料層ＦＬＲがバンク膜ＢＮＫと接触していない部分は該バンク膜ＢＮＫの開口部の一辺のみであるが、それだけであっても該発光材料層ＦＬＲの発光劣化を最小限に抑制することができる。
【００８９】
仮に、発光材料層ＦＬＲを一方向に並設された各画素領域に共通に形成するにおいて、その幅がバンク膜ＢＮＫの開口部の幅よりも大きく形成されてしまった場合、該発光材料層ＦＬＲはバンク膜ＢＮＫの開口部の全辺にわたって接触してしまい、該発光材料層ＦＬＲの発光劣化の程度がはげしくなるからである。
【００９０】
《製造方法》
ここで、前記発光材料層ＦＬＲは、次に説明する蒸着マスクを用いて形成されるようになっている。
【００９１】
図７は上記蒸着マスクの一実施例を示す分解斜視図である。図７に示すように前記蒸着マスクは、まずマスク板ＭＰがあり、このマスク板ＭＰは、その周辺においてフレームＦＬに固定されているとともに、該フレームに囲まれた領域内に多数の孔ＨＬが形成されて構成されている。
【００９２】
該マスク板ＭＰの材料としては、たとえばｃｌａｄ鋼板が用いられている。このｃｌａｄ鋼板は、その材料自体の高い剛性に加え、板厚断面における内部応力発生による平面保持剛性が向上したものとなっている。このことは、逆に許容された平面保持特性内で大型の蒸着マスクを作成することを意味する。
【００９３】
図８（ａ）に示すように、該蒸着マスクはたとえば鉄（Ｆｅ）にニッケル（Ｎｉ）を含有させたものからなり、その一面側から他面側にかけて高濃度Ｎｉ含有層、低濃度Ｎｉ含有層、高濃度Ｎｉ含有層というようにＮｉの濃度勾配がなされた３層構造となっている。なお、板厚方向に対する該濃度勾配の関係を図８（ｂ）に示している。
【００９４】
また、前記フレームＦＬはアルミニゥム等の高剛性低膨張率材料から構成され、たとえば溶接、クランプ、あるいは接着等により固着されている。
【００９５】
さらに、マスク板に形成された孔は、図９（ａ）に示すように、高濃度Ｎｉ含有層にて径が小さく、低濃度Ｎｉ含有層にてその中央にいくに従って径が大きく形成されている。これはエッチング液で該孔を形成する場合、Ｆｅを多く含む低濃度Ｎｉ含有層にてエッチング速度が大きくなるからである。
【００９６】
このように該孔の断面がほぼ凹レンズ状の形状となることにより、この孔を通して形成される蒸着層はいわゆるむらのないパターンどおりの形状で形成される効果を有するようになる。
【００９７】
そして、このように構成された蒸着マスクは以下のような物理的特性を有するようになっている。
【００９８】
すなわち、その使用温度範囲１０℃〜３７０℃で平坦度が２０μｍ以下となっている。また、蒸着マスクに対して蒸着物質の蒸着流角度が４５°以下とした場合、該蒸着物質の透過率が９５％以上（蒸着マスクパターンの開口面積を１００％とした場合）となっている。さらに、前記フレームに固着された状態で、温度が１０℃〜３７０℃の範囲にて蒸着マスクパターンのｘ、ｙ方向の変位が±１．０μｍ以下となっている。
【００９９】
さらに、フレームに固着された状態で、常温７×１０^−５Ｐａ以下の真空槽に設置し、３７０℃まで加熱した場合、該蒸着マスク等からのガス放出量が２×１０^−４Ｐａ以下となっている。ただし、蒸着マスクの面積は４８０×３７０ｍｍ^２、フレームの体積は１０３２ｃｍ^２とした場合である。
【０１００】
このように構成される蒸着マスクは、その平坦性の向上から、蒸着むら、混色、画素内の発光分布不均一、蒸着位置ずれを無くすことができるようになる。
【０１０１】
さらに、蒸着マスクがｃｌａｄ鋼板で形成されていることから、その温度上昇時のバイメタルアクションによって、熱膨張による撓みが無く、被蒸着基板（基板ＳＵＢ１）に対する該蒸着マスクの密着力を強固にすることができる効果も奏する。すなわち、該基板に対する蒸着マスクの密着性の不十分による蒸着パターンの精度の劣化を回避することができる。
【０１０２】
ちなみに、この効果を有さない場合、基板に対して蒸着マスクを外力（たとえばマグネット等）によって抑えつけなければならず、該蒸着マスク面側の基板表面の予め形成された素子等（たとえば薄膜トランジスタ）を損傷させるようになる。このことが、本実施例による蒸着マスクは前記素子等の損傷を回避できる効果も奏する。
【０１０３】
本発明による上述の蒸着マスクは、エッチング特性の異なる第１材料（Ｎｉ含有比の高いＮｉ−Ｆｅ合金）と第２材料（Ｎｉ含有比の低いＮｉ−Ｆｅ合金）とを、第１材料からなる第１層、第２材料からなる第２層、及び第１材料からなる第３層の順に積層して形成された板状部材に層厚方向の開口を設けた構造において、非特許文献１に記載された有機ＥＬ用メタルマスクと共通する。しかし、第１層、第２層、及び第３層の厚さの比において、本発明による蒸着マスクと非特許文献１の有機ＥＬ用メタルマスクとは相違する。これにより、非特許文献１の有機ＥＬ用メタルマスクの開口が層厚方向に沿って狭まるのに対して、本発明による蒸着マスクの開口ＨＬは上記第２層にて広がる。この第２層における開口ＨＬの広がりは、開口ＨＬ内における有機材料の蒸気（昇華した有機材料）の第１層から第３層への流れを制御し、基板上に有機材料を無駄なく供給する。
【０１０４】
上記第１層、第２層、及び第３層を、非特許文献１の有機ＥＬ用メタルマスクのキャリア層（材料供給側）、バリア層、及びマスク層（基板側）として、夫々の厚さを図９（ｂ）のｔ_ＣＬ１、ｔ_Ｃｏｒｅ、及びｔ_ＣＬ２とすると、これらの厚さの間にはｔ_ＣＬ１＞ｔ_ＣＬ２＞ｔ_Ｃｏｒｅなる関係がある。このようなキャリア層、バリア層、及びマスク層からなる３層箔（Ｔｒｉｐｌｅ ｌａｙｅｒｅｄ ｆｏｉｌ）を両面から夫々エッチングすることにより、マスク層の開口に比べてキャリア層及びバリア層の開口が拡がるため、マスク層の開口に対して斜め方向から供給される材料の蒸気に対するマスク材の影が抑えられる。
【０１０５】
一方、本発明の蒸着マスクでは、第２層における開口ＨＬの広がりを確保するため、第２層の厚みを第１層及び第３層の厚みに近づけることが重要となる。その望ましき大小関係は、ｔ_Ｃｏｒｅ≧ｔ_ＣＬ１，ｔ_ＣＬ２とも記されるが、ｔ_Ｃｏｒｅをｔ_ＣＬ１やｔ_ＣＬ２の少なくとも一方より小さくしてもよい。但し、ｔ_ＣＬ１に対するｔ_Ｃｏｒｅの値を非特許文献１の有機ＥＬ用メタルマスクのバリア層並に薄くすると、第２層の開口ＨＬの広がりによる有機材料の蒸気流の制御が困難となる。従って、これらの間に、例えば、２ｔ_Ｃｏｒｅ≧ｔ_ＣＬ１，ｔ_ＣＬ２なる関係が成り立つように第１層、第２層、及び第３層の厚さを決めることが望ましい。さらに、第１層の厚さ（ｔ_ＣＬ１）と第３層の厚さ（ｔ_ＣＬ２）との差は、なるべく抑えることが望ましく、両者の間に、例えば、２ｔ_ＣＬ１≧ｔ_ＣＬ２≧（ｔ_ＣＬ１／２）なる関係を成り立たせることが推奨される。
を後有機エレクトロルミネセント材料の蒸着させてもよい。
【０１０６】
図１０は、前記蒸着マスクを介して基板ＳＵＢ１の表面に発光材料層ＦＬＲの材料を蒸着（昇華）する場合のそれらの位置関係を示したものである。
【０１０７】
固定された蒸着マスクに対して基板ＳＵＢ１がその蒸着面を下にして配置されるようになっている。このため、該基板に対する蒸着マスクの密着に要する外力は該基板の自重のみとなっている（図では便宜的に離間させて描いている）。したがって、上述したように該基板ＳＵＢ１の既に数種の層が形成された加工面を損傷させる不都合を解消することができる。
【０１０８】
発光材料層ＦＬＲの材料はその昇華によって該蒸着マスクの孔を通して該基板ＳＵＢ１面に蒸着されるようになる。
【０１０９】
この場合、基板ＳＵＢ１面に形成された発光材料層ＦＬＲは蒸着マスクの孔に対応する箇所に該蒸着マスクの孔のパターンどおりに形成されることになる。換言すれば、該蒸着マスクの孔に対応した精度よい発光材料層ＦＬＲを形成することができる。
【０１１０】
【発明の効果】
以上説明したことから明らかとなるように、本発明による有機ＥＬ表示装置によれば、有機ＥＬ層の発光特性の劣化を抑制できるようになる。
【図面の簡単な説明】
【図１】本発明による有機ＥＬ表示装置の画素の一実施例を示す平面図である。
【図２】本発明による有機ＥＬ表示装置の一実施例を示す平面図である。
【図３】図１のＩＩＩ−ＩＩＩ線における断面図である。
【図４】本発明による有機ＥＬ表示装置の画素の他の実施例を示す平面図である。
【図５】本発明による有機ＥＬ表示装置の画素の他の実施例を示す平面図である。
【図６】本発明による有機ＥＬ表示装置の画素の他の実施例を示す平面図である。
【図７】本発明による有機ＥＬ表示装置の製造に用いられる蒸着マスクの一実施例を示す分解斜視図である。
【図８】本発明による有機ＥＬ表示装置の製造に用いられる蒸着マスクの一実施例を示す構成図である。
【図９】本発明による有機ＥＬ表示装置の製造に用いられる蒸着マスクの孔の一実施例を示す（ａ）構成図、および（ｂ）断面図である。
【図１０】本発明による有機ＥＬ表示装置の製造における基板と蒸着マスクの位置関係を示す構成図である。
【符号の説明】
ＳＵＢ…基板、ＧＬ…ゲート信号線、ＤＬ…ドレイン信号線、ＰＸ…画素電極、ＣＴ…対向電極、ＴＦＴ…薄膜トランジスタ、ＢＮＫ…バンク膜、ＦＬＲ…発光材料層（有機ＥＬ層）。[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an organic EL display device.
[0002]
[Prior art]
For example, in an active matrix type organic EL display device, a plurality of gate signal lines arranged in parallel on the surface of a substrate and a plurality of drain signal lines arranged in parallel to the gate signal lines are formed. The area surrounded by the line is a pixel area.
[0003]
Each pixel region is provided with a thin film transistor operated by a scanning signal from a gate signal line, and a pixel electrode to which a video signal from a drain signal line is supplied via the thin film transistor.
[0004]
The pixel electrode is formed by interposing an organic EL layer together with a counter electrode, and the organic EL layer emits light according to the intensity of current flowing from one of the electrodes to the other electrode. I have.
[0005]
At least one of the pixel electrode and the counter electrode is formed of a light-transmitting conductive layer, so that light from the organic EL layer reaches an observer's eye through the light-transmitting conductive layer. It is configured.
[0006]
Here, the signal lines, the electrodes, and the like are formed by laminating a conductive layer, an insulating layer, a semiconductor layer, and the like formed in a predetermined pattern on the substrate, and these are selectively etched by a so-called photolithography technique. On the other hand, the organic EL layer is usually formed by vapor-depositing an organic EL material through a vapor deposition mask having a hole formed in a portion corresponding to a portion where the organic EL layer is to be formed.
[0007]
In the step of sublimating and vapor-depositing the organic EL material on the substrate, a mask (vapor deposition mask) made of a metal or alloy material is used. An example of a deposition mask and a method for depositing an organic EL layer using the same is disclosed in Non-Patent Document 1 below. This Non-Patent Document 1 discloses a three-layer foil (triple layered clad foil) in which a carrier layer having a thickness of 40 μm, a barrier layer having a thickness of 1 μm, and a mask layer having a thickness of 10 μm are laminated in this order. A vapor deposition mask provided with an opening corresponding to is disclosed. The opening of the evaporation mask is formed to be narrower from the carrier layer to the mask layer, and the opening on the mask layer side (the narrower opening) faces the main surface of the substrate (the surface on which the pixel electrodes and the like are formed). Then, the organic EL material is deposited. The carrier layer and the mask layer are formed of a material selected from 42 alloy (42Ni-Fe Alloy), Invar (36Ni-Fe Alloy), and super Invar (Super Invar, 31Ni-5Co-Fe Alloy). The barrier layer is formed of titanium.
[Non-patent document 1]
Triple layered clad for metal mask for organic EL metal mask, distributed by Hitachi Metals, Ltd.
[0008]
[Problems to be solved by the invention]
However, in the organic EL display device configured as described above, the organic EL layer formed by the vapor deposition mask on the surface of the conductive layer, the insulating layer, or the like finely formed by the photolithography technique has a predetermined position due to its accuracy. It has been pointed out that the case where the pattern is not formed according to a predetermined pattern often occurs. This is because, when the organic EL layer is formed, bending or the like due to a temperature change occurring in the evaporation mask is caused.
[0009]
For this reason, in an organic EL display device in which the substrate itself becomes larger with higher definition of pixels, it is desired to form an organic EL layer with high accuracy.
[0010]
In addition, it has been pointed out that when the organic EL layer is not formed with high accuracy, the light-emitting characteristics of the organic EL layer are deteriorated due to the contact with another material layer (for example, resin).
[0011]
This is because the characteristics of the organic EL layer change due to a chemical reaction caused by contact between the organic EL layer and another material layer.
[0012]
The present invention has been made in view of such circumstances, and an object of the present invention is to provide an organic EL display device that can suppress deterioration of the light emitting characteristics of an organic EL layer.
[0013]
[Means for Solving the Problems]
The following is a brief description of an outline of typical inventions disclosed in the present application.
[0014]
Means 1.
In the organic EL display device according to the present invention, for example, a plurality of gate signal lines juxtaposed on the surface of the substrate and a plurality of drain signal lines juxtaposed to the gate signal lines are formed,
A region surrounded by each of the signal lines is defined as a pixel region. Each pixel region includes a thin film transistor which operates by a scanning signal from a gate signal line, and a pixel to which a video signal from a drain signal line is supplied via the thin film transistor. An electrode, a counter electrode serving as a reference for the video signal, and an organic EL layer sandwiched between the pixel electrode and the counter electrode,
A bank film is formed by covering at least the respective signal lines and exposing the pixel electrode, and the organic EL layer formed above the pixel electrode is formed without contacting the bank film. It is characterized by having been done.
[0015]
Means 2.
In the organic EL display device according to the present invention, for example, a plurality of gate signal lines juxtaposed on the surface of the substrate and a plurality of drain signal lines juxtaposed to the gate signal lines are formed,
A region surrounded by each of the signal lines is defined as a pixel region. Each pixel region includes a thin film transistor which operates by a scanning signal from a gate signal line, and a pixel to which a video signal from a drain signal line is supplied via the thin film transistor. An electrode, a counter electrode serving as a reference for the video signal, and an organic EL layer sandwiched between the pixel electrode and the counter electrode,
A bank film is formed by covering at least the signal lines and exposing the pixel electrode, and the organic EL layer formed above the pixel electrode has three sides other than one side. It is formed without contacting the bank film.
[0016]
Means 3.
In the organic EL display device according to the present invention, for example, a plurality of gate signal lines juxtaposed on the surface of the substrate and a plurality of drain signal lines juxtaposed to the gate signal lines are formed,
A region surrounded by each of the signal lines is defined as a pixel region. Each pixel region includes a thin film transistor which operates by a scanning signal from a gate signal line, and a pixel to which a video signal from a drain signal line is supplied via the thin film transistor. An electrode, a counter electrode serving as a reference for the video signal, and an organic EL layer sandwiched between the pixel electrode and the counter electrode,
A bank film is formed by covering at least each of the signal lines and exposing the pixel electrode, and the organic EL layer formed above the pixel electrode has a structure other than two sides orthogonal to each other. The two sides are formed without contacting the bank film.
[0017]
Means 4.
In the organic EL display device according to the present invention, for example, a plurality of gate signal lines juxtaposed on the surface of the substrate and a plurality of drain signal lines juxtaposed to the gate signal lines are formed,
A region surrounded by each of the signal lines is defined as a pixel region. Each pixel region includes a thin film transistor which operates by a scanning signal from a gate signal line, and a pixel to which a video signal from a drain signal line is supplied via the thin film transistor. An electrode, a counter electrode serving as a reference for the video signal, and an organic EL layer sandwiched between the pixel electrode and the counter electrode,
A bank film formed covering at least the respective signal lines and exposing the pixel electrode is formed,
The organic EL layer is commonly formed for each pixel arranged in one direction, and a side parallel to the one direction is formed without contacting the bank film.
[0018]
Means 5.
In the organic EL display device according to the present invention, for example, a plurality of gate signal lines juxtaposed on the surface of the substrate and a plurality of drain signal lines juxtaposed to the gate signal lines are formed,
A region surrounded by each of the signal lines is defined as a pixel region. Each pixel region includes a thin film transistor which operates by a scanning signal from a gate signal line, and a pixel to which a video signal from a drain signal line is supplied via the thin film transistor. An electrode, a counter electrode serving as a reference for the video signal, and an organic EL layer sandwiched between the pixel electrode and the counter electrode,
A bank film formed covering at least the respective signal lines and exposing the pixel electrode is formed,
The organic EL layer is formed in common for each pixel arranged in one direction, and at least one side parallel to the one direction is formed without contacting the bank film. It is.
[0019]
It should be noted that the present invention is not limited to the above configuration, and various changes can be made without departing from the technical idea of the present invention.
[0020]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the organic EL display device according to the present invention will be described with reference to the drawings.
《Overall configuration》
FIG. 2 is a plan view showing one embodiment of the whole organic EL display device according to the present invention.
First, there is a pair of substrates SUB1 and SUB2 that are arranged to face each other with a slight gap therebetween. The fixing of one substrate SUB1 to the other substrate SUB2 is performed, for example, by a sealing material SL formed around the substrate SUB2. I have.
[0021]
Here, the substrate SUB1 is made of a light-transmitting material such as glass, and the substrate SUB2 is made of a non-light-transmitting material such as metal.
[0022]
On the surface of the one substrate SUB1 on the substrate SUB2 side surrounded by the sealing material SL, the gate signal lines GL extending in the x direction and arranged in the y direction extend in the y direction and are arranged in the x direction. And the provided drain signal line DL.
[0023]
A region surrounded by each gate signal line GL and each drain signal line DL constitutes a pixel region, and a matrix-like aggregate of these pixel regions constitutes an EL display part AR. Therefore, the sealing material SL is formed so as to surround the EL display portion AR.
[0024]
Further, in each of the pixel regions arranged in parallel in the x direction, a common counter voltage signal line CL running in each of the pixel regions is formed. The counter voltage signal line CL is a signal line for supplying a reference voltage for a video signal to a later-described counter electrode CT of each pixel region.
[0025]
It should be noted that the counter voltage signal line CL and the counter electrode CT are formed in the entire area of the EL display part AR, in other words, in the counter area formed in common in each pixel region, as will be apparent from the description of << Pixel Configuration >>. It is constituted by forming the electrode CT, and the boundary with the counter voltage signal line CL cannot be clearly distinguished.
[0026]
In each pixel region, a thin film transistor TFT activated by a scanning signal from one gate signal line GL and a pixel electrode PX to which a video signal from one drain signal line DL is supplied via the thin film transistor TFT are formed. Have been.
[0027]
The pixel electrode PX is formed so as to sandwich the light emitting material layer (organic EL layer) FLR together with the counter electrode CT so that the light emitting material layer FLR emits light in accordance with the intensity of the current flowing through the light emitting material layer FLR. Has become.
[0028]
One end of each of the gate signal lines GL extends beyond the sealing material SL, and the extending end forms a terminal to which an output terminal of the scanning signal drive circuit V is connected. The input terminal of the scanning signal drive circuit V is configured to receive a signal from a printed circuit board (not shown) disposed outside the circuit board SUB1.
[0029]
The scanning signal drive circuit V is composed of a plurality of semiconductor devices, and a plurality of gate signal lines GL adjacent to each other are grouped, and one semiconductor device is assigned to each group. This semiconductor layer is formed of, for example, a semiconductor device of a so-called tape carrier system that is connected across the transparent substrate SUB1 and the printed substrate.
[0030]
Similarly, one end of each of the drain signal lines DL extends beyond the sealing material SL, and the extending end forms a terminal to which an output terminal of the video signal driving circuit He is connected. . The input terminal of the video signal drive circuit He is adapted to receive a signal from a printed circuit board (not shown) disposed outside the circuit board SUB1.
[0031]
The video signal drive circuit He also includes a plurality of semiconductor devices, and a plurality of drain signal lines DL adjacent to each other are grouped, and one semiconductor device is assigned to each of these groups. . This semiconductor layer is formed of, for example, a semiconductor device of a so-called tape carrier system that is connected across the transparent substrate SUB1 and the printed substrate.
[0032]
One of the gate signal lines GL is sequentially selected by a scanning signal from a scanning signal driving circuit V.
[0033]
Further, a video signal is supplied to each of the drain signal lines DL by a video signal driving circuit He in accordance with a timing of selecting the gate signal line GL.
[0034]
In addition, as the semiconductor device constituting the scanning signal drive circuit V and the video signal drive circuit He, a so-called tape carrier type semiconductor device connected across a transparent substrate SUB1 and a printed substrate (not shown) is shown. For example, when the semiconductor device mounted on the transparent substrate SUB1 and the semiconductor layer of the thin film transistor TFT are made of polycrystalline silicon (p-Si), the polycrystalline silicon is formed on the surface of the transparent substrate SUB1. May be formed together with the wiring layer.
[0035]
<< Pixel configuration >>
FIG. 1 is a plan view showing a configuration of one of the pixels arranged in a matrix in an organic EL display device according to the present invention. Therefore, the upper, lower, left and right pixels adjacent to the pixel have the same configuration. FIG. 3 is a sectional view taken along line III-III in FIG.
[0036]
First, an underlayer GW made of, for example, SiO or SiN is formed on the main surface of the transparent substrate SUB1 (see FIG. 3). The underlayer GW is formed in order to prevent ionic impurities contained in the transparent substrate SUB1 from affecting a thin film transistor TFT described later.
[0037]
Then, a semiconductor layer PS made of, for example, a polysilicon layer extending in the x direction is formed at, for example, a lower left portion of the pixel region on the surface of the underlayer GW. This semiconductor layer PS is to be a semiconductor layer of the thin film transistor TFT.
[0038]
Further, an insulating film GI (see FIG. 3) is formed on the surface of the substrate SUB1 so as to cover the semiconductor layer PS. This insulating film GI functions as a gate insulating film in a region where the thin film transistor TFT is formed.
[0039]
On the surface of the insulating film GI, a gate signal line GL extending in the x direction and juxtaposed in the y direction is formed. The gate signal line GL is formed so as to define the pixel region with a drain signal line DL described later.
[0040]
The gate signal line GL partially has an extended portion extending substantially across the center of the semiconductor layer PS, and the extended portion functions as the gate electrode GT of the thin film transistor TFT. It is supposed to.
[0041]
After the formation of the gate electrode GT, impurity ions are implanted by using the mask as a mask, so that the resistance of the semiconductor layer PS in other regions except the region immediately below the gate electrode GT is reduced.
[0042]
An insulating film IN (see FIG. 3) is formed on the surface of the transparent substrate SUB so as to cover the gate signal line GL (gate electrode GT). The insulating film IN has a function as an interlayer insulating film for the gate signal line GL in a region where a drain signal line DL described later is formed.
[0043]
Then, on the surface of the insulating film IN, a drain signal line DL extending in the y direction and juxtaposed in the x direction is formed. A part of the drain signal line DL extends to one end of the semiconductor layer PS adjacent to the drain signal line DL. It is connected. That is, the extending portion of the drain signal line DL functions as the drain electrode SD1 of the thin film transistor TFT.
[0044]
At the other end of the semiconductor layer PS, a source electrode SD2 penetrating the insulating film IN and the insulating film GI and connected through a through-hole TH2 formed in advance is formed. The source electrode SD2 is a pixel electrode to be described later. It has an extended portion with a relatively large area for connection with the PX.
[0045]
The insulating film IL (see FIG. 3) is formed on the surface of the substrate SUB on which the drain signal line DL (drain electrode SD1) and the source electrode SD2 are formed.
[0046]
On the upper surface of the insulating film IL, a pixel electrode PX is formed at the center of each of the pixel regions except for a slight periphery thereof. Is connected to
[0047]
The pixel electrode PX guides light from a light emitting material layer FLR described later to the transparent substrate SUB1 side. For example, ITO (Indium Tin Oxide), ITZO (Indium Tin Zinc Oxide), IZO (Indium Zinc Oxide), SnO ₂ (Tin oxide), In ₂ O ₃ (Indium oxide) and the like.
[0048]
Further, on the surface of the transparent substrate SUB1 on which the pixel electrode PX is formed, a bank film BNK which slightly covers a peripheral portion of the pixel electrode PX and exposes a central portion thereof is formed. The bank film BNK is made of, for example, an organic material layer and is formed integrally with the bank film BNK of another adjacent pixel region.
[0049]
The bank film BNK divides the light emitting material layer FLR for each pixel, extracts light having a desired luminance from each of the adjacent pixels, and forms a counter electrode, which will be described later, from the pixel electrode PX provided for each pixel through the light emitting material layer FLR. It is provided to separate a current path or a charge path leading to the electrode CT for each pixel. In other words, the bank film BNK optically or electrically separates between pixels (in some cases, between pixel rows or pixel columns). The electrical isolation between pixels by the bank film BNK is performed by covering a light emitting material layer FLR of a plurality of pixels in which a later-described counter electrode CT is two-dimensionally arranged in the main surface of the substrate (TN-TFT type liquid crystal display device). This is effective for an organic EL display device formed like the common electrode described above.
[0050]
Further, a light emitting material layer FLR is formed on the opening of the bank film BNK, that is, on the surface of the pixel electrode PX exposed from the bank film BNK. In the case of this embodiment, the light emitting material layer FLR is made of a light emitting material layer exhibiting any one of red, blue and green colors, and is physically separated from the light emitting material layer of another adjacent pixel region. It is formed independently in the pixel area.
[0051]
The light emitting material layer FLR is formed without the periphery thereof being in contact with the side wall surface of the opening of the bank film BNK. In other words, the light emitting material layers FLR are arranged so that their centers are substantially aligned in the opening of the bank film BNK, and the width in the x direction and the width in the y direction are respectively equal to the opening of the bank film BNK. The width of the portion is slightly smaller than the width in the x direction and the width in the y direction.
[0052]
In order to form the light emitting material layer FLR in this manner, the light emitting material of the light emitting material layer FLR is deposited through a mask. For example, a mask which does not bend due to thermal expansion is used, and a pattern of holes formed in the mask is used. It is necessary to form the pattern of the light emitting material layer FLR in the same manner as described above. This will be described later.
[0053]
The light emitting material layer FLR may of course be formed at least between the pixel electrode PX and a layer called a hole injection layer. This is because light emission efficiency can be improved.
[0054]
A common electrode CT common to each pixel region is formed on the upper surface of the light emitting material layer FLR. The counter electrode CT is made of, for example, a metal material such as aluminum, and a reference voltage is applied to a video signal line supplied to the pixel electrode PX.
[0055]
Needless to say, the light emitting material layer FLR may be formed at least between the counter electrode CT and a layer called an electron injection layer. This is because light emission efficiency can be improved.
[0056]
Here, in this specification, the light emitting material layer FLR is referred to as a light emitting material layer FLR regardless of whether the hole injection layer or the electron injection layer is formed.
[0057]
The light emitting material layer FLR used here is formed of an organic material exhibiting electroluminescence belonging to a group called a low molecular weight system (organic electroluminescent material, Electroluminescent Material). Since the organic materials belonging to this group have a relatively low molecular weight, they can be sublimated without breaking the molecular structure. On the other hand, another group of the organic electroluminescent materials that are difficult to sublimate is called a polymer system. In any organic electroluminescent material, the wavelength of the electroluminescence (the emission wavelength from the organic electroluminescent material) is determined according to the molecular structure (electronic state), so that the organic EL display device that displays a color image In, the organic electroluminescent material forming the light emitting material layer FLR is changed for each of the red (R), green (G), and blue (B) pixels.
[0058]
As an example of a low-molecular-weight organic electroluminescent material exhibiting red electroluminescence, BPPC (N, N'-bis- (2,5-di-tert-butylphenyl) 3,4,9,10-perylenedicarboxylicboximide) There is. This material has the molecular structure shown in [Formula 1].
[0059]
Embedded image

[0060]
One example of a low-molecular organic electroluminescent material that exhibits green electroluminescence is Alq3 (8-hydroxyquinoline aluminum). This material has the molecular structure shown in [Formula 2].
[0061]
Embedded image

[0062]
An example of a low molecular weight organic electroluminescent material exhibiting blue electroluminescence is PPCP (1,2,3,4,5-pentaphenyl-1,3-cyclopentadiene). This material has a molecular structure represented by Chemical Formula 3.
[0063]
Embedded image

[0064]
According to the video signal supplied to the pixel electrode PX, a current flows through the light emitting material layer FLR interposed between the counter electrodes CT, and the light emitting material layer FLR emits light according to the current value. The light LL is emitted to the observer via the pixel electrode PX, the insulating film IL, the insulating film IN, the insulating film GI, and the transparent substrate SUB1.
[0065]
<< Position relationship between opening of bank film and light emitting material layer >>
Here, as described above, the light emitting material layer FLR is formed so as to overlap the upper surface of the pixel electrode PX exposed from the opening of the bank film BNK. In this embodiment, for example, one independent light emitting material layer FLR is provided in one pixel, and the periphery of the light emitting material layer FLR has a slight gap between itself and the side wall surface of the opening of the bank film BNK. However, the bank film BNK is formed without contacting the side wall surface of the opening.
[0066]
If a part of the light emitting material layer FLR is formed in contact with the bank film BNK, those materials chemically react with each other, and after a long time, the light emitting material layer FLR causes light emission deterioration. It is because.
[0067]
That is, the length and width of the light-emitting material layer FLR are set to be smaller than the length and width of the opening of the bank film BNK, and the center thereof substantially coincides with the center of the opening of the bank film BNK. It is attached and formed.
[0068]
In this case, since the opening of the bank film BNK is usually formed by a selective etching method using a photolithography technique, the vertical and horizontal dimensions of the opening can be accurately set due to its nature. However, since the luminescent material layer FLR is usually formed by depositing a luminescent material scattered through the holes with a deposition mask having a hole formed in the metal plate interposed therebetween, for example, the deposition mask may be bent. When this occurs, the vertical and horizontal dimensions may not be formed as specified.
[0069]
However, in the present embodiment, since a specially designed mask is used as the vapor deposition mask, it can be formed according to the pattern of the holes of the vapor deposition mask including the dimensions, and the bank film BNK of the light emitting material layer FLR can be formed. It is possible to avoid light emission deterioration caused by contact with the light emitting device. This vapor deposition mask will be described later in detail.
[0070]
In the vapor deposition of an organic electroluminescent material using a vapor deposition mask described later, the position of the light emitting material layer FLR formed by the vapor deposition can be accurately controlled. Therefore, in an example of the planar structure of the organic EL display device reflecting this advantage, the overlap between the light emitting material layer FLR and the bank film BNK in the pixel can be reduced or eliminated. Such a structure is particularly effective in suppressing the deterioration of the light emitting material layer FLR due to dehydration or degassing from the bank film BNK formed of an organic material and the growth of the non-light emitting region caused thereby. Examples of the structure of such a pixel include a contour of the light emitting material layer FLR formed thereon, a contour of the opening of the bank film BNK, a pair of adjacent gate signal lines GL provided on both sides of the pixel, and A pair of adjacent drain signal lines DL (extending in the direction in which the gate signal lines GL extend) provided on both sides of the pixel is described as follows.
[0071]
The outline of the light emitting material layer FLR is (1) separated from at least one of edges of the opening of the bank film BNK along the pair of gate signal lines GL, and (2) the pair of drain signals of the opening of the bank film BNK. It is separated from at least one of the edges along the line DL. Even if a part of the light emitting material layer FLR overlaps with the bank film BNK due to an unexpected positional shift of the deposition mask with respect to the substrate SUB1, growth suppression of a non-light emitting region is expected in accordance with the reduction of the region.
[0072]
The space separating the outer periphery of the light emitting material layer FLR and the edge of the bank film BNK is filled with a conductive material forming the counter electrode CT. When propagating light from the light emitting material layer FLR toward the substrate SUB1, the counter electrode CT is formed of an inorganic material such as a metal or an alloy having a higher reflectance than the light emitting material layer FLR. In the case where light from the light emitting material layer FLR is propagated toward the counter electrode CT, the counter electrode CT is formed of an inorganic material having a higher light transmittance than the light emitting material layer FLR (a thin film of metal or alloy, or a thin film of ITO, IZO, or the like). Representative conductive oxide film). In any case, the conductive material forming the counter electrode CT suppresses diffusion of moisture and impurities generated from the bank film BNK inside the counter electrode CT, and prevents them from reaching the light emitting material layer FLR.
[0073]
In the above-described pixel structure in which the outline of the light emitting material layer FLR is separated from the bank film BNK, it becomes difficult to electrically separate the pixel electrode PX and the counter electrode CT by the bank film BNK. Under such circumstances, in an example of the cross-sectional structure of the organic EL display device according to the present invention, the light emitting material layer FLR electrically separates the pixel electrode PX from the counter electrode CT. Such a pixel structure is described as follows with reference to the cross-sectional structure of the pixel shown in FIG. 3 and the planar structure of the pixel shown in FIG.
[0074]
(1) The outline (edge) of the pixel electrode PX provided in the pixel is accommodated inside the outline (outline) of the light emitting material layer FLR provided in the pixel. As described above, the pixel structure in which the upper surface of the pixel electrode PX is covered with the light-emitting material layer FLR is formed such that the contour (outline) of the light-emitting material layer FLR fits inside the opening of the bank film BNK provided in the pixel. Recommended when
[0075]
When the pixel electrode PX is formed on the insulating layer IL and receives a current or charge output from a switching element provided below the insulating layer IL through a through hole TH3 provided in the insulating layer IL, 2) The through hole TH3 is connected to the pixel electrode PX inside the contour (outer) of the light emitting material layer FLR formed on the pixel electrode PX. This structure is also recommended when the contour of the light emitting material layer FLR is formed so as to fit inside the opening of the bank film BNK provided in the pixel.
[0076]
The arrangement of the pixel electrode PX and the light emitting material layer FLR described above becomes unnecessary when the light emitting material layer FLR is artificially overlapped with at least one side of the opening of the bank film BNK. In this case, the pixel electrode PX may be made to protrude from the contour of the portion of the light emitting material layer FLR overlapping the bank film BNK, and the position where the through hole TH3 is in contact with the pixel electrode PX is determined by the portion of the light emitting material layer FLR overlapping the bank film BNK. Of the bank film BNK from the outline thereof.
[0077]
FIG. 4 is a diagram showing another embodiment of the positional relationship between the opening of the bank film BNK and the light emitting material layer FLR, and corresponds to FIG.
[0078]
The configuration different from that in FIG. 1 is that the vapor deposition mask at the time of forming the light emitting material layer FLR is slightly shifted from its predetermined position, and the light emitting material layer FLR is similarly shifted from the opening of the bank film BNK. Is formed.
[0079]
In the case of FIG. 4, the case where the vapor deposition mask is shifted only in the x direction, and as a result, the light emitting material layer FLR is also shifted only in the x direction, is shown only in the y direction, or in each of the x and y directions. It may be shifted in the direction.
[0080]
In this case, one or two sides of each of the four sides of the light emitting material layer FLR come into contact with the bank film BNK, but the light emitting material is compared with the case where three or four sides come into contact with the bank film BNK. This is because deterioration of the layer FLR is small.
[0081]
In order to form the light emitting material layer FLR in this manner, the light emitting material layer FLR is set to have a smaller area than the opening area of the bank film BNK by using an accurate evaporation mask.
[0082]
FIG. 5 is a view showing another embodiment of the positional relationship between the opening of the bank film BNK and the light emitting material layer FLR, and corresponds to FIG.
[0083]
In this embodiment, any one of the red, blue, and green light emitting material layers FLR is commonly formed in, for example, each pixel region arranged in the y direction. Therefore, the light emitting material layer FLR is formed across the bank film BNK disposed between other pixel regions adjacent in the y direction.
[0084]
The width (length with each y-direction side) of the light emitting material layer FLR is set smaller than the width (length with each y-direction side) of the opening of the bank film BNK.
[0085]
Also in this case, two sides of the light emitting material layer FLR come into contact with the bank film BNK, but the other two sides can avoid contact with the bank film BNK, and light emission deterioration of the light emitting material layer FLR is prevented. Can be avoided as much as possible.
[0086]
FIG. 6 is a view showing another embodiment of the positional relationship between the opening of the bank film BNK and the light emitting material layer FLR, and corresponds to FIG.
[0087]
The configuration different from FIG. 5 is that the light emitting material layer FLR is formed with a positional shift in the x direction.
[0088]
In this case, the portion where the light emitting material layer FLR is not in contact with the bank film BNK is only one side of the opening of the bank film BNK. can do.
[0089]
If the light emitting material layer FLR is formed in common in each pixel region arranged in one direction, if the width of the light emitting material layer FLR is formed larger than the width of the opening of the bank film BNK, the light emitting material layer FLR is formed. Is in contact with all sides of the opening of the bank film BNK, and the degree of light emission deterioration of the light emitting material layer FLR becomes severe.
[0090]
"Production method"
Here, the light emitting material layer FLR is formed using an evaporation mask described below.
[0091]
FIG. 7 is an exploded perspective view showing one embodiment of the vapor deposition mask. As shown in FIG. 7, the vapor deposition mask includes a mask plate MP. The mask plate MP is fixed to a frame FL around the mask plate MP, and a large number of holes HL are formed in a region surrounded by the frame. It is formed and configured.
[0092]
As a material of the mask plate MP, for example, a clad steel plate is used. This clad steel sheet has improved rigidity of holding a plane due to generation of internal stress in a cross section of the sheet thickness, in addition to high rigidity of the material itself. This in turn means creating a large deposition mask within the allowed plane retention characteristics.
[0093]
As shown in FIG. 8A, the deposition mask is made of, for example, iron (Fe) containing nickel (Ni), and has a high-concentration Ni-containing layer and a low-concentration Ni-containing layer from one side to the other side. It has a three-layer structure in which the concentration gradient of Ni is made such as a layer and a high-concentration Ni-containing layer. FIG. 8B shows the relationship between the density gradient and the thickness direction.
[0094]
The frame FL is made of a high-rigidity, low-expansion material such as aluminum, and is fixed by, for example, welding, clamping, or bonding.
[0095]
Further, as shown in FIG. 9A, the hole formed in the mask plate has a smaller diameter in the high-concentration Ni-containing layer and a larger diameter in the center of the low-concentration Ni-containing layer. I have. This is because when the holes are formed with an etchant, the etching rate is increased in the low-concentration Ni-containing layer containing a large amount of Fe.
[0096]
Since the cross section of the hole has a substantially concave lens shape as described above, the vapor deposited layer formed through the hole has an effect of being formed in a so-called uniform pattern.
[0097]
Then, the vapor deposition mask thus configured has the following physical characteristics.
[0098]
That is, the flatness is 20 μm or less in the operating temperature range of 10 ° C. to 370 ° C. When the deposition flow angle of the deposition material with respect to the deposition mask is 45 ° or less, the transmittance of the deposition material is 95% or more (when the opening area of the deposition mask pattern is 100%). Further, the displacement in the x and y directions of the deposition mask pattern is ± 1.0 μm or less when the temperature is in a range of 10 ° C. to 370 ° C. in a state of being fixed to the frame.
[0099]
Further, in a state of being fixed to the frame, a room temperature of 7 × 10 ^-5 When placed in a vacuum chamber of Pa or lower and heated to 370 ° C., the amount of gas released from the deposition mask or the like is 2 × 10 ^-4 Pa or less. However, the area of the evaporation mask is 480 × 370 mm ² , Frame volume is 1032cm ² Is the case.
[0100]
The deposition mask configured as described above can eliminate unevenness of deposition, color mixture, non-uniform light emission distribution in a pixel, and displacement of a deposition position due to improvement in flatness.
[0101]
Further, since the vapor deposition mask is formed of a clad steel plate, there is no bending due to thermal expansion due to the bimetal action when the temperature rises, and the adhesion of the vapor deposition mask to the substrate (substrate SUB1) is strengthened. The effect which can be performed also plays. That is, it is possible to avoid deterioration of the accuracy of the deposition pattern due to insufficient adhesion of the deposition mask to the substrate.
[0102]
By the way, when this effect is not provided, the vapor deposition mask must be suppressed against the substrate by an external force (for example, a magnet or the like). Will damage you. This has the effect that the vapor deposition mask according to the present embodiment can avoid damage to the elements and the like.
[0103]
In the above-described vapor deposition mask according to the present invention, a first material (a Ni-Fe alloy having a high Ni content) and a second material (a Ni-Fe alloy having a low Ni content) having different etching characteristics are made of the first material. Non-Patent Document 1 discloses a structure in which a plate-shaped member formed by laminating a first layer, a second layer made of a second material, and a third layer made of the first material in the order of thickness is provided. It is common to the described metal mask for organic EL. However, the thickness ratio of the first layer, the second layer, and the third layer is different from the vapor deposition mask according to the present invention and the metal mask for organic EL of Non-Patent Document 1. Thereby, while the opening of the metal mask for organic EL of Non-Patent Document 1 narrows along the layer thickness direction, the opening HL of the vapor deposition mask according to the present invention expands in the second layer. The expansion of the opening HL in the second layer controls the flow of the vapor (sublimated organic material) of the organic material from the first layer to the third layer in the opening HL, and supplies the organic material onto the substrate without waste. .
[0104]
The first layer, the second layer, and the third layer serve as a carrier layer (material supply side), a barrier layer, and a mask layer (substrate side) of the metal mask for organic EL of Non-Patent Document 1, respectively. To t in FIG. 9 (b). _CL1 , T _Core , And t _CL2 Then, between these thicknesses, t _CL1 > T _CL2 > T _Core There is a relationship. By etching such a triple layered foil composed of a carrier layer, a barrier layer, and a mask layer from both sides, the openings of the carrier layer and the barrier layer are wider than the openings of the mask layer. The shadow of the mask material on the vapor of the material supplied obliquely to the opening of the layer is suppressed.
[0105]
On the other hand, in the vapor deposition mask of the present invention, it is important to make the thickness of the second layer closer to the thicknesses of the first and third layers in order to secure the widening of the opening HL in the second layer. The desired size relationship is t _Core ≧ t _CL1 , T _CL2 Is also written as _Core To t _CL1 And t _CL2 May be smaller than at least one of the following. Where t _CL1 T for _Core Is thinner than the barrier layer of the organic EL metal mask of Non-Patent Document 1, it becomes difficult to control the vapor flow of the organic material due to the spread of the opening HL of the second layer. Therefore, for example, 2t _Core ≧ t _CL1 , T _CL2 It is desirable to determine the thickness of the first layer, the second layer, and the third layer so that the following relationship is satisfied. Further, the thickness of the first layer (t _CL1 ) And the thickness of the third layer (t _CL2 ) Is desirably suppressed as much as possible. _CL1 ≧ t _CL2 ≧ (t _CL1 / 2) is recommended.
May be subsequently deposited with an organic electroluminescent material.
[0106]
FIG. 10 shows the positional relationship when the material of the light emitting material layer FLR is deposited (sublimated) on the surface of the substrate SUB1 via the deposition mask.
[0107]
The substrate SUB1 is arranged with its deposition surface down with respect to the fixed deposition mask. For this reason, the external force required for bringing the deposition mask into close contact with the substrate is only the own weight of the substrate (illustrated separately for convenience in the drawing). Therefore, the inconvenience of damaging the processed surface of the substrate SUB1 on which several types of layers have been formed as described above can be solved.
[0108]
The material of the light emitting material layer FLR is deposited on the surface of the substrate SUB1 through the holes of the deposition mask by sublimation.
[0109]
In this case, the light emitting material layer FLR formed on the surface of the substrate SUB1 is formed at a position corresponding to the hole of the vapor deposition mask according to the pattern of the hole of the vapor deposition mask. In other words, an accurate light emitting material layer FLR corresponding to the hole of the evaporation mask can be formed.
[0110]
【The invention's effect】
As is apparent from the above description, according to the organic EL display device of the present invention, it is possible to suppress the deterioration of the light emitting characteristics of the organic EL layer.
[Brief description of the drawings]
FIG. 1 is a plan view showing one embodiment of a pixel of an organic EL display device according to the present invention.
FIG. 2 is a plan view showing an embodiment of the organic EL display device according to the present invention.
FIG. 3 is a sectional view taken along line III-III in FIG. 1;
FIG. 4 is a plan view showing another embodiment of the pixel of the organic EL display device according to the present invention.
FIG. 5 is a plan view showing another embodiment of the pixel of the organic EL display device according to the present invention.
FIG. 6 is a plan view showing another embodiment of the pixel of the organic EL display device according to the present invention.
FIG. 7 is an exploded perspective view showing one embodiment of a deposition mask used for manufacturing an organic EL display device according to the present invention.
FIG. 8 is a configuration diagram showing one embodiment of a deposition mask used for manufacturing an organic EL display device according to the present invention.
FIGS. 9A and 9B are a configuration diagram and a cross-sectional view illustrating an embodiment of a hole of a vapor deposition mask used for manufacturing an organic EL display device according to the present invention. FIGS.
FIG. 10 is a configuration diagram showing a positional relationship between a substrate and a deposition mask in manufacturing an organic EL display device according to the present invention.
[Explanation of symbols]
SUB: substrate, GL: gate signal line, DL: drain signal line, PX: pixel electrode, CT: counter electrode, TFT: thin film transistor, BNK: bank film, FLR: light emitting material layer (organic EL layer).

Claims (5)

A plurality of gate signal lines juxtaposed on the surface of the substrate and a plurality of drain signal lines juxtaposed to intersect these gate signal lines are formed,
A region surrounded by each of the signal lines is defined as a pixel region. Each pixel region includes a thin film transistor which operates by a scanning signal from a gate signal line, and a pixel to which a video signal from a drain signal line is supplied via the thin film transistor. An electrode, a counter electrode serving as a reference for the video signal, and an organic EL layer sandwiched between the pixel electrode and the counter electrode,
A bank film is formed by covering at least the respective signal lines and exposing the pixel electrode, and the organic EL layer formed above the pixel electrode is formed without contacting the bank film. An organic EL display device, comprising: A plurality of gate signal lines juxtaposed on the surface of the substrate and a plurality of drain signal lines juxtaposed to intersect these gate signal lines are formed,
A region surrounded by each of the signal lines is defined as a pixel region. Each pixel region includes a thin film transistor which operates by a scanning signal from a gate signal line, and a pixel to which a video signal from a drain signal line is supplied via the thin film transistor. An electrode, a counter electrode serving as a reference for the video signal, and an organic EL layer sandwiched between the pixel electrode and the counter electrode,
A bank film is formed by covering at least the signal lines and exposing the pixel electrode, and the organic EL layer formed above the pixel electrode has three sides other than one side. An organic EL display device formed without contacting the bank film. A plurality of gate signal lines juxtaposed on the surface of the substrate and a plurality of drain signal lines juxtaposed to intersect these gate signal lines are formed,
A region surrounded by each of the signal lines is defined as a pixel region. Each pixel region includes a thin film transistor which operates by a scanning signal from a gate signal line, and a pixel to which a video signal from a drain signal line is supplied via the thin film transistor. An electrode, a counter electrode serving as a reference for the video signal, and an organic EL layer sandwiched between the pixel electrode and the counter electrode,
A bank film is formed by covering at least each of the signal lines and exposing the pixel electrode, and the organic EL layer formed above the pixel electrode has a structure other than two sides orthogonal to each other. An organic EL display device, wherein two sides are formed without contacting the bank film. A plurality of gate signal lines juxtaposed on the surface of the substrate and a plurality of drain signal lines juxtaposed to intersect these gate signal lines are formed,
A region surrounded by each of the signal lines is defined as a pixel region. Each pixel region includes a thin film transistor which operates by a scanning signal from a gate signal line, and a pixel to which a video signal from a drain signal line is supplied via the thin film transistor. An electrode, a counter electrode serving as a reference for the video signal, and an organic EL layer sandwiched between the pixel electrode and the counter electrode,
A bank film formed covering at least the respective signal lines and exposing the pixel electrode is formed,
The organic EL display device, wherein the organic EL layer is formed in common for each pixel arranged in one direction, and a side parallel to the one direction is formed without contacting the bank film. A plurality of gate signal lines juxtaposed on the surface of the substrate and a plurality of drain signal lines juxtaposed to intersect these gate signal lines are formed,
A region surrounded by each of the signal lines is defined as a pixel region. Each pixel region includes a thin film transistor which operates by a scanning signal from a gate signal line, and a pixel to which a video signal from a drain signal line is supplied via the thin film transistor. An electrode, a counter electrode serving as a reference for the video signal, and an organic EL layer sandwiched between the pixel electrode and the counter electrode,
A bank film formed covering at least the respective signal lines and exposing the pixel electrode is formed,
The organic EL layer is commonly formed for each pixel arranged in one direction, and at least one side parallel to the one direction is formed without contacting the bank film. EL display device.

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