CN1506439A - Red RE oxide luminophor and its prepn - Google Patents
Red RE oxide luminophor and its prepn Download PDFInfo
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- CN1506439A CN1506439A CNA021447314A CN02144731A CN1506439A CN 1506439 A CN1506439 A CN 1506439A CN A021447314 A CNA021447314 A CN A021447314A CN 02144731 A CN02144731 A CN 02144731A CN 1506439 A CN1506439 A CN 1506439A
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- rare earth
- red fluorescence
- earth oxide
- oxide red
- fluorescence powder
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Abstract
The present invention belongs to the field of luminous material technology, relates to luminophor capable of emitting red fluorescence under the excitation of electronic beam or vacuum ultraviolet ray, and is especially red RE oxide luminophor and its preparation. The luminophor has the chemical expression of (Y1-x-yGdxEuy)2O3, where x is 0-0.9 and y is 0.01-0.1. Gd ion is led into cubic Y2O3:Eu3+ system to form solid solution of (Y,Gd)2O3 and (Y,Gd, Eu)2O3 in cubic strength. The solid solution is processed through material selection, mixing, sintering and post-treatment to become the red RE oxide luminophor. The present invention features that the luminophor maintains its cubic structure and crystal quality up to 1250 deg.c, has satisfactory activator concentration range, additive to lower the burn temperature, raise light emitting strength and promote crystal growth, and simple and easy-to-operate production process.
Description
Technical field: the invention belongs to field of light emitting materials, relate to the fluorescent material of emission red fluorescence under electron beam or excited by vacuum ultraviolet, is a kind of rare earth oxide red fluorescence powder and manufacture method thereof.
Background technology: can excite material luminous under the situation a lot, these materials can be applied in fields such as demonstration as fluorescent material, for example cube type Gd
2O
3Common cube of type Gd
2O
3The transformation temperature that changes monocline type into is greatly about 1250 ℃, promptly at the Gd that obtains more than 1250 ℃
2O
3Be monocline.According to a cube type Gd
2O
3This character, can prepare a cube type Gd
2O
3Fluorescent powder for matrix.But with a cube type Gd
2O
3The fluorescent material for preparing for matrix has monocline, and the light-emitting phosphor efficient of monocline is low.Use Eu
3+Activated cubic oxide yttrium is widely used in the new technologies such as demonstration, video picture, lighting source at electron beam or vacuum ultraviolet-excited down red-emitting, but along with the development of these technology, Y
2O
3: Eu
3+Luminescent properties can not satisfy the demand, people require to provide performance more good luminescent material.
Summary of the invention: the present invention is at a cube Y
2O
3: Eu
3+Introduce the Gd ion in the system and make it part replacement Y, Y under 1250 ℃ of high temperature
2O
3And Gd
2O
3And Y
2O
3, Gd
2O
3And Eu
2O
3Formation have cubic structure (Y, Gd)
2O
3(Y, Gd, Eu)
2O
3Solid solution.The new Solid solution of this class is that very stable class matter homophase is replaced Solid solution, has good luminescent properties.By at a cube Y
2O
3: Eu
3+Introduce the Gd ion in the system, purpose provides the good rare earth oxide red fluorescence powder of a kind of luminosity height, purity of color and prepares the method for this fluor
The present invention passes through at a cube Y
2O
3: Eu
3+Introduce the Gd ion in the system and make it part replacement Y, Y under 1250 ℃ of high temperature
2O
3And Gd
2O
3And Y
2O
3, Gd
2O
3And Eu
2O
3Formation have cubic structure (Y, Gd)
2O
3(Y, Gd, Eu)
2O
3Solid solution obtains the rare earth oxide red fluorescence powder.
The present invention is at a cube Y
2O
3: Eu
3+After introducing the Gd ion in the system, Y in the system
2O
3And Gd
2O
3And Y
2O
3, Gd
2O
3And Eu
2O
3Formation have cubic structure (Y, Gd)
2O
3(Y, Gd, Eu)
2O
3Solid solution, its chemical expression is as follows:
(Y
1-x-yGd
xEu
y)
2O
3
Wherein x is the content of matrix components Gd, and content is 0<x≤0.9, and y is the content of activator Eu, and content is 0.01≤y≤0.1.Fluor matrix part is made up of the oxide compound of Gd and Y, and the activator material is for containing Eu
3+Oxide compound.
Rare earth oxide red fluorescence powder of the present invention, when the content of matrix components Gd in 0<x≤0.9 scope, be higher than Gd
2O
3Transformation temperature (1250 ℃) time, (Y
1-x-yGd
xEu
y)
2O
3Fluorescent material is body-centered cubic structure still, has luminosity height, characteristics that purity of color is good.
The present invention is Y under 1250 ℃ of high temperature
2O
3And Gd
2O
3, Y
2O
3, Gd
2O
3And Eu
2O
3Formation have cubic structure (Y, Gd)
2O
3(Y, Gd, Eu)
2O
3Solid solution is that very stable class matter homophase is replaced Solid solution, has good luminescent properties.
Rare earth oxide red fluorescence powder step of preparation process of the present invention is as follows:
1, selects materials
By (Y
1-x-yGd
xEu
y)
2O
3The chemical expression metering is than the Y that takes by weighing a certain amount of 99.99% purity
2O
3, Gd
2O
3, Eu
2O
3And the above boric acid of purity assay, metal fluoride and metal carbonate in one or more.Wherein, boric acid, metal fluoride and metal carbonate are additives, and metal fluoride can be CaF
2, metal carbonate can be K
2CO
3Or Li
2CO
3The additive add-on is 0.1~0.5wt%.
2, batch mixing
Y with above-mentioned 99.99% purity
2O
3, Gd
2O
3, Eu
2O
3And the above H of purity assay
3BO
3, CaF
2, K
2CO
3, Li
2CO
3In a kind of or one to three kind as raw material, in the ball grinder of packing into, put into agate ball, the weight ratio of ball and raw material is 1: 1, the ball milling time is more than 10 hours.
3, sintering
In the above-mentioned raw materials of ball mill mixing is packed alumina crucible or corundum crucible into, add a cover and put into high temperature sintering furnace.When packing in the alumina crucible, raw material is a room temperature.Raw material in alumina crucible rises to 1250~1400 ℃ with stove, and constant temperature 1~2 hour stops to heat up, and reduces to below 1000 ℃ with stove and takes out.
4, aftertreatment
Above-mentioned raw materials obtains the white powder product through burning till.With the product white powder fragmentation that obtains, in the ball grinder of packing into, add entry and φ 3mm glass sphere, wherein the ratio of product white powder powder, water and glass sphere is: powder: water: ball ≈ 1: 1: 1, ball milling 2~4 hours.Powder behind the ball milling and water become the powder slurry, and powder is starched in the beaker of packing into, use 2%HCl solution stirring 2~4 hours, then are washed till neutrality with 70~80 ℃ of hot deionized waters.Sieve through 400 orders, 110~130 ℃ of oven dry in baking oven obtain fluorescent material behind the suction filtration.The fluorescent material of oven dry is sieved through 260 orders again, and detect, promptly obtain red fluorescence powder of the present invention.
Characteristics of the present invention are: (1) obtains cubic structure (Y at high temperature more than 1250 ℃
1-x-yGd
xEu
y)
2O
3Fluorescent material, even Gd content is up to 90% o'clock, i.e. (Y
0.06Gd
0.90Eu
0.04)
2O
3The time, material is a cubic structure still, does not have monocline Gd
2O
3Dephasign exists.As Fig. 1 is (Y
0.06Gd
0.90Eu
0.04)
2O
3The XRD figure of fluorescent material (2 θ=18 °~74 °), this is a typical body-centered cubic structure, and diffraction peak is very strong, and (FWHM) is narrow for the half-breadth height, and the crystal structure quality is good; (2) high temperature that is obtained cube (Y, Gd)
2O
3: the emmission spectrum of Eu fluorescent material and cube Y
2O
3: Eu and cube Gd
2O
3: Eu is identical, as shown in Figure 2; (3) satisfied activator concentration scope is arranged, as shown in Figure 3, optimum concn is 0.04mol; (4) select for use a small amount of boric acid, metal fluoride and metal carbonate as additive, not only reduced calcination temperature, and improve luminosity, promote crystal growth; (5) manufacturing process is simple, easy handling, suitable batch production.
Description of drawings:
Fig. 1 is (Y
0.06Gd
0.90Eu
0.04)
2O
3The XRD figure of fluorescent material (2 θ=18 °~74 °);
Fig. 2 be cube (Y, Gd)
2O
3: Eu, Y
2O
3: Eu, Gd
2O
3: the emmission spectrum figure of Eu fluorescent material;
Fig. 3 is light-emitting phosphor intensity and activator Eu
3+The graph of a relation of concentration.
Embodiment:
Embodiment 1, take by weighing Y
2O
3100g, Eu
2O
37g, BaF
20.1g, H
3BO
30.3g, above-mentioned raw materials is packed in the ball grinder, put into agate ball, the weight ratio of ball and raw material is 1: 1, the ball milling time is more than 10 hours.The material of the mixing corundum crucible of packing into is put into high temperature sintering furnace in the lump, the sintering oven temperature is raised to 1270 ℃, constant temperature 2 hours is treated that furnace temperature is reduced to take out crucible below 1000 ℃ and be cooled to room temperature.The material fragmentation of will coming out of the stove in the ball grinder of packing into, adds entry and φ 3mm glass sphere, powder: water: ball ≈ 1: 1: 1, and ball milling is 2 hours at a slow speed.Powder is starched in the beaker of packing into, used 2-5%HCl solution stirring 2 hours, then be washed till neutrality, sieve 120 ℃ of oven dry in baking oven behind the suction filtration through 400 orders with 70-80 ℃ of hot deionized water.The fluorescent material of oven dry is sieved through 260 orders again, promptly obtain (Y after testing
1-x-yGd
xEu
y)
2O
3Red-emitting phosphors, relative luminous intensity is 100 under cathode-ray exciting.
Embodiment 3, take by weighing Y
2O
370g, Gd
2O
322g, Eu
2O
313g, BaF
20.1g, H
3BO
30.3g all the other conditions are with embodiment 1, relative luminous intensity is 87.2 under cathode-ray exciting.
Embodiment 4, take by weighing Y
2O
360g, Gd
2O
344g, Eu
2O
36g, BaF
20.1g, H
3BO
30.3g,, all the other conditions are with embodiment 1, and relative luminous intensity is 102.4 under cathode-ray exciting.
Embodiment 5, take by weighing Y
2O
350g, Gd
2O
339.5g, Eu
2O
311.5g, BaF
20.1g, H
3BO
30.3g all the other conditions are with embodiment 1, relative luminous intensity is 91.6 under cathode-ray exciting.
Embodiment 6, take by weighing Y
2O
340g, Gd
2O
357g, Eu
2O
35g, BaF
20.1g, H
3BO
30.3g,, all the other conditions are with embodiment 1, and relative luminous intensity is 101.6 under cathode-ray exciting.
Embodiment 7, take by weighing Y
2O
340g, Gd
2O
363g, Eu
2O
312g, BaF
20.35g, H
3BO
30.6g all the other conditions are with embodiment 1, relative luminous intensity is 89.8 under cathode-ray exciting.
Embodiment 8, take by weighing Y
2O
320g, Gd
2O
386g, Eu
2O
35g, BaF
20.1g, H
3BO
30.3g all the other conditions are with embodiment 1, relative luminous intensity is 97.3 under cathode-ray exciting.
Embodiment 9, take by weighing Y
2O
320g, Gd
2O
3107g, Eu
2O
313g, BaF
20.4g, H
3BO
30.7g all the other conditions are with embodiment 1, relative luminous intensity is 86.5 under cathode-ray exciting.
Embodiment 10, take by weighing Y
2O
370g, Gd
2O
330g, Eu
2O
36g, BaF
20.1g, H
3BO
30.3g all the other conditions are with embodiment 1, relative luminous intensity is 103.1 under cathode-ray exciting.
Claims (9)
1, a kind of rare earth oxide red fluorescence powder is characterized in that at a cube Y
2O
3: Eu
3+Introduce the Gd ion in the system and make it part replacement Y, Y under 1250 ℃ of high temperature
2O
3And Gd
2O
3And Y
2O
3, Gd
2O
3And Eu
2O
3Formation have cubic structure (Y, Gd)
2O
3(Y, Gd, Eu)
2O
3Solid solution, its chemical expression is: (Y
1-x-yGd
xEu
y)
2O
3, wherein x is the content of matrix components Gd, y is the content of activator Eu; Also include additive in the Solid solution.
2, rare earth oxide red fluorescence powder according to claim 1 is characterized in that its matrix part is made up of the oxide compound of Gd and Y, and the content of matrix components Gd is 0<x≤0.9.
3, rare earth oxide red fluorescence powder according to claim 2 is characterized in that the activator material is for containing Eu
3+Oxide compound, content is 0.01≤y≤0.1.
4, rare earth oxide red fluorescence powder according to claim 3, it is characterized in that the additive that is comprised be in boric acid, metal fluoride, the metal carbonate one or more.
5, rare earth oxide red fluorescence powder according to claim 4 is characterized in that the additive metal fluorochemical can be CaF
2, metal carbonate can be K
2CO
3Or Li
2CO
3
6, rare earth oxide red fluorescence powder according to claim 5 is characterized in that the additive add-on is 0.1-0.5wt%.
7, the preparation method of rare earth oxide red fluorescence powder according to claim 1, include select materials, batch mixing, sintering and last handling process, it is characterized in that by (Y
1-x-yGd
xEu
y)
2O
3The chemical expression metering is than the Y that takes by weighing a certain amount of 99.99% purity
2O
3, Gd
2O
3, Eu
2O
3And the above additive of purity assay; With above-mentioned Y
2O
3, Gd
2O
3, Eu
2O
3And additive packs in the ball grinder, puts into agate ball, ball mill mixing; Raw material behind the ball mill mixing is packed in alumina crucible or the corundum crucible, add a cover and put into the high temperature sintering furnace sintering; The white powder product fragmentation that sintering is obtained, pack in the ball grinder, add entry and φ 3mm glass sphere, powder behind the ball milling and water become the powder slurry, and powder is starched in the beaker of packing into, use 2%HCl solution stirring 2~4 hours, then be washed till neutrality with 70~80 ℃ of hot deionized waters, sieve through 400 orders, 110~130 ℃ of oven dry in baking oven obtain fluorescent material behind the suction filtration.
8, the preparation method of rare earth oxide red fluorescence powder according to claim 7 is characterized in that the agate ball that batch mixing is used and the weight ratio of raw material are 1: 1, and the ball milling time is more than 10 hours; Under the room temperature batch mixing is packed in the alumina crucible, rise to 1250~1400 ℃ with stove, constant temperature 1~2 hour stops to heat up, and reduces to below 1000 ℃ with stove and takes out; White powder product in the aftertreatment: water: glass sphere ≈ 1: 1: 1.
9, the preparation method of rare earth oxide red fluorescence powder according to claim 7 is characterized in that the fluorescent material of oven dry is sieved through 260 orders again.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN 02144731 CN1212367C (en) | 2002-12-07 | 2002-12-07 | Red RE oxide luminophor and its prepn |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN 02144731 CN1212367C (en) | 2002-12-07 | 2002-12-07 | Red RE oxide luminophor and its prepn |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| CN1506439A true CN1506439A (en) | 2004-06-23 |
| CN1212367C CN1212367C (en) | 2005-07-27 |
Family
ID=34232080
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN 02144731 Expired - Fee Related CN1212367C (en) | 2002-12-07 | 2002-12-07 | Red RE oxide luminophor and its prepn |
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| Country | Link |
|---|---|
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Cited By (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN1331982C (en) * | 2004-10-11 | 2007-08-15 | 北京有色金属研究总院 | Phosphor powder of composite oxide in use for white light LED and fabricated electric light source |
| CN100540629C (en) * | 2007-11-12 | 2009-09-16 | 中国科学院长春光学精密机械与物理研究所 | Near ultraviolet or blue-light excited red fluorescence powder and preparation method thereof |
| CN100575451C (en) * | 2008-01-24 | 2009-12-30 | 同济大学 | A kind of red nano-fluorescent powder and preparation method thereof |
| CN102888223A (en) * | 2012-09-07 | 2013-01-23 | 彩虹集团电子股份有限公司 | Manufacture method for red fluorescent powder for three-primary-color energy saving lamp |
-
2002
- 2002-12-07 CN CN 02144731 patent/CN1212367C/en not_active Expired - Fee Related
Cited By (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN1331982C (en) * | 2004-10-11 | 2007-08-15 | 北京有色金属研究总院 | Phosphor powder of composite oxide in use for white light LED and fabricated electric light source |
| CN100540629C (en) * | 2007-11-12 | 2009-09-16 | 中国科学院长春光学精密机械与物理研究所 | Near ultraviolet or blue-light excited red fluorescence powder and preparation method thereof |
| CN100575451C (en) * | 2008-01-24 | 2009-12-30 | 同济大学 | A kind of red nano-fluorescent powder and preparation method thereof |
| CN102888223A (en) * | 2012-09-07 | 2013-01-23 | 彩虹集团电子股份有限公司 | Manufacture method for red fluorescent powder for three-primary-color energy saving lamp |
Also Published As
| Publication number | Publication date |
|---|---|
| CN1212367C (en) | 2005-07-27 |
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