CN101200637A - Fluorescent substance for vacuum ultraviolet-exited light emitting diode - Google Patents
Fluorescent substance for vacuum ultraviolet-exited light emitting diode Download PDFInfo
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- CN101200637A CN101200637A CNA2007100961827A CN200710096182A CN101200637A CN 101200637 A CN101200637 A CN 101200637A CN A2007100961827 A CNA2007100961827 A CN A2007100961827A CN 200710096182 A CN200710096182 A CN 200710096182A CN 101200637 A CN101200637 A CN 101200637A
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- fluorescent material
- emitting diode
- light emitting
- vacuum ultraviolet
- fluorescent substance
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Abstract
A fluorescent substance for vacuum ultraviolet radiation excited light-emitting devices which containing vacuum ultraviolet radiation excited light-emitting devices of fluorescent substance, including: a compound represented by the general formula: mM<1>O.nM<2>O.2M<3>O2, wherein M<1> is at least one metal selected from Ca, Sr and Ba, M<2> is at least one metal selected from Mg and Zn, M<3> is at least one metal selected from Si and Ge, and m and n satisfy 0.5</=m</=3.5 and 0.5</=n</=2.5, respectively, provided that when m=n=1 , M<1> is either at least two metals selected from Ca, Sr and Ba or one of Sr and Ba; and at least one metal selected from Eu and Mn as an activator.
Description
The application is to be September 27 calendar year 2001, application number the dividing an application for the Chinese patent application of " fluorescent material that is used for fluorescent substance for vacuum ultraviolet-exited light emitting diode " that be 01137167.6 denomination of invention the applying date.
Technical field
The present invention relates to be applicable to the fluorescent material of fluorescent substance for vacuum ultraviolet-exited light emitting diode such as plasma display panel (hereinafter referred to as " PDPs ") and rare gas lamp.
Background technology
Luminous fluorescent material comprises when with the vacuum UV irradiation equal excitation, for example BaMgAl
10O
17: Eu, it comprises Ba, Mg, Al, O and as the activator (Eu) of the blue fluorescent material of fluorescent substance for vacuum ultraviolet-exited light emitting diode, and Zn
2SiO
4: Mn, it comprises Zn, Si, O and as the activator (Mn) of green fluorescence material.Also have, for example (Y, Gd) BO
3: Eu, it comprises Y, Gd, B, O and activator (Eu), known its as red fluorescence material.This fluorescent material also is used in the rare gas lamp.Yet these prior art fluorescent materials that are used for fluorescent substance for vacuum ultraviolet-exited light emitting diode preferably can show further enhanced brightness.
In fluorescent substance for vacuum ultraviolet-exited light emitting diode such as PDPs and rare gas lamp, when producing plasma body, rare gas causes discharge to produce vacuum UV irradiation then.The problem that the fluorescent material of prior art relates to is because they are exposed to plasma body, and its brightness reduces.Therefore, need a kind of fluorescent material that is used for fluorescent substance for vacuum ultraviolet-exited light emitting diode, its brightness can not reduce greatly because of being exposed to plasma body.
United States Patent (USP) 5839718 discloses a kind of silicate fluorescent material, and it comprises (the Sr by general formula m
1-aM
1 a) On (Mg
1-bM
2 b) O2 (Si
1-cGe
c) O
2: Eu
xLn
yThe compound of expression, wherein M
1Be Ba, M
2Be at least a element that is selected from Be, Zn and Cd, Ln is at least a element that is selected from Sc, Y, La, Ce, Pr, Nd, Sm, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu, B, Al, Ga, In, Tl, Sb, Bi, As, P, Sn, Pb, Ti, Zr, Hf, V, Nb, Ta, Mo, W, Cr and Mn.The specific examples of disclosed this silicate fluorescent material comprises Sr
1.995MgSi
2O
7: Eu
0.005, Dy
0.025, Cl
0.025And Sr
0.445Ba
1.55MgSi
2O
7: Eu
0.005, Dy
0.025, Cl
0.025These fluorescent materials are as the light store battery that shows or be used for similar purpose in dark surrounds." the 6th international scientific and technology show the additional summary of phosphorescent substance meeting ", the 21-24 page or leaf discloses CaMgSi
2O
6: Eu is as the fluorescent material of fluorescent substance for vacuum ultraviolet-exited light emitting diode.
This fluorescent material that comprises silicate still has such problem, their luminance shortage and owing to be exposed to plasma body, and brightness reduces.
The object of the invention provides a kind of fluorescent material that is used for fluorescent substance for vacuum ultraviolet-exited light emitting diode, and it can send the light of higher brightness and after being exposed to plasma body, brightness has less reduction.
Summary of the invention
In this case, the inventor has carried out deeply and the research that continues, and seeks to address the above problem, and found that at silicate that is used for fluorescent substance for vacuum ultraviolet-exited light emitting diode or germanate fluorescent material, fluorescent material with specific composition, it comprises by general formula: mM
1OnM
2O2M
3O
2The compound of expression, wherein M
1Be at least a metal that is selected from Ca, Sr and Ba, M
2Be at least a metal that is selected from Mg and Zn, M
3Be at least a metal and m and the satisfied respectively 0.5≤m of n≤3.5 and 0.5≤n≤2.5 that are selected from Si and Ge, condition is when m=n=1, M
1Be at least two kinds of metals that are selected from Ca, Sr and Ba, or be selected from a kind of metal of Sr and Ba; With at least a metal that is selected from Eu and Mn as activator, it sends the light of higher brightness and after being exposed to plasma body, brightness has less reduction.Therefore, realized the present invention.
In view of the above, the invention provides a kind of fluorescent material that is used for fluorescent substance for vacuum ultraviolet-exited light emitting diode, it comprises by general formula: mM
1OnM
2O2M
3O
2The compound of expression, wherein M
1Be at least a metal that is selected from Ca, Sr and Ba, M
2Be at least a metal that is selected from Mg and Zn, M
3Be at least a metal and m and the satisfied respectively 0.5≤m of n≤3.5 and 0.5≤n≤2.5 that are selected from Si and Ge, condition is when m=n=1, and M1 is at least two kinds of metals that are selected from Ca, Sr and Ba, or is selected from a kind of metal of Sr and Ba; With at least a metal that is selected from Eu and Mn as activator.The present invention also provides the fluorescent substance for vacuum ultraviolet-exited light emitting diode of the fluorescent material that comprises above definition.
Embodiment
The fluorescent material that is used for fluorescent substance for vacuum ultraviolet-exited light emitting diode according to the present invention is characterised in that and comprises by general formula mM
1OnM
2O2M
3O
2The basic crystal that the compound of expression constitutes, wherein M
1Be at least a metal that is selected from Ca, Sr and Ba, M
2Be at least a metal that is selected from Mg and Zn, M
3Be at least a metal and m and the satisfied respectively 0.5≤m of n≤3.5 and 0.5≤n≤2.5 that are selected from Si and Ge, condition is when m=n=1, M
1Be at least two kinds of metals that are selected from Ca, Sr and Ba, or be selected from a kind of metal of Sr and Ba; With at least a metal that is selected from Eu and Mn as activator.
In above-mentioned general formula, work as m=n=1, M
1Be selected from Sr and Ba, the combination of Sr, Ba and Ca, the combination of Sr and Ca, the combination of the combination of Ba and Sr and Ba and Ca.
Preferably, the fluorescent material that is used for fluorescent substance for vacuum ultraviolet-exited light emitting diode according to the present invention has the crystalline structure identical with diopside, akermanite or merwinite.
Have in the fluorescent material of same crystal structure with diopside, preferably include and have a kind of of above-mentioned general formula compound, wherein m=n=1.As the fluorescent material that is used for fluorescent substance for vacuum ultraviolet-exited light emitting diode, preferred a kind of have such composition, wherein M
1And M
2Be activated agent Eu and Mn respectively and partly replace, and it is by general formula: (M
1 1-aEu
a) (M
2 1-bMn
b) M
3 2O
6Expression, wherein M
1Be at least two kinds of metals that are selected from Ca, Sr and Ba, or be selected from a kind of metal of Sr and Ba; M
2Be at least a metal that is selected from Mg and Zn, M
3Be at least a metal and a and the satisfied 0≤a of b≤0.5,0≤b≤0.5 and the 0<a+b that is selected from Si and Ge.
Also preferred and diopside has same crystal structure a kind of fluorescent material, it comprises the compound with above-mentioned general formula, m=n=1 wherein, it has such composition, wherein M
1Be Ca and Sr, M
2And M
3Be respectively that Mg and Si and Ca are activated agent Eu and partly replace, and it is by general formula: Ca
1-c-dSr
cEu
dMgSi
2O
6Expression, wherein c and d satisfy 0<c≤0.1 and 0<d≤0.1 respectively.
Have in the fluorescent material of same crystal structure with akermanite, preferably include and have a kind of of above-mentioned general formula compound, wherein m=2 and n=1.As the fluorescent material that is used for fluorescent substance for vacuum ultraviolet-exited light emitting diode, preferred a kind of have such composition, wherein M
1And M
2Be activated agent Eu and Mn respectively and partly replace, and it is by general formula: (M
1 1-eEu
e)
2(M
2 1-fMn
f) M
3 2O
7Expression, wherein M
1Be at least a metal that is selected from Ca, Sr and Ba, M
2Be at least a metal that is selected from Mg and Zn, M
3Be at least a metal and e and the satisfied 0≤e of f≤0.5,0≤f≤0.5 and the 0<e+f that is selected from Si and Ge.The fluorescent material that also more preferably has such composition, wherein f=0, and M
3Be Si, it is by general formula (M
1 1-eEu
e)
2M
2Si
2O
7Expression, wherein M
1Be at least a metal that is selected from Ca, Sr and Ba, M
2Be that at least a metal and the e that is selected from Mg and Zn satisfies 0.001≤e≤0.1.
Have in the fluorescent material of same crystal structure with akermanite, preferably include and have a kind of of above-mentioned general formula compound, wherein m=1 and n=2.As the fluorescent material that is used for fluorescent substance for vacuum ultraviolet-exited light emitting diode, preferred a kind of have such composition, wherein M
1And M
2Be activated agent Eu and Mn respectively and partly replace, and it is by general formula: (M
1 1-hEu
h) (M
2 1-iMn
i)
2M
3 2O
7Expression, wherein M
1Be at least a metal that is selected from Ca, Sr and Ba, M
2Be at least a metal that is selected from Mg and Zn, M
3Be at least a metal and h and the satisfied 0≤h of i≤0.5,0≤i≤0.5 and the 0<h+i that is selected from Si and Ge.
Have in the fluorescent material of same crystal structure with merwinite, preferably include and have a kind of of above-mentioned general formula compound, wherein m=3 and n=1.As the fluorescent material that is used for fluorescent substance for vacuum ultraviolet-exited light emitting diode, preferred a kind of have such composition, wherein M
1And M
2Be activated agent Eu and Mn respectively and partly replace, and it is by general formula: (M
1 1-jEu
j)
3(M
2 1-kMn
k)
2M
3 2O
8Expression, wherein M
1Be at least a metal that is selected from Ca, Sr and Ba, M
2Be at least a metal that is selected from Mg and Zn, M
3Be at least a metal and j and the satisfied 0≤j of k≤0.5,0≤k≤0.5 and the 0<j+k that is selected from Si and Ge.
Have in the fluorescent material of same crystal structure with diopside, akermanite or merwinite, preferably with diopside have same crystal structure those and have those of same crystal structure with merwinite.The fluorescent material that has same crystal structure with diopside is particularly preferred.
In preparation fluorescent material of the present invention, as the raw material in calcium, strontium and barium source can be at high temperature to resolve into those of oxide compound, such as the oxyhydroxide of calcium, strontium and barium, carbonate, nitrate, halogenide, oxalate etc., or has the oxide compound of calcium, strontium and the barium of high purity (99.9% or higher) with high purity (99% or higher).
As the raw material in magnesium and zinc source can be at high temperature can resolve into oxide compound those such as the oxyhydroxide with high purity (99% or higher) magnesium and zinc, carbonate, nitrate, halogenide, oxalate etc., or have the magnesium of high purity (99% or higher) and the oxide compound of zinc.
As the raw material in silicon and germanium source can be at high temperature to resolve into those of oxide compound, such as the oxyhydroxide with high purity (99% or higher) silicon and germanium, carbonate, nitrate, halogenide, oxalate etc., or have the silicon of high purity (99% or higher) and the oxide compound of germanium.
As the raw material that contains europium or manganese of activator can be at high temperature to resolve into those of oxide compound, such as the oxyhydroxide with high purity (99% or higher) europium and manganese, carbonate, nitrate, halogenide, oxalate etc., or have the europium of high purity (99% or higher) and the oxide compound of manganese.
The method for preparing fluorescent material of the present invention is not particularly limited.Fluorescent material for example can prepare by above-mentioned raw materials is mixed and calcines this mixture.
For example, have by formula M
1 1-aEu
a) (M
2 1-bMn
b) M
3 2O
6The fluorescent material of composition of expression, it is a kind of in the above-mentioned preferred composition, its preparation can mix them and also calcine this mixture by weighing above-mentioned raw materials and above-mentioned raw materials is admixed in the predetermined composition.In mixing this raw material, can use ball mill, V-type mixing tank, whipping appts etc.
After mixing, this mixture of calcining is about 1-100 hour in for example about 1000 ℃ of-1500 ℃ of scopes of temperature, obtains fluorescent material of the present invention.Be used under the situation of those raw materials that can resolve into oxide compound under the high temperature, such as the oxyhydroxide of bioelement, carbonate, nitrate, halogenide, oxalate etc., can before main calcining, under for example about 600 ℃-900 ℃ temperature, carry out this mixture of precalcining.
Incinerating atmosphere is not particularly limited, but preferably calcines in reducing atmosphere, reducing atmosphere comprises for example hydrogen of nitrogen, argon etc. and 10% (volume) content.Precalcining can be carried out under atmosphere or under the reducing atmosphere.In order to carry out calcination reaction, can add the fusing assistant of appropriate amount.
In addition, the fluorescent material that is obtained by aforesaid method for example can use ball mill, spray formula shredder to wait and pulverize.In addition, this material can be washed and classification.In order to obtain the fluorescent material of higher crystallinity, can carry out precalcining.
The fluorescent material of the present invention that obtains thus can send the light of high brightness when exciting with vacuum UV irradiation, and only shows because of being exposed to the brightness that plasma body causes and reduce in a small amount.In preparation PDP, rare gas lamp etc., technology generally comprises fluorescent material is dispersed in the solvent, adds tackiness agent in this dispersion liquid, dispersion liquid is applied on the luminous component, and the dispersion liquid that heating applies is like this removed tackiness agent to about 500 ℃.Fluorescent material of the present invention is even through such processing, only show the brightness that causes because of thermal treatment and reduce in a small amount.Therefore, in fluorescent substance for vacuum ultraviolet-exited light emitting diode such as PDP or rare gas lamp, use fluorescent material of the present invention can realize that PDP or rare gas lamp show high brightness and persistent work-ing life.Therefore, fluorescent material of the present invention is suitable for fluorescent substance for vacuum ultraviolet-exited light emitting diode.
Fluorescent material of the present invention is overseas ultraviolet radiation, X-ray, the electron beam equal excitation in vacuum available ultraviolet region also, therefore can use in ultraviolet radiation, X-ray or the device of electron beam as excitaton source outside using vacuum ultraviolet region.
Embodiment
With reference to following examples, describe the present invention in more detail, but the invention is not restricted to these embodiment.
Embodiment 1
The raw material of weighing, the i.e. lime carbonate (CaCO that produces by WAKOJUNYAKU company limited
3), the Strontium carbonate powder (SrCO that produces by WAKOJUNYAKU company limited
3), the europium sesquioxide (Eu that produces by SHINETSUKAGAKUKOGYO company limited
2O
3), magnesium basic carbonate is (by (MgCO of WAKOJUNYAKU company limited production
3)
4Mg (OH)
25H
2O) and the silicon oxide (SiO that produces by WAKOJUNYAKU company limited
2), and mix, so that CaCO
3: SrCO
3: Eu
2O
3: (MgCO
3)
4Mg (OH)
25H
2O: SiO
2Mol ratio be 0.9215: 0.0485: 0.015: 0.2: 2.Under 1200 ℃, at the H that contains 2% (volume) content
2The Ar air-flow under, the mixture that obtained in 2 hours of calcining grinds, then again under 1200 ℃, at the H that contains 2% (volume) content
2The Ar air-flow under, calcined 2 hours.Obtain thus by formula Ca
0.9215Sr
0.485Eu
0.03MgSi
2O
6The fluorescent material of the composition of expression.When this fluorescent material at pressure 6.7Pa (5 * 10
-2Torr) or in the lower vacuum chamber, (model: the H0012 that is produced by USHIO DENKI company) during the ultraviolet radiation irradiation, it sends brightness 24cd/m to use excimer 146-nm lamp
2Blue light.
The fluorescent material that obtains was thus heat-treated under 500 ℃ 30 minutes in air.Measure the brightness through heat treated fluorescent material, the result compares with the brightness of fluorescent material before the thermal treatment, and brightness does not reduce.
The fluorescent material that obtains is put into have Xe, the Ne ratio of components is 5%: 95% (volume), in the atmosphere of pressure 13.2Pa and be exposed to the plasma body 30 minutes of 10W, is exposed to the plasma body 15 minutes of 50W then.After being exposed to plasma body, measure the brightness of fluorescent material, the result compares with the brightness that is exposed to plasma body fluorescent material before, and brightness does not reduce.
With the fluorescent material that obtains in air, under 500 ℃ through Overheating Treatment 30 minutes.Then, fluorescent material is put into have Xe, the Ne ratio of components is 5%: 95% (volume), in the atmosphere of pressure 13.2Pa and be exposed to the plasma body 30 minutes of 10W, is exposed to the plasma body 15 minutes of 50W then.After being exposed to plasma body, measure the brightness of fluorescent material, the result compares with the brightness of the fluorescent material that is exposed to plasma body with thermal treatment, and the brightness reduction is less than 4%.
Embodiment 2
The raw material of weighing, the i.e. Strontium carbonate powder (SrCO that produces by WAKOJUNYAKU company limited
3), the barium carbonate (BaCO that produces by WAKOJUNYAKU company limited
3), the europium sesquioxide (Eu that produces by SHINETSUKAGAKUKOGYO company limited
2O
3), magnesium basic carbonate is (by (MgCO of WAKOJUNYAKU company limited production
3)
4Mg (OH)
25H
2O) and the silicon oxide (SiO that produces by WAKOJUNYAKU company limited
2), and mix, so that SrCO
3: BaCO
3: Eu
2O
3: (MgCO
3)
4Mg (OH)
25H
2O: SiO
2Mol ratio be 2.28: 0.57: 0.075: 0.2: 2.Under 1200 ℃, at the H that contains 2% (volume) content
2Ar atmosphere under, the mixture that obtained in 2 hours of calcining.Obtain thus by formula Sr
2.28Ba
0.57Eu
0.15MgSi
2O
8The fluorescent material of the composition of expression.When this fluorescent material at pressure 6.7Pa (5 * 10
-2Torr) or in the lower vacuum chamber, (model: the H0012 that is produced by USHIODENKI company) during the ultraviolet radiation irradiation, it sends brightness 30cd/m to use excimer 146-nm lamp
2Blue light.
Embodiment 3
The raw material of weighing, the i.e. barium carbonate (BaCO that produces by KANTOKAGAKU company limited
3), the europium sesquioxide (Eu that produces by SHINETSU KAGAKUKOGYO company limited
2O
3), magnesium oxide (by the MgO of KANTOKAGAKU company limited production) and silicon oxide are (by the SiO of KOJUNDOKAGAKUKENKYUSHO company limited production
2), and mix, so that BaCO
3: Eu
2O
3: MgO: SiO
2Mol ratio be 1.98: 0.01: 1: 2.With respect to 1 mole of product, add 0.1 mole of B
2O
3As flux, the mixture that obtains is with mortar fully wet mixing in acetone, and is dry then.The mixing raw material that obtains thus is put in the stainless steel mould, under 40Mpa, pressurizes then, form the spherolite of size 15mm (diameter) * 3mm (thickness).The spherolite that obtains is put in the aluminium crucible, and under 1200 ℃, has H
2, the Ar ratio of components be in 5%: 95% (volume) atmosphere the calcining 3 hours.Obtain thus by formula Ba
1.98Eu
0.02MgSi
2O
7The fluorescent material of the composition of expression.When this fluorescent material at pressure 6.7Pa (5 * 10
-2Torr) or in the lower vacuum chamber, (model: the H0012 that is produced by USHIO DENKI company) during the ultraviolet radiation irradiation, it sends brightness 95cd/m to use excimer 146-nm lamp
2Green glow.
Embodiment 4
Preparation (Sr
0.99Eu
0.01)
2MgSi
2O
7The raw material that uses is that Strontium carbonate powder is (by the SrCO of KANTOKAGAKU company limited production
3), the europium sesquioxide (Eu that produces by SHINETSU KAGAKUKOGYO company limited
2O
3), magnesium oxide (MgO that is produced by KANTOKAGAKU company limited) and silicon oxide be (by the SiO of KOJUNDOKAGAKU KENKYUSHO company limited production
2).Weigh these materials and mixing are so that SrCO
3: Eu
2O
3: MgO: SiO
2Mol ratio be 1.98: 0.01: 1: 2, then with respect to 1 mole of product, i.e. (Sr
0.99Eu
0.01)
2MgSi
2O
7, add 0.1 mole of B
2O
3As flux, the mixture that obtains is with mortar fully wet mixing in acetone, and is dry then.The mixing raw material that obtains thus is put in the stainless steel mould, under 40Mpa, pressurizes then, form the spherolite of size 15mm (diameter) * 3mm (thickness).The spherolite that obtains is put in the aluminium crucible, and under 1200 ℃, has H
2, the Ar ratio of components be in 5%: 95% atmosphere the calcining 3 hours.In the time will being shone with the ultraviolet radiation with wavelength 254nm or 365nm by the sample that calcining obtains, in either case, it sends the high brightness bright blue.When sample at pressure 6.7Pa (5 * 10
-2Torr) or in the lower vacuum chamber, when using the irradiation of excimer 146-nm lamp (being produced by USHIODENKI company) ultraviolet radiation, it sends brightness 25cd/m
2Be deeply conscious of light blue light.
Embodiment 5
Preparation (Sr
0.99Eu
0.01)
2ZnSi
2O
7The raw material that uses is Strontium carbonate powder (SrCO
3), europium sesquioxide (Eu
2O
3), zinc oxide (ZnO) and silicon oxide (SiO
2).Weigh these materials and mixing are so that SrCO
3: Eu
2O
3: ZnO: SiO
2Mol ratio be 1.98: 0.01: 1: 2, then with respect to 1 mole of product, i.e. (Sr
0.99Eu
0.01)
2ZnSi
2O
7, add 0.1 mole of B
2O
3As flux, the mixture that obtains is with mortar fully wet mixing in acetone, and is dry then.The mixing raw material that obtains thus is put in the stainless steel mould, under 40Mpa, pressurizes then, form the spherolite of size 15mm (diameter) * 3mm (thickness).The spherolite that obtains is put in the aluminium crucible, and under 1200 ℃, has H
2, the Ar ratio of components be in 5%: 95% atmosphere the calcining 3 hours.In the time will being shone with the ultraviolet radiation with wavelength 254nm or 365nm by the sample that calcining obtains, it sends the light blue green glow of high brightness.
The comparative example 1
The raw material of weighing, the i.e. lime carbonate (CaCO that produces by WAKOJUNYAKU company limited
3), the europium sesquioxide (Eu that produces by SHINETSU KAGAKUKOGYO company limited
2O
3), magnesium basic carbonate is (by (MgCO of WAKOJUNYAKU company limited production
3)
4Mg (OH)
25H
2O) and the silicon oxide (SiO that produces by WAKOJUNYAKU company limited
2), and mix, so that CaCO
3: Eu
2O
3: (MgCO
3)
4Mg (OH)
25H
2O: SiO
2Mol ratio be 0.95: 0.025: 0.2: 2.Under 1200 ℃, at the H that contains 2% (volume) content
2The Ar air-flow under, the mixture that obtained in 2 hours of calcining.Obtain thus by formula Ca
0.95Eu
0.05MgSi
2O
6The fluorescent material of the composition of expression.When this fluorescent material at pressure 6.7Pa (5 * 10
-2Torr) or in the lower vacuum chamber, (model: the H0012 that is produced by USHIO DENKI company) during the ultraviolet radiation irradiation, it sends brightness 12cd/m to use excimer 146-nm lamp
2Blue light.
The comparative example 2
Fluorescent material (BaMgAl with the blue light-emitting that is purchased
10O
17: Eu) in air, under 500 ℃, heat-treated 30 minutes.Measure the brightness through heat treated fluorescent material, the brightness of the fluorescent material before result and the thermal treatment is compared, and brightness has 1% to reduce.
Fluorescent material (BaMgAl with the blue light-emitting that is purchased
10O
17: Eu) be put into pressure 13.2Pa, have Xe, the Ne ratio of components is in the atmosphere of 5%: 95% (volume), and is exposed to 10W plasma body 30 minutes, is exposed to the 50W plasma body then 15 minutes.After being exposed to plasma body, measure the brightness of fluorescent material, the result be exposed to plasma body before the brightness of fluorescent material compare, brightness reduces by 25%.
Fluorescent material (BaMgAl with the blue light-emitting that is purchased
10O
17: Eu) in air, under 500 ℃, heat-treated 30 minutes.Then fluorescent material is put into pressure 13.2Pa, has Xe, the Ne ratio of components is in the atmosphere of 5%: 95% (volume), and is exposed to 10W plasma body 30 minutes, is exposed to the 50W plasma body then 15 minutes.After being exposed to plasma body, from atmosphere, take out fluorescent material, measure its brightness, the result compares with the brightness of fluorescent material in heat-treated and the state that is exposed to before the plasma body, and brightness reduces by 28%.
Fluorescent material of the present invention sends high-luminance light and only shows because of being exposed to a small amount of reduction of the brightness that plasma body causes, therefore, it is specially adapted to fluorescent substance for vacuum ultraviolet-exited light emitting diode such as PDPs and rare gas lamp.Because this fluorescent material can realize that fluorescent substance for vacuum ultraviolet-exited light emitting diode shows high brightness, so it is specially adapted to industry.
Claims (5)
1. fluorescent substance for vacuum ultraviolet-exited light emitting diode, it comprises the fluorescent material that is used for fluorescent substance for vacuum ultraviolet-exited light emitting diode, and described fluorescent material comprises by general formula: mM
1O.nM
2O.2M
3O
2The compound of expression, wherein M
1Be at least a metal that is selected from Ca, Sr and Ba, M
2Be at least a metal that is selected from Mg and Zn, M
3Be at least a metal and m and the satisfied respectively 0.5≤m of n≤3.5 and 0.5≤n≤2.5 that are selected from Si and Ge, condition is when m=n=1, M
1Be at least two kinds of metals that are selected from Ca, Sr and Ba, or be selected from a kind of metal of Sr and Ba; With at least a metal that is selected from Eu and Mn as activator.
2. according to the fluorescent substance for vacuum ultraviolet-exited light emitting diode of claim 1, the fluorescent material that wherein is used for fluorescent substance for vacuum ultraviolet-exited light emitting diode has the crystalline structure identical with diopside.
3. according to the fluorescent substance for vacuum ultraviolet-exited light emitting diode of claim 2, wherein in general formula, m=n=1.
4. according to the fluorescent substance for vacuum ultraviolet-exited light emitting diode of claim 2, wherein in general formula, M
1Be Ca and Sr, M
2And M
3Be respectively Mg and Si, activator is Eu.
5. according to the fluorescent substance for vacuum ultraviolet-exited light emitting diode of claim 1, wherein said fluorescent material is not halogen-containing.
Applications Claiming Priority (3)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP2000299320 | 2000-09-29 | ||
| JP299320/00 | 2000-09-29 | ||
| JP66318/01 | 2001-03-09 |
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| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CNB011371676A Division CN100338170C (en) | 2000-09-29 | 2001-09-27 | Fluorescent material for vacuum ultraviolet ray radiation stimulated emission lighting device |
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| Publication Number | Publication Date |
|---|---|
| CN101200637A true CN101200637A (en) | 2008-06-18 |
Family
ID=38730142
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| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CNA2007100961827A Pending CN101200637A (en) | 2000-09-29 | 2001-09-27 | Fluorescent substance for vacuum ultraviolet-exited light emitting diode |
| CNA200710096613XA Pending CN101033397A (en) | 2000-09-29 | 2001-09-27 | Fluorescent substances for vacuum ultraviolet radiation laser light-emitting devices |
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| CNA200710096613XA Pending CN101033397A (en) | 2000-09-29 | 2001-09-27 | Fluorescent substances for vacuum ultraviolet radiation laser light-emitting devices |
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| CN101289615B (en) * | 2008-05-22 | 2010-09-22 | 同济大学 | Method for preparing novel red magnesium barium germinate fluorescent powder for displaying |
| CN101792928B (en) * | 2010-03-30 | 2012-06-27 | 山东大学 | High temperature piezocrystal of melilite structure and preparation method and application thereof |
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