CN112159220A

CN112159220A - High-thermal-stability high-quantum-efficiency fluorescent ceramic for white light LED/LD and preparation method thereof

Info

Publication number: CN112159220A
Application number: CN202011015514.6A
Authority: CN
Inventors: 张乐; 马跃龙; 孙炳恒; 康健; 邵岑; 陈东顺; 周天元; 黄国灿; 李明; 陈浩
Original assignee: Xuzhou Attapulgite Photoelectric Technology Co ltd
Current assignee: Xuzhou Attapulgite Photoelectric Technology Co ltd
Priority date: 2020-09-24
Filing date: 2020-09-24
Publication date: 2021-01-01
Anticipated expiration: 2040-09-24
Also published as: CN112159220B

Abstract

The invention discloses a high-thermal stability high-quantum efficiency fluorescent ceramic for a white light LED/LD and a preparation method thereof, wherein the chemical formula of the fluorescent ceramic is as follows: (Y)_yCe_zLu_1‑z‑y)₃(Sc_xAl_1‑x)₂Al₃O₁₂Wherein z is Ce³⁺Doped Lu³⁺Mole percent of the sites, Y being Y³⁺Doped Lu³⁺Mole percent of the sites, x being Sc³⁺Doped octahedral Al³⁺Mole percent of the sites, 0.5<x≤0.8，0.4≤y≤0.6，y：x＝2：3～3：4，0<z is less than or equal to 0.015, and the material is prepared by sintering by a solid-phase reaction method. The transparent fluorescent ceramic material of the inventionThe emission spectrum has a main peak of 520-550 nm and a full width at half maximum of 90-110 nm. Under the excitation of a high-power blue LED (350-500 mA) or a blue LD (2-10W), the light emission from green light to green-yellow light is realized, the color temperature is 4000-10000K, the luminous intensity is attenuated by 2-5% at 150 ℃, and the internal quantum efficiency is 82-88%. The prepared ceramic has simple process and is easy for industrial production.

Description

High-thermal-stability high-quantum-efficiency fluorescent ceramic for white light LED/LD and preparation method thereof

Technical Field

The invention relates to the technical field of fluorescent ceramics, in particular to high-thermal-stability high-quantum-efficiency fluorescent ceramic for a white light LED/LD and a preparation method thereof.

Background

Fluorescent conversion white light emitting diodes and laser diodes (abbreviated as LEDs/LDs) are widely used as solid-state illumination light sources for new generation, because of their advantages of high luminous efficiency, good robustness, small device size, long service life, etc. With the updating of the technology, the fluorescent powder Ce is used³⁺:Y₃Al₅O₁₂The traditional mode of mixing (Ce: YAG for short) and organic silica gel is gradually replaced by a remote excitation packaging mode of an excitation source and Ce: YAG fluorescent ceramic. As a core material for color conversion, the Ce: YAG fluorescent ceramic has become a hot spot of domestic and foreign research due to the advantages of high thermal conductivity, good mechanical properties, stable physical and chemical properties, easy realization of high doping concentration and the like. However, in the blue LED/LD laserYAG fluorescent ceramics have obvious disadvantages, such as: the color proportion of the emitted light is disordered, the improved thermal quenching temperature is low, the quantum efficiency is low and the like, so that the prepared packaged device has the defects of low color rendering index, high relative color temperature, low luminous efficiency and the like, and the high-power use requirement is difficult to meet.

YAG fluorescent ceramic is reported to regulate the light emitting behavior and the spectral emission peak. However, when the performance of the emission spectrum is regulated, the thermal stability and quantum efficiency of the fluorescent ceramic are reduced. The quantum efficiency is far less than that of the original substrate, and the luminous intensity is greatly reduced to below 50% in the normal service temperature environment. At present, the method for regulating and controlling the spectrum of the fluorescent ceramic at home and abroad is mainly divided into Mg²⁺-Si⁴⁺Ion pair replacement (J.Mater.chem.C,2018,6,12200-12205.J.Mater.chem.C,2016,4, 2359-. The above method can improve the individual luminescence properties, though. However, the disadvantages are also obvious, the concentration of the added external ions for generating the pure garnet phase is difficult to control accurately, and a heterogeneous phase is generated, so that the thermal stability and the quantum efficiency of the corresponding fluorescent ceramic are both reduced remarkably.

Disclosure of Invention

The invention aims to provide a fluorescent ceramic with high thermal stability and high quantum efficiency for a white light LED/LD, which has high thermal stability and high quantum efficiency.

The invention also aims to provide a preparation method of the high-thermal stability quantum efficiency fluorescent ceramic for the white light LED/LD, which is easy for industrial production.

In order to achieve the purpose, the technical scheme adopted by the invention is as follows: a high-thermal stability high-quantum efficiency fluorescent ceramic for white light LED/LD, the chemical formula of the fluorescent ceramic is as follows:

(Y_yCe_zLu_1-z-y)₃(Sc_xAl_1-x)₂Al₃O₁₂

wherein x is Sc³⁺Doped octahedral Al³⁺Mole percent of the sites, Y being Y³⁺Doped Lu³⁺Mole percent of the sites, z being Ce³⁺Doped Lu³⁺Mole percent of the sites, 0.5<x≤0.8，0.4≤y≤0.6，y：x＝2： 3～3：4，0<z≤0.015。

Under the excitation of a high-power blue light LED (350-500 mA) or a blue light LD (2W-10W), the light emission from green light to green-yellow light is realized, the color temperature is 4000-10000K, the reduction of the luminous intensity along with the temperature rise is not obvious along with the operation of the device, the luminous intensity is attenuated by 2-5% at 150 ℃, and the thermal stability is excellent. The quantum efficiency in the ceramic is between 82% and 88%.

The invention also provides a preparation method of the high-thermal-stability high-quantum-efficiency fluorescent ceramic for the white light LED/LD, which adopts a solid-phase reaction method for sintering, and specifically comprises the following steps:

(1) according to the formula (Y)_yCe_zLu_1-z-y)₃(Sc_xAl_1-x)₂Al₃O₁₂，0.5<x≤0.8，0.4≤y≤0.6， y：x＝2：3～3：4，0<z is less than or equal to 0.015, and alpha-alumina, yttrium oxide, lutetium oxide, scandium oxide and cerium oxide are respectively weighed as raw material powder according to the stoichiometric ratio of the elements; mixing and ball-milling raw material powder and a ball-milling medium according to a certain proportion to obtain mixed slurry;

(2) placing the mixed slurry obtained in the step (1) in a drying oven for drying, and sieving the dried mixed powder;

(3) placing the powder sieved in the step (2) into a grinding tool for forming, and then carrying out cold isostatic pressing to obtain a biscuit with the relative density of 51-52%;

(4) sintering the biscuit obtained in the step (3) in a vacuum furnace at the sintering temperature of 1680-1750 ℃ for 6-10 h, wherein the sintering vacuum degree is not lower than 10^-4Pa, obtaining fluorescent ceramic;

(5) and (3) carrying out air annealing treatment on the fluorescent ceramic subjected to vacuum sintering in the step (4), wherein the annealing temperature is 1000-1150 ℃, and the heat preservation time is 20-50 h, so as to obtain the fluorescent ceramic with the relative density of 99.2-99.9%.

Preferably, in the step (1), the ball-to-feed ratio is 3.5-4.5: 1, the diameter of the selected grinding ball is 0.5 cm-2 cm.

Preferably, in the step (1), the ball milling rotation speed is 170r/min to 190r/min, and the ball milling time is 25h to 40 h.

Preferably, in the step (1), the ball milling medium is absolute ethyl alcohol, and the mass-to-volume ratio of the raw material powder to the ball milling medium is 2-3: 1 g/ml.

Preferably, in the step (2), the drying time is 10-15 h, and the drying temperature is 60-70 ℃.

Preferably, in the step (2), the number of the sieved screens is 50-150 meshes, and the sieving frequency is 4-6.

Preferably, in the step (4), the temperature rise rate in the vacuum sintering stage is 0.25-0.5 ℃/min, and the temperature drop rate after sintering is 2-4 ℃/min.

Preferably, in the step (4), the temperature rise rate in the air annealing stage is 0.25-0.5 ℃/min, and the temperature drop rate is 2-4 ℃/min.

Compared with the prior art, the invention has the following beneficial effects:

1. the fluorescent ceramic provided by the invention is based on Ce: LuAG, using Sc³⁺Ion substituted octahedral Al³⁺Ion site and Y³⁺Ion-substituted dodecahedral Lu³⁺The concept of ions, fully utilizes Sc in octahedral lattice positions³⁺Ions and Al³⁺New effective ion radius of ion formation and the ion diameter at dodecahedral lattice site Y³⁺Ions and Lu³⁺The matching effect of the new effective ionic radius of ion formation. On the basis of regulating the micro-coordination structure of the system, the structural rigidity of the system is provided, and further the Ce is improved³⁺The ion-emitting thermal stability, and the ceramic also has higher quantum efficiency. Sc of introduced octahedral sites³⁺Y of each position of ion and dodecahedron³⁺The ions can promote Ce³⁺The coordination complexity of the crystal field environment of the ion is further changed, the full width at half maximum and the position of the peak of the emission spectrum are further changed, and the color of the emitted light can be realizedAnd (6) adjusting.

2. The invention combines a solid-phase reaction method with a vacuum sintering technology, and controls the chemical proportion to ensure that the Sc³⁺Ions occupying octahedral Al only³⁺Ion site, Y³⁺Ion occupying dodecahedral Lu³⁺And (4) ion lattice sites. The ionic radius of the whole system is matched properly, and the garnet pure-phase fluorescent ceramic is obtained.

3. The fluorescent ceramic provided by the invention can effectively solve the problems that Ce: the YAG fluorescent ceramic has the problems of insufficient green light and the problem of preparing lutetium aluminum garnet pure phase under high Sc content, and can effectively improve the luminous performance of the LED/LD device. Under the excitation of a high-power blue light LED (350-500 mA) or a blue light LD (2W-10W), the emission spectrum has a main peak of 520-550 nm and a half-height width of 90-110 nm, so that the green-green light to green-yellow light emission is realized, and the color temperature is 4000-10000K.

4. The fluorescent ceramic provided by the invention has the advantages that the luminous intensity is attenuated by 2-5% at 150 ℃, and the internal quantum efficiency is 82-88%.

Drawings

FIG. 1 is a diagram of a fluorescent ceramic prepared according to examples 1 and 2 of the present invention;

FIG. 2 is an XRD pattern of a fluorescent ceramic obtained according to examples 1 and 2 of the present invention and a comparative example;

FIG. 3 is a SEM image of the surface of a fluorescent ceramic prepared in example 1 of the present invention;

FIG. 4 is an emission spectrum of a fluorescent ceramic obtained in example 1 of the present invention under excitation at a wavelength of 460 nm;

FIG. 5 shows the electroluminescence spectrum of the fluorescent ceramic prepared in example 1 under the excitation of a 460nm blue LED chip (I ═ 350 mA);

FIG. 6 is a graph showing the emission spectrum of the fluorescent ceramic according to the temperature variation obtained in example 1 of the present invention;

FIG. 7 is an emission spectrum of a fluorescent ceramic prepared in example 2 of the present invention under excitation at a wavelength of 460 nm;

FIG. 8 shows the electroluminescence spectrum of the fluorescent ceramic prepared in example 2 under the excitation of a 460nm blue LED chip (I ═ 350 mA);

FIG. 9 is a graph showing the transmittance of the fluorescent ceramics obtained in examples 1 and 2 of the present invention and comparative example;

FIG. 10 is a drawing showing a fluorescent ceramic produced according to a comparative example of the present invention;

FIG. 11 is an SEM image of the surface of a fluorescent ceramic prepared according to a comparative example of the present invention.

Detailed Description

The invention is described in further detail below with reference to the figures and specific examples.

The raw material powders used in the following examples are all commercial products, the purity is more than 99.9%, and the average grain diameter of the alpha-phase alumina is 150 nm-200 nm; the average grain diameter of the yttrium oxide is 10 nm-50 nm; the average grain diameter of the lutetium oxide is 10nm to 50 nm; the average grain diameter of the scandium oxide is 1 nm-50 nm; the average grain diameter of the cerium oxide is 1 nm-50 nm.

Example 1: the preparation chemical formula is (Lu)_0.596Y_0.4Ce_0.004)₃(Al_0.4Sc_0.6)₂Al₃O₁₂Fluorescent ceramic

(1) Setting the mass of the target product to be 60g according to the chemical formula (Lu)_0.594Y_0.4Ce_0.006)₃(Al_0.2Sc_0.8)₂Al₃O₁₂Weighing alpha-alumina (15.25g), yttrium oxide (10.55g), lutetium oxide (27.73g), scandium oxide (6.40g) and cerium oxide (0.16g) as raw material powder according to the stoichiometric ratio of the elements; mixing the raw material powder with 120ml of absolute ethyl alcohol, adding 210g of alumina balls with the diameter of 0.5mm, and carrying out ball milling in an alumina ball milling tank, wherein the ball milling speed is 170r/min, and the ball milling time is 40 h;

(2) and (2) placing the mixed slurry subjected to ball milling in the step (1) into a 60 ℃ forced air drying oven for drying for 10 hours, and sieving the dried mixed powder with a 50-mesh sieve for 6 times.

(3) Putting the calcined powder in the step (2) into a grinding tool for dry pressing and molding, and then carrying out cold isostatic pressing molding, wherein the relative density of the molded biscuit is 51%;

(4) sintering the ceramic biscuit obtained in the step (4) in a vacuum furnace, wherein the sintering temperature is 1680 ℃, the heat preservation time is 10 hours, the heating rate is 0.25 ℃/min, and the cooling rate is 2 ℃/min after sintering;

(5) putting the ceramic obtained in the step (5) into a muffle furnace for air annealing at the annealing temperature of 1000 ℃, the heat preservation time of 50h, the heating rate of 0.25 ℃/min, and the cooling rate of 2 ℃/min after sintering; the relative density of the ceramic was 99.2%.

And (3) polishing the two sides of the sintered transparent ceramic until the thickness of the ceramic is 1.0mm to obtain the fluorescent ceramic with high thermal stability and high quantum efficiency, wherein the real object of the fluorescent ceramic is a blue-yellow transparent ceramic, and characters below the ceramic bottom are clearly visible (as numbered 1 in figure 1).

(Lu) obtained in this example_0.596Y_0.4Ce_0.004)₃(Al_0.4Sc_0.6)₂Al₃O₁₂XRD testing of the fluorescent ceramic is carried out, and the result is shown in figure 2, which shows that: the prepared material is a pure garnet phase.

(Lu) obtained in this example_0.596Y_0.4Ce_0.004)₃(Al_0.4Sc_0.6)₂Al₃O₁₂The fluorescent ceramic is observed under a scanning electron microscope, and the result is shown in figure 3, and the ceramic crystal grain size is uniform, no impurity phase exists, and the result is consistent with the XRD test result.

(Lu) obtained in the example_0.596Y_0.4Ce_0.004)₃(Al_0.4Sc_0.6)₂Al₃O₁₂When the fluorescent ceramic is excited at the wavelength of 460nm, as shown in FIG. 4, the main peak of the emission spectrum is 539nm, and the full width at half maximum is 102 nm. The ceramic is excited by a 460nm blue LED chip (I is 350mA) to carry out an electroluminescence spectrum test, and as shown in figure 5, the green-green light emission can be realized, and the color temperature is 10000K.

(Lu) obtained in this example_0.596Y_0.4Ce_0.004)₃(Al_0.4Sc_0.6)₂Al₃O₁₂The fluorescent ceramic is subjected to emission spectrum testing as a function of temperature. The results are shown in FIG. 6, indicating that: the luminous intensity of the ceramic is gradually reduced along with the increase of the temperature, and the luminous intensity is only reduced by 2.3 percent at 150 ℃. The internal quantum efficiency was 88%.

(Lu) obtained in this example_0.596Y_0.4Ce_0.004)₃(Al_0.4Sc_0.6)₂Al₃O₁₂The transmittance test of the fluorescent ceramic is shown in fig. 9, which shows that: the transmittance T of the fluorescent ceramic is 69.06% @800 nm.

Example 2: the preparation chemical formula is (Lu)_0.385Y_0.6Ce_0.015)₃(Al_0.2Sc_0.8)₂Al₃O₁₂Fluorescent ceramic

(1) Setting the mass of the target product to be 60g according to the chemical formula (Lu)_0.385Y_0.6Ce_0.015)₃(Al_0.2Sc_0.8)₂Al₃O₁₂Weighing alpha-alumina (14.36g), yttrium oxide (16.84g), lutetium oxide (19.04g), scandium oxide (9.14g) and cerium oxide (0.64g) as raw material powder according to the stoichiometric ratio of the elements; mixing the raw material powder with 180ml of absolute ethyl alcohol, adding 270g of alumina balls with the diameter of 2mm, and carrying out ball milling in an alumina ball milling tank, wherein the ball milling speed is 190r/min, and the ball milling time is 25 h;

(2) and (2) placing the mixed slurry subjected to ball milling in the step (1) into a 70 ℃ forced air drying oven for drying for 10 hours, and sieving the dried mixed powder with a 150-mesh sieve for 4 times.

(3) Putting the calcined powder in the step (2) into a grinding tool for dry pressing and molding, and then carrying out cold isostatic pressing molding, wherein the relative density of the molded biscuit is 52%;

(4) sintering the ceramic biscuit obtained in the step (4) in a vacuum furnace, wherein the sintering temperature is 1750 ℃, the heat preservation time is 6 hours, the heating rate is 0.5 ℃/min, and the cooling rate is 4 ℃/min after sintering;

(5) putting the ceramic obtained in the step (5) into a muffle furnace for air annealing at 1150 ℃, keeping the temperature for 20 hours, and cooling at 4 ℃/min after sintering, wherein the heating rate is 0.5 ℃/min; the relative density of the ceramic was 99.9%.

And (3) polishing the two sides of the sintered transparent ceramic until the thickness of the ceramic is 1.0mm to obtain the fluorescent ceramic with high thermal stability and high quantum efficiency, wherein the real object of the fluorescent ceramic is a blue-yellow transparent ceramic, and characters below the ceramic bottom are clearly visible (as numbered 2 in figure 1).

(Lu) obtained in this example_0.385Y_0.6Ce_0.015)₃(Al_0.2Sc_0.8)₂Al₃O₁₂XRD test is carried out on the fluorescent ceramic, and the test result is shown in figure 2, which shows that: the prepared material is a pure garnet phase.

(Lu) obtained in this example_0.385Y_0.6Ce_0.015)₃(Al_0.2Sc_0.8)₂Al₃O₁₂The emission spectrum of the fluorescent ceramic under the excitation of 460nm wavelength is shown in FIG. 7, and the main peak of the emission spectrum is 546nm, and the full width at half maximum is 110 nm. The ceramic is excited by a 460nm blue LED chip (I is 350mA) to carry out an electroluminescence spectrum test, and as shown in figure 8, green and yellow light emission can be realized, and the color temperature is 4000K.

(Lu) obtained in this example_0.385Y_0.6Ce_0.015)₃(Al_0.2Sc_0.8)₂Al₃O₁₂The fluorescent ceramic is subjected to emission spectrum testing as a function of temperature. The results show that: the luminous intensity of the ceramic gradually decreases with increasing temperature, and the luminous intensity only decreases by 4.8% at 150 ℃. The internal quantum efficiency was 82%.

(Lu) obtained in this example_0.385Y_0.6Ce_0.015)₃(Al_0.2Sc_0.8)₂Al₃O₁₂The transmittance test of the fluorescent ceramic is shown in fig. 9, which shows that: the transmittance T of the fluorescent ceramic is 63.61% @800 nm.

Comparative example: the preparation chemical formula is (Lu)_0.997Ce_0.003)₃(Al_0.5Sc_0.5)₂Al₃O₁₂Fluorescent ceramic

(1) Setting the mass of the target product to be 60g according to the chemical formula (Lu)_0.997Ce_0.003)₃(Al_0.5Sc_0.5)₂Al₃O₁₂The stoichiometric ratio of each element is respectively weighed alpha-alumina (14.07g) and lutetium oxide(41.07g), scandium oxide (4.75g) and cerium oxide (0.11g) as raw material powders; mixing the raw material powder with 150ml of absolute ethyl alcohol, adding 240g of alumina balls with the diameter of 1.5mm, and carrying out ball milling in an alumina ball milling tank, wherein the ball milling speed is 185r/min, and the ball milling time is 20 h;

(2) putting the mixed slurry subjected to ball milling in the step (1) into a 60 ℃ forced air drying oven for drying for 10 hours, and sieving the dried mixed powder with a 50-mesh sieve for 6 times;

(3) putting the calcined powder in the step (2) into a grinding tool for dry pressing and molding, and then carrying out cold isostatic pressing molding, wherein the relative density of the molded biscuit is 51.5%;

(4) sintering the ceramic biscuit obtained in the step (4) in a vacuum furnace, wherein the sintering temperature is 1700 ℃, the heat preservation time is 6 hours, the heating rate is 0.25 ℃/min, and the cooling rate is 2 ℃/min after sintering;

(5) putting the ceramic obtained in the step (5) into a muffle furnace for air annealing at 1050 ℃, keeping the temperature for 15h, and cooling at 2 ℃/min after sintering, wherein the heating rate is 0.25 ℃/min; the relative density of the ceramic was 99.1%.

And (3) polishing the two sides of the sintered transparent ceramic to the thickness of 1.0mm to obtain the fluorescent ceramic, wherein the actual object of the fluorescent ceramic is a blue-yellow transparent ceramic, and characters below the ceramic are covered (as shown in figure 10).

(Lu) obtained in this comparative example_0.997Ce_0.003)₃(Al_0.5Sc_0.5)₂Al₃O₁₂XRD test is carried out on the fluorescent ceramic, and the test result is shown in figure 2, which shows that: the prepared material is garnet phase and scandium oxide phase.

(Lu) obtained in this comparative example_0.997Ce_0.003)₃(Al_0.5Sc_0.5)₂Al₃O₁₂The fluorescent ceramic is observed under a scanning electron microscope, and the result is shown in fig. 11, and it can be seen that an obvious impurity phase exists, and the main phase crystal grains and the impurity phase of the ceramic coexist.

(Lu) obtained in the example_0.997Ce_0.003)₃(Al_0.5Sc_0.5)₂Al₃O₁₂Under the excitation of 460nm wavelength, the main peak of the emission spectrum of the fluorescent ceramic is 519nm, and the full width at half maximum is 88.7 nm. The ceramic is excited by an LED chip (I is 350mA) with the blue light of 460nm to carry out electroluminescence spectrum test, and can realize deep blue light emission and color temperature of 8400K.

(Lu) obtained in this comparative example_0.997Ce_0.003)₃(Al_0.5Sc_0.5)₂Al₃O₁₂The fluorescent ceramic is subjected to emission spectrum testing as a function of temperature. The results show that: the luminous intensity of the ceramic gradually decreases with increasing temperature, and the luminous intensity decreases by 21.4% at 150 ℃. The internal quantum efficiency was 72%.

(Lu) obtained in this comparative example_0.997Ce_0.003)₃(Al_0.5Sc_0.5)₂Al₃O₁₂The fluorescent ceramic was subjected to a transmittance test, as shown in fig. 9, and the results showed that: the transmittance T of the fluorescent ceramic is 0.34% @800 nm.

Claims

1. A high-thermal stability high-quantum efficiency fluorescent ceramic for white light LED/LD is characterized in that the chemical formula of the fluorescent ceramic is as follows:

(Y_yCe_zLu_1-z-y)₃(Sc_xAl_1-x)₂Al₃O₁₂

wherein x is Sc³⁺Doped octahedral Al³⁺Mole percent of the sites, Y being Y³⁺Doped Lu³⁺Mole percent of the sites, z being Ce³⁺Doped Lu³⁺Mole percent of the sites, 0.5<x≤0.8，0.4≤y≤0.6，y：x＝2：3～3：4，0<z≤0.015。

2. The high thermal stability and high quantum efficiency fluorescent ceramic for white light LED/LD according to claim 1, characterized in that, when the ambient temperature is 150 ℃, the luminous intensity of the fluorescent ceramic is attenuated by 2-5%, and the internal quantum efficiency is between 82-88%.

3. The preparation method of the fluorescent ceramic with high thermal stability and high quantum efficiency for the white light LED/LD according to claim 1 or 2, characterized in that the sintering is carried out by a solid phase reaction method, and the method specifically comprises the following steps:

(1) according to the formula (Y)_yCe_zLu_1-z-y)₃(Sc_xAl_1-x)₂Al₃O₁₂，0.5<x≤0.8，0.4≤y≤0.6，y：x＝2：3～3：4，0<Respectively weighing alpha-alumina, yttrium oxide, lutetium oxide, scandium oxide and cerium oxide as raw material powder according to the stoichiometric ratio of each element with z being less than or equal to 0.015; mixing and ball-milling raw material powder and a ball-milling medium according to a certain proportion to obtain mixed slurry;

4. The method for preparing high thermal stability and high quantum efficiency fluorescent ceramic for white light LED/LD according to claim 3, characterized in that, in the step (1), the ball milling rotation speed is 170 r/min-190 r/min, and the ball milling time is 25 h-40 h.

5. The preparation method of the fluorescent ceramic with high thermal stability and high quantum efficiency for the white light LED/LD according to claim 3, wherein in the step (1), the ball milling medium is absolute ethyl alcohol, and the mass-to-volume ratio of the raw material powder to the ball milling medium is 2-3: 1 g/ml.

6. The method for preparing fluorescent ceramic with high thermal stability and high quantum efficiency for white LED/LD according to claim 3, wherein in the step (2), the drying time is 10-15 h, and the drying temperature is 60-70 ℃.

7. The method for preparing high thermal stability and high quantum efficiency fluorescent ceramic for white light LED/LD according to claim 3, characterized in that in the step (2), the mesh number of the sieved screen is 50-150 meshes, and the sieving frequency is 4-6.

8. The method for preparing high thermal stability and high quantum efficiency fluorescent ceramic for white LED/LD according to claim 3, characterized in that in the step (4), the temperature rise rate in the vacuum sintering stage is 0.25-0.5 ℃/min, and the temperature drop rate after sintering is 2-4 ℃/min.

9. The method for preparing high thermal stability and high quantum efficiency fluorescent ceramic for white LED/LD according to claim 3, characterized in that in the step (5), the temperature rise rate in the air annealing stage is 0.25-0.5 ℃/min, and the temperature drop rate after sintering is 2-4 ℃/min.