JP4123758B2 - Light emitting device - Google Patents

Description

このうち試料５の蛍光体は次のように合成した。即ち、下記原料
BaCO3:0.3molx0.1 5.92g SrCO3:0.3molx0.1 4.42g
CaCO3:0.3molx0.1 3.00g MgCO3:1molx0.1 8.43g
SiO2:1molx0.1 6.01g Eu2O3:0.1molx0.05 1.76g
NH4Cl:0.1g
を秤取り，必要な量を充分に良く混合した後、この混合物を熔融アルミナルツボ等の耐熱容器に充填し、空気中８００℃で、次いで５％水素混合窒素ガス雰囲気中１２５０℃の温度で焼成する。この焼成物は粉砕後、水洗、乾燥を行ない青色発光蛍光体を得た。この他の蛍光体も同様にして合成した。その後，１４７ｎｍ真空紫外線励起下での同蛍光体の発光輝度を現行蛍光体ＢＡＭのそれを１００％とした場合の各試料の相対発光強度を求めた。その結果は，表１に示すとおり，１００％〜１１５％である。また，これらの蛍光体の寿命特性が，比較試料より向上していることを確認した。
［実施例２］
先に述べた原料を用い，同様な合成プロセスに従い表２に記載したＣａ，Ｓｒ，Ｂａ，そしてＭｇまたはＺｎで一部置換した蛍光体(試料９〜２０)を合成した。これらの蛍光体はいずれも１４７ｎｍ紫外線励起下で比較的に高い発光輝度を有するものであることがわかった。具体的な発光強度は，表２に示す。また，これらの蛍光体の寿命特性は，比較試料より向上していることを確認した。
［実施例３］
青色蛍光膜を構成する青色蛍光体として本発明による２価ユ−ロピウム付活アルカリ土類珪酸塩蛍光体（表１及び２に示す組成）を用いてプラズマディスプレイパネル（ＰＤＰ）を作製した。
【０００９】
【表２】

本実施の形態のような面放電型カラーＰＤＰのＰＤＰでは，例えば，表示電極（一般に，走査電極と呼ぶ。）に負の電圧を，アドレス電極と表示電極に正の電圧（表示電極に印加される電圧に比して正の電圧）を印加することにより放電が発生し，これにより，表示電極間で放電を開始するための補助となる壁電荷が形成される（これを書き込みと称する。）この状態で表示電極と表示電極との間に，適当な逆の電圧を印加すると，誘電体（及び保護層）を介して，両電極の間の放電空間で放電が発生する。放電終了後，表示電極と表示電極とに印加する電圧を逆にすると，新たに放電が発生する。これを繰り返すことにより継続的に放電が発生する（これを維持放電又は表示放電と呼ぶ）。
【００１０】
本実施の形態のＰＤＰは，背面基板上に，銀などで構成されているアドレス電極と，ガラス系の材料で構成される誘電体層を形成した後，同じくガラス系の材料で構成される隔壁材を厚膜印刷し，ブラストマスクを用いて，ブラスト除去により，隔壁を形成する。次に，この隔壁上に，赤，緑，青の各蛍光体層を該当する隔壁間の溝面を被覆する形で，順次ストライプ状に形成する。
【００１１】
ここで，各蛍光体層は，赤，緑，青に対応し，赤蛍光体粒子４０重量部（ビヒクル６０重量部），緑蛍光体粒子３５重量部（ビヒクル６５重量部），青蛍光体粒子３５重量部（ビヒクル６５重量部）とし，それぞれビヒクルと混ぜて蛍光体ペーストとし，スクリーン印刷により塗布したあと，乾燥及び焼成工程により蛍光体ペースト内の揮発成分の蒸発と有機物の燃焼除去を行って形成する。なお，本実施の形態で用いた蛍光体層は，中央粒径が３μｍの各蛍光体粒子で構成されている。
【００１２】
また，各蛍光体の材料は，赤蛍光体は(Y,Gd)BO3:Eu蛍光体とY2O3:Eu蛍光体１：１の混合物であり，緑蛍光体はZn2SiO4:Mn蛍光体である。
【００１３】
次に,表示電極，バス電極，誘電体層，保護層を形成した前面基板と，背面基板をフリット封着し，パネル内を真空排気した後放電ガスを注入し封止する。本実施の形態のＰＤＰは，そのサイズが３型で一画素のピッチが１０００μｍｘ１０００μｍである。
次に，実施例１及び２で形成した各蛍光体を用いて，赤，緑光体は同一の材料を使用し，各蛍光体層２５に充填したプラズマディスプレイ装置を作製し，初期輝度及び寿命特性を調べた。
このパネルは青色蛍光体のみを２価ユ−ロピウム付活アルミン酸バリウム・マグネシウム蛍光体に換えて製作した従来品に比較して色調がよく、かつ高輝度で長寿命を有するものであった。
初期輝度は，表２の各蛍光体に関し記載した粉体の相対発光強度とほぼ同等の結果が得られた。また寿命性能では，すべての蛍光体（表１及び表２に示すすべての組成）が，比較蛍光体を上回る結果を示した。
また，この実施例では赤及び緑の蛍光体に関して，詳細な検討結果を示していないが，以下に示す各組成の蛍光体でも同様にＰＤＰを作製することができる。
【００１４】
赤蛍光体では，(Y,Gd)BO3:Eu，(Y,Gd)2O3:Eu,(Y,Gd)(P,V)O4:Euのいずれか一種以上の蛍光体を含む場合が可能である。また，緑蛍光体は， Zn2SiO4:Mn，(Y,Gd,Sc)2SiO5:Tb,(Y,Gd)3(Al,Ga)5O12:Tb，(Y,Gd)3(Al,Ga)5O12:Ce,(Y,Gd)B3O6:Tb，（Y,Gd）PO4：Tbの群から選ばれた一種以上の蛍光体を含む場合が可能である。さらに，ここに示していない蛍光体との組合せも適用できる。
［実施例４］
青色蛍光体色として本発明による２価ユ−ロピウム付活アルカリ土類珪酸塩蛍光体（表１に示す組成）を，緑色蛍光体として２価マンガン付活珪酸亜鉛蛍光体を，そして赤色蛍光体には３価ユ−ロピウム付活酸化イットリウム・ガドリニウム蛍光体を用いて希ガス(キセノンガス)放電白色蛍光ランプを製作した。 このランプは青色蛍光体のみを２価ユ−ロピウム付活アルミン酸バリウム・マグネシウム蛍光体に換えて製作した従来品に比較して高発光効率かつ長寿命を有するものであった。
［実施例５］
青色蛍光体として本発明による２価ユ−ロピウム付活アルカリ土類珪酸塩蛍光体（表２に示す組成）を，緑色蛍光体として２価マンガン付活珪酸亜鉛蛍光体を，そして赤色蛍光体には３価ユ−ロピウム付活酸化イットリウム・ガドリニウム蛍光体を用いて平面型希ガス(キセノンガス)放電白色蛍光ランプを製作した。このランプは青色蛍光体のみを２価ユ−ロピウム付活アルミン酸バリウム・マグネシウム蛍光体に換えて製作した従来品に比較して高発光効率かつ長寿命を有するものであった。
［実施例６］
ここでは，まず蛍光膜を形成するガラス基板の内面に均一な透明電極を形成した。次に、青色蛍光膜を構成する青色蛍光体として本発明による２価ユ−ロピウム付活アルカリ土類珪酸塩蛍光体（表１及び表２に示す組成）を，緑色蛍光膜を構成する緑色蛍光体として２価マンガン付活珪酸亜鉛蛍光体を，そして赤色蛍光膜を構成する赤色蛍光体として３価ユ−ロピウム付活酸化イットリウム・ガドリニウム蛍光体を順次形成した。このガラス基板と微少な電子線源が作り込んであるもう一つのガラス基板を合わせて封着し，真空排気後に１０型の電界放射型ディスプレイ（ＦＥＤ）パネルを製作した。このパネルは従来の青色蛍光体のみを２価ユ−ロピウム付活アルミン酸バリウム・マグネシウム蛍光体に換えて製作したＦＥＤパネルより高効率，かつ長寿命の特性を示した。このパネルを用いて，表示パネルを構成し，テレビ，ビデオ，自動車などのディスプレイシステムとして使用したところ，良い表示品質が得られることを確認した。
上述の通り、真空紫外領域紫外線および低速電子線励起下において効率の高い青色蛍光体［２価ユ−ロピウム付活アルカリ土類珪酸塩蛍光体］を希ガス放電表示・発光装置，または電界放射型ディスプレイ（ＦＥＤ）装置に用いることにより，長寿命化を実現できた。
【００１５】
【発明の効果】
本発明の発光装置及び表示装置は長寿命である。[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a technology of a plasma display and a field emission display including a phosphor that emits light when excited by a rare gas resonance ultraviolet ray or a low-energy electron beam in a vacuum ultraviolet region (wavelength: 200 nm or less), and a light emitting device. And a display device using the same.
[0002]
[Prior art]
As display and light-emitting devices have become thinner, plasma display devices, liquid crystal display devices, and field emission display (FED) devices have been improved in performance. The plasma display device is a fluorescent light that is arranged in the discharge space using ultraviolet light generated in a negative glow region in a minute discharge space containing a rare gas (in the case of using xenon as a rare gas, at 147 nm and 172 nm) as an excitation source. This is a method of performing color display by causing the body to emit light. Also, in liquid crystal display devices, straight tube type white fluorescent lamps are currently used for backlights, but there are also demands for improving the brightness of the display screen and environmentally mercury-free, and measures to solve these problems A flat type rare gas discharge fluorescent lamp has been developed, and a rare gas resonance line excitation phosphor is used for this.
[0003]
[Problems to be solved by the invention]
The performance of plasma display devices, rare gas discharge light emitting devices (fluorescent lamps, etc.) and field emission display (FED) devices largely depends on the performance of the phosphor. The current blue phosphor for PDP (BaMgAl10O17: Eu, hereinafter abbreviated as BAM) is desired to have a longer life and improved luminous efficiency.
[0004]
[Means for Solving the Problems]
The present inventors previously developed a divalent europium activated alkaline earth silicate phosphor as a blue phosphor for electron beams [JP-A 64-6087, JP-A 01-167394]. Evaluation in the region ultraviolet and low-energy electron beam has not been studied. Now, the present inventors have found a composition having good color tone and high luminous efficiency under excitation in the ultraviolet and ultraviolet regions of the vacuum ultraviolet region and low-energy electron beam, and have led to the present invention.
[0005]
The phosphor of the present invention is represented by the following composition formula.
(Ae) ac (Ae) bSixOy: Euc
Ae is at least one alkaline earth element selected from Sr, Ca and Ba. Ae is at least one element selected from Mg and Zn. In the above chemical formula, a is 1 or 2, and b is 1 or 0. Further, x is 1 or 2, and y is 4, 6 or 7. C is a number in the following range.
0.01 ≦ c ≦ 0.3
The plasma display device, the rare gas discharge light emitting device, and the field emission display (FED) device of the present invention are all displays and light emitting devices provided with the phosphor film made of the phosphor.
[0006]
DETAILED DESCRIPTION OF THE INVENTION
The present inventors have developed a high-efficiency blue-emitting divalent europium-activated alkaline earth silicate phosphor having a long life and using it as a blue component, thereby enabling a high-performance plasma display device, A gas discharge light emitting device and a field emission display (FED) device could be obtained.
Examples of the present invention will be described below.
[0007]
The representative phosphor of the present invention is synthesized as follows.
Phosphor raw materials include alkaline earth carbonate compounds such as strontium carbonate, zinc compounds such as zinc carbonate, europium compounds such as europium fluoride, silicon compounds such as silicon oxide, and ammonium halides such as ammonium chloride. Using these compounds, weigh and collect each of these raw materials according to the composition formula and mix them well by wet or dry methods. This mixture is filled in a heat-resistant container such as a fused alumina crucible and fired twice. The first firing is performed at 800 ° C. in air, and the second firing is performed at a temperature of 1250 ° C. in a 5% hydrogen mixed nitrogen gas atmosphere. The fired product is pulverized, washed with water and dried to obtain the blue light-emitting phosphor of the present invention.
[Example 1]
Table 1 shows the phosphor composition and relative emission intensity.
[0008]
[Table 1]

Among these, the phosphor of Sample 5 was synthesized as follows. That is, the following raw materials
BaCO3: 0.3molx0.1 5.92g SrCO3: 0.3molx0.1 4.42g
CaCO3: 0.3molx0.1 3.00g MgCO3: 1molx0.1 8.43g
SiO2: 1molx0.1 6.01g Eu2O3: 0.1molx0.05 1.76g
NH4Cl: 0.1g
After weighing and mixing the required amount sufficiently well, this mixture is filled in a heat-resistant container such as a fused alumina crucible and fired at 800 ° C. in air and then at 1250 ° C. in a 5% hydrogen mixed nitrogen gas atmosphere. To do. The fired product was pulverized, washed with water and dried to obtain a blue-emitting phosphor. Other phosphors were synthesized in the same manner. Thereafter, the relative emission intensity of each sample when the emission luminance of the phosphor under 147 nm vacuum ultraviolet excitation was 100% of that of the current phosphor BAM was determined. The results are 100% to 115% as shown in Table 1. It was also confirmed that the lifetime characteristics of these phosphors were improved over the comparative samples.
[Example 2]
Using the raw materials described above, phosphors (samples 9 to 20) partially substituted with Ca, Sr, Ba, and Mg or Zn described in Table 2 were synthesized according to the same synthesis process. All of these phosphors were found to have a relatively high emission luminance under 147 nm ultraviolet excitation. Specific emission intensity is shown in Table 2. Moreover, it was confirmed that the lifetime characteristics of these phosphors were improved over the comparative samples.
[Example 3]
A plasma display panel (PDP) was produced using the divalent europium activated alkaline earth silicate phosphor (composition shown in Tables 1 and 2) according to the present invention as the blue phosphor constituting the blue phosphor film.
[0009]
[Table 2]

In the PDP of the surface discharge type color PDP as in the present embodiment, for example, a negative voltage is applied to the display electrode (generally referred to as a scan electrode), and a positive voltage (applied to the display electrode is applied to the address electrode and the display electrode). A discharge is generated by applying a positive voltage compared to the voltage to be generated, thereby forming a wall charge that assists in starting the discharge between the display electrodes (this is referred to as writing). When an appropriate reverse voltage is applied between the display electrodes in this state, a discharge is generated in the discharge space between the two electrodes via the dielectric (and the protective layer). When the voltage applied to the display electrode and the display electrode is reversed after the discharge is completed, a new discharge is generated. By repeating this, a discharge is continuously generated (this is called a sustain discharge or a display discharge).
[0010]
The PDP according to the present embodiment is formed by forming an address electrode made of silver or the like and a dielectric layer made of a glass-based material on a rear substrate, and then forming a partition made of the same glass-based material. The material is printed on a thick film, and a partition wall is formed by blast removal using a blast mask. Next, red, green, and blue phosphor layers are sequentially formed on the barrier ribs so as to cover the groove surfaces between the barrier ribs.
[0011]
Here, each phosphor layer corresponds to red, green and blue, 40 parts by weight of red phosphor particles (60 parts by weight of vehicle), 35 parts by weight of green phosphor particles (65 parts by weight of vehicle), and blue phosphor particles. 35 parts by weight (65 parts by weight of the vehicle) are mixed with the vehicle to form a phosphor paste, applied by screen printing, and then evaporated and volatile components in the phosphor paste are evaporated and removed by burning and drying processes. Form. The phosphor layer used in the present embodiment is composed of each phosphor particle having a median particle diameter of 3 μm.
[0012]
As for the material of each phosphor, the red phosphor is a mixture of (Y, Gd) BO3: Eu phosphor and Y2O3: Eu phosphor 1: 1, and the green phosphor is Zn2SiO4: Mn phosphor.
[0013]
Next, the front substrate and the rear substrate on which the display electrode, bus electrode, dielectric layer, and protective layer are formed are frit-sealed, the inside of the panel is evacuated, and then discharge gas is injected and sealed. The PDP of this embodiment has a size of 3 type and a pitch of one pixel of 1000 μm × 1000 μm.
Next, using the phosphors formed in Examples 1 and 2, the same materials are used for the red and green phosphors, and a plasma display device filled in each phosphor layer 25 is manufactured, and the initial luminance and lifetime characteristics are produced. I investigated.
This panel had good color tone, high brightness and long life as compared with the conventional product produced by replacing only the blue phosphor with a divalent europium activated barium magnesium aluminate phosphor.
The initial luminance was almost the same as the relative light emission intensity of the powder described for each phosphor in Table 2. In terms of lifetime performance, all phosphors (all compositions shown in Tables 1 and 2) showed results exceeding the comparative phosphors.
Further, in this example, although detailed examination results are not shown for the red and green phosphors, PDPs can be similarly produced using phosphors having the following compositions.
[0014]
The red phosphor may contain one or more of (Y, Gd) BO3: Eu, (Y, Gd) 2O3: Eu, (Y, Gd) (P, V) O4: Eu. is there. Green phosphors are Zn2SiO4: Mn, (Y, Gd, Sc) 2SiO5: Tb, (Y, Gd) 3 (Al, Ga) 5O12: Tb, (Y, Gd) 3 (Al, Ga) 5O12: It is possible to include one or more phosphors selected from the group of Ce, (Y, Gd) B3O6: Tb, (Y, Gd) PO4: Tb. Furthermore, combinations with phosphors not shown here are also applicable.
[Example 4]
The divalent europium activated alkaline earth silicate phosphor (composition shown in Table 1) according to the present invention as the blue phosphor color, the divalent manganese activated zinc silicate phosphor as the green phosphor, and the red phosphor A trivalent europium activated yttrium oxide and gadolinium phosphor was used to produce a rare gas (xenon gas) discharge white fluorescent lamp. This lamp had higher luminous efficiency and longer life than a conventional product manufactured by replacing only a blue phosphor with a divalent europium activated barium magnesium aluminate phosphor.
[Example 5]
The divalent europium activated alkaline earth silicate phosphor (composition shown in Table 2) according to the present invention is used as the blue phosphor, the divalent manganese activated zinc silicate phosphor as the green phosphor, and the red phosphor. Manufactured a planar rare gas (xenon gas) discharge white fluorescent lamp using trivalent europium activated yttrium gadolinium phosphor. This lamp had higher luminous efficiency and longer life than a conventional product manufactured by replacing only a blue phosphor with a divalent europium activated barium magnesium aluminate phosphor.
[Example 6]
Here, a uniform transparent electrode was first formed on the inner surface of the glass substrate on which the fluorescent film was to be formed. Next, the divalent europium-activated alkaline earth silicate phosphor (composition shown in Tables 1 and 2) according to the present invention is used as the blue phosphor constituting the blue phosphor film, and the green fluorescence constituting the green phosphor film. A divalent manganese-activated zinc silicate phosphor was sequentially formed as a body, and a trivalent europium-activated yttrium oxide / gadolinium phosphor was sequentially formed as a red phosphor constituting the red phosphor film. This glass substrate and another glass substrate in which a minute electron beam source was built were sealed together, and a 10-type field emission display (FED) panel was manufactured after evacuation. This panel showed higher efficiency and longer life characteristics than the FED panel manufactured by replacing only the conventional blue phosphor with a divalent europium activated barium magnesium aluminate phosphor. Using this panel, a display panel was constructed and used as a display system for televisions, videos, automobiles, etc., and it was confirmed that good display quality was obtained.
As described above, a blue phosphor [divalent europium-activated alkaline earth silicate phosphor] having high efficiency under vacuum ultraviolet light and low-energy electron beam excitation is used as a rare gas discharge display / light emitting device or field emission type. By using it in a display (FED) device, it was possible to extend the service life.
[0015]
【The invention's effect】
The light emitting device and the display device of the present invention have a long life.

Claims (4)

A light emitting device comprising a fluorescent film containing a blue light emitting divalent europium activated alkaline earth silicate phosphor represented by the following chemical formula:
_{(Ae) 1-c (Mg} 0.9, Zn 0.1) Si 2 O 6: Eu c
(However, Ae is at least one alkaline earth element selected from Sr, Ca and Ba, and c is in the range of 0.01 ≦ c ≦ 0.3 .) A light emitting device comprising a fluorescent film containing a blue light emitting divalent europium activated alkaline earth silicate phosphor represented by the following chemical formula:
Ca (Mg _1-d , Zn _d ) Si ₂ O ₆
(However, d is 0.01 ≦ d ≦ 2 Or d = 1 It is. ) A pair of opposing substrates,
A discharge gas space formed between the pair of substrates, in which a gas that generates ultraviolet rays by discharge is sealed, and an electrode formed on each of the opposing surfaces of the pair of substrates;
A phosphor layer formed on the surface of one of the pair of substrates in contact with the discharge gas space;
Among the phosphor layers, the red phosphor layer is at least one selected from (Y, Gd) BO3: Eu, (Y, Gd) 2O3: Eu, (Y, Gd) (P, V) O4: Eu The light-emitting device according to claim 1, wherein the light-emitting device is a plasma display having a phosphor. Among the phosphor layers, the green phosphor layer is Zn2SiO4: Mn, (Y, Gd, Sc) 2SiO5: Tb, (Y, Gd) 3 (Al, Ga) 5O12: Tb, (Y, Gd) 3 (Al, A plasma display having at least one phosphor selected from the group consisting of Ga) 5O12: Ce, (Y, Gd) B3O6: Tb, (Y, Gd) PO4: Tb The light emitting device according to claim 3.