JP5565046B2 - Method for producing Li-containing α-sialon phosphor - Google Patents

Description

  The present invention relates to a method for producing an optical functional material having a function of converting a part of irradiated light into light having a different wavelength. Specifically, the present invention relates to a method for producing a sialon-based phosphor activated with a rare earth metal element suitable for an ultraviolet to blue light source.

  In recent years, blue light emitting diodes (LEDs) have been put into practical use, and white LEDs using the blue LEDs have been vigorously developed. White LEDs have lower power consumption and longer life than existing white light sources, and are therefore being used for backlights for liquid crystal panels, indoor and outdoor lighting devices, and the like.

  The white LED currently being developed is obtained by applying YAG (yttrium, aluminum, garnet) doped with Ce on the surface of a blue LED. However, the fluorescence wavelength of YAG doped with Ce is in the vicinity of 530 nm. If this fluorescent color and the light of a blue LED are mixed to form white light, white light with strong bluish light is obtained, and good white color cannot be obtained.

  On the other hand, it is known that an α-sialon-based phosphor activated with a rare earth element generates fluorescence having a longer wavelength than that of Ce-doped YAG (see Patent Document 1). When a white LED is configured using such sialon fluorescence, a white LED with a light bulb color having a lower color temperature than a white LED using YAG can be produced.

Further, in Non-Patent Document 1, when the composition formula of the sialon-based phosphor is expressed as M _x Si _{12- (m + n)} Al _{m + n On} N _16-n , m = 2.8 has the highest intensity, The peak wavelength at that time is about 595 nm. This fluorescent wavelength is suitable for a white LED having a low color temperature such as a light bulb color. However, white LEDs having higher color temperatures such as daylight white and daylight with higher color temperatures cannot be produced.

  Daylight white and daylight colors are widely used not only for lighting but also for backlights of liquid crystal display devices, and societal needs are greater than those of light bulbs. Therefore, it is desired to shorten the wavelength of the fluorescence of the sialon phosphor. However, as can be seen from Non-Patent Document 1, in the α-sialon phosphor containing Ca, the fluorescence intensity decreases when the fluorescence wavelength is shorter than 595 nm. Therefore, it has been difficult to produce a sialon-based phosphor that emits short-wavelength fluorescence suitable for producing a high-brightness daylight white or daylight color LED in combination with a blue LED.

  In order to solve this, Patent Document 2 discloses a Li (lithium) -containing α-sialon-based phosphor. This can emit fluorescence having a shorter wavelength than the Ca-containing α-sialon phosphor.

  Generally, in order to obtain a sialon that emits short-wavelength fluorescence, as shown in Patent Document 3, it is necessary to increase the oxygen content (n value in the composition formula). Similarly, in the case of Li-containing α-sialon, it is necessary to increase the oxygen content in order to obtain a short fluorescence wavelength.

  Conventionally, as a crucible used for firing Li-containing α-sialon, a Mo (molybdenum) container as shown in Patent Document 4 and a BN (boron nitride) sintered body as shown in Patent Document 2 are used. . Such a non-oxide crucible is used because sialon is an oxynitride. For example, if an oxide crucible is used, sialon is expected to be oxidized and cause sialon decomposition. However, the present inventors have found that when a non-oxide crucible is used for firing, oxidation is avoided, but a problem that the oxygen content decreases is caused. For this reason, there exists a possibility that it may become disadvantageous to obtain the short wavelength fluorescence which is the characteristic of Li containing alpha-sialon.

  As described above, from the standpoint of preventing oxidation and increasing the oxygen content, it is considered that in the case of Li-containing α-sialon, it is necessary to conduct a more detailed study on the crucible to be used.

JP 2002-363554 A WO2007 / 004493 A1 WO2007 / 004492 A1 JP 2004-67837 A

J. Phys. Chem. B 2004, 108, 12027-12031

  The present invention was made in order to solve the above-mentioned problems of sialon-based phosphors, and achieves both high fluorescence intensity and shorter wavelength of Li-containing α-sialon, combined with a blue LED, daylight white Another object of the present invention is to provide a fluorescent material that emits a fluorescent color capable of producing a white light emitting diode of daylight color.

  The present inventors have conducted detailed studies on an α-sialon phosphor containing Li and Eu (europium), and surprisingly, a non-oxide crucible is used as a container used for firing a powder mixture. Rather, it was found that the use of an alumina crucible makes it possible to shorten the wavelength of the fluorescent light and the fluorescent light.

  That is, the present invention is a process for producing a Li-containing α-sialon-based phosphor activated with Eu, characterized in that heat treatment is performed using an alumina crucible having a relative density of 80% or more. -It relates to a method for producing sialon phosphor powder.

  The Li-containing α-sialon-based phosphor of the present invention can achieve both high fluorescence intensity and shorter wavelength, which have not been obtained conventionally, by using a dense alumina crucible at the time of firing. An illumination device such as a white LED that emits a daylight color can be provided.

It is a figure which shows the fluorescence and excitation spectrum of fluorescent substance (Example 1, comparative example 1). It is a SEM photograph of fluorescent substance (Example 1, comparative example 1). It is a figure which shows the X-ray-diffraction chart of a crystal | crystallization (Example 1, comparative example 1). It is a figure which shows the fluorescence and excitation spectrum of fluorescent substance (Example 4, Comparative Examples 4-6). It is a figure which shows the X-ray-diffraction chart of a crystal | crystallization (Example 4, Comparative Examples 4-6).

  The present invention will be described in detail below.

The Li-containing α-sialon-based phosphor of the present invention has the general formula Li _x Eu _y Si _{12- (m + n)} Al _{(m + n) On + δ} N _16-n-δ (1)
Indicated by Here, when the average valence of Eu is a, x + ya + δ = m (where δ> 0).

Moreover, the general formula _{Li x Eu y Si 12- (m} + n) Al (m + n) O n N 16-n (2)
Indicated by Here, if the average valence of Eu is a, Li-containing α-sialon in which x + ya = m may be used.

  The present invention is characterized in that a dense alumina crucible is used when firing Li-containing α-sialon.

  In conventional Li-containing α-sialon firing, firing using a Mo crucible or a BN crucible is performed. Therefore, we also tried firing using a BN crucible. As a result, only long-wavelength Li-containing α-sialon could be obtained by this method. As a result of investigating the cause, when a BN crucible was used, oxygen decreased during the firing process, and as a result, the fluorescence wavelength was prolonged. At the same time, it turned out that the evaporation of Li progresses. As Li evaporation progressed, it was also noticed that Li-containing α-sialon had a problem that the fluorescence intensity did not increase. This is presumably because the BN crucible is made of nitride and is porous, so that the evaporation of oxygen and Li cannot be suppressed.

  In order to obtain Li-containing α-sialon having a high fluorescence intensity at a short wavelength, it is necessary to suppress oxygen reduction and Li evaporation during the firing process and increase oxygen and Li in the Li-containing α-sialon. When a dense alumina crucible is used, it is possible to suppress the evaporation of oxygen and the reduction of Li in the Li-containing α-sialon. The reason is considered that the material of the crucible is an oxide, so that a high oxygen partial pressure state can be maintained during firing, and the diffusion of Li outside the crucible by the dense crucible can be prevented. For this reason, it is possible to synthesize Li-containing α-sialon with little oxygen and Li deficiency, and it is possible to achieve both shorter wavelength and higher fluorescence intensity.

The alumina crucible is dense and has a relative density of 80% or more, preferably 90% or more, more preferably 95% or more. If it is less than 80%, the fluorescence intensity is remarkably lowered, which is not preferable. The composition of the alumina crucible is preferably 90% by mass or more of Al ₂ O ₃ if the sialon firing temperature is 1400 ° C. or higher. Furthermore, if it is 1600 degreeC or more, 95 mass% or more is preferable. When there are many impurities, melting | fusing point falls and there exists a possibility that it may become impossible to use as a crucible. There is no restriction | limiting in particular in the shape of a crucible, Shapes, such as a round shape and a square shape, can be employ | adopted arbitrarily.

  The mixture of starting materials can be placed in an alumina crucible and fired in an atmosphere containing nitrogen at normal pressure. The firing temperature is preferably 1400 ° C. to 1800 ° C., more preferably 1500 to 1700 ° C., and the desired Li-containing α-sialon phosphor powder is obtained.

  If the firing temperature is lower than 1400 ° C, it takes a long time to produce the desired Li-containing α-sialon phosphor powder, which is not practical, and the Li-containing α-sialon phosphor phase in the produced powder There is also a risk that the production rate will also decrease. When the firing temperature exceeds 1800 ° C., an undesirable situation may occur in which silicon nitride and sialon undergo sublimation decomposition and free silicon is generated.

  The Li-containing α-sialon phosphor thus obtained has a glass layer attached to the surface, and in order to obtain a phosphor with higher fluorescence intensity, it is preferable to remove the glass layer. For removal of the glass layer on the surface of the phosphor particles, cleaning with an acid is easiest.

  The fluorescence spectrum of the Li-containing α-sialon thus obtained is shown in FIG. 1 (a), and the excitation spectrum is shown in FIG. 1 (b). For comparison, FIG. 1 also shows the fluorescence spectrum and excitation spectrum of Li-containing α-sialon produced using a nitride crucible. It can be seen that higher fluorescence intensity is obtained when the dense alumina crucible is used than when the nitride crucible is used. Further, it can be seen that sialon produced using an alumina crucible becomes sialon having a shorter wavelength (peak wavelength of 575 nm or less).

  Next, an example of particle morphology is shown in FIG. It can be seen that the Li-containing α-sialon produced using an alumina crucible according to the production method of the present invention is a uniform granular particle having a particle size of about 2-3 μm and a small aspect ratio. As a comparison, FIG. 2 (b) shows the particle morphology of a product produced using a nitride crucible. In addition to the granular particles having a particle size of 2-3 μm, rod-like particles having a length of 5 μm or more are generated, and the shape of the particles is not uniform. The reason why the particle forms are different is considered to be due to the influence of the ratio of the different phases of the crystal phase described later.

  Next, the crystal phase will be described. X-ray diffraction (XRD) was conducted to investigate the crystal phase identification and crystal quality. The results are shown in FIG. Whether using an alumina crucible or a nitride crucible, it was confirmed that Li-containing α-sialon was produced. When a nitride crucible was used, AlN was confirmed as a slight heterogeneous phase. It is presumed that the generation of such heterogeneous phase is caused by deviation of Li from the stoichiometric composition of Li-containing α-sialon due to the evaporation of Li during firing. The quality of the crystal can be judged from the intensity of the peak. The higher the peak intensity, the more advanced the crystallization. In the case of a phosphor, a material with a high crystallinity gives a higher fluorescence intensity, so that a material with a higher peak intensity is superior. Regarding the peak intensity, it can be confirmed that the alumina crucible is higher than the nitride crucible and the crystallinity is high. The reason is that the generation of Li defects is prevented by suppressing the evaporation of Li described later.

  Table 3 shows the composition analysis of the resulting Li-containing α-sialon. It can be seen that the Li-containing α-sialon produced using an alumina crucible has a larger oxygen and Li content, and has a greater effect of suppressing the evaporation of oxygen and Li.

  As described above, when a Li-containing α-sialon is produced using a dense alumina crucible, the Li-containing α-sialon has high crystallinity and uniform particle shape by suppressing Li evaporation and preventing Li defects. Is obtained. Further, the evaporation of oxygen is suppressed, and a shorter wavelength Li-containing α-sialon having a high oxygen content is obtained.

  When a Li-containing α-sialon was baked using a porous alumina crucible, carbon crucible, or MgO crucible in addition to a dense alumina crucible, as shown in FIG. It is low, and it is impossible to achieve both short wavelength and high fluorescence intensity.

  From the above results, it was found that by using a dense alumina crucible, Li evaporation during firing was suppressed, a heterogeneous phase was generated, and a highly crystalline Li-containing α-sialon was obtained.

  By using the production method of the present invention, it has become possible for the first time to synthesize a Li-containing α-sialon-based phosphor that can achieve both a short wavelength and high fluorescence intensity.

  Next, a method for producing the sialon phosphor powder of the present invention will be further described.

  The Li-containing α-sialon-based phosphor powder of the present invention includes a silicon nitride powder, a substance serving as an aluminum source containing AlN, a Li nitride, an oxynitride, an oxide, or a precursor that becomes an oxide by thermal decomposition. The body material and the Eu nitride, oxynitride, oxide, or precursor material that becomes oxide by thermal decomposition are weighed and mixed, and the mixture is placed in an inert gas atmosphere at normal pressure containing nitrogen. It can obtain by baking at 1400-2000 degreeC. The obtained powder is washed with an acid solution to remove glass components and the like adhering to the surface, thereby finally obtaining a phosphor powder having substantially a Li-containing α-sialon phosphor as a main phase. be able to.

  As the raw material silicon nitride powder, crystalline silicon nitride, nitrogen-containing silane compound and / or amorphous silicon nitride powder may be used.

  The nitrogen-containing silane compound and / or amorphous silicon nitride powder as the main raw material may be obtained by a known method, for example, by vaporizing silicon halide such as silicon tetrachloride, silicon tetrabromide, silicon tetraiodide and ammonia in the gas phase. A Si—N—H system precursor compound such as silicon diimide produced by reacting in a liquid phase can be obtained by thermal decomposition at 600 to 1200 ° C. in a nitrogen or ammonia gas atmosphere. The crystalline silicon nitride powder can be obtained by firing the obtained nitrogen-containing silane compound and / or amorphous silicon nitride powder at 1300 ° C to 1550 ° C. Crystalline silicon nitride can also be obtained by nitriding metal silicon directly in a nitrogen atmosphere, but this method requires a pulverization step to obtain a fine powder, so impurities can easily enter. It is preferable to employ a method of decomposing a precursor that easily obtains a pure powder.

  Further, the nitrogen-containing silane compound and / or the amorphous silicon nitride powder and the crystalline silicon nitride powder are not limited, but those having an oxygen content of 1 to 5% by mass are preferably used. More preferably, the oxygen content is 1 to 3% by mass. When the oxygen content is less than 1% by mass, it is difficult to generate an α-sialon phase due to a reaction in the firing process, and there is a possibility that the crystal phase of the starting material remains or that an AlN polytype such as 21R is generated. On the other hand, if the oxygen content exceeds 5% by mass, the α-sialon production reaction is promoted, but the production rate of β-sialon and oxynitride glass may increase.

The nitrogen-containing silane compound and / or amorphous silicon nitride powder preferably has a specific surface area of 80 to 600 m ² / g. A thing of 340-500 m < ² > / g is still more preferable. For crystalline silicon ^nitride, it is preferable to use a material having a specific surface area of 1m ² / g~15m 2 / g.

Examples of the aluminum source include aluminum oxide, metal aluminum, and aluminum nitride. Each of these powders may be used alone or in combination. It is preferable to use a general aluminum nitride powder having an oxygen content of 0.1 to 8% by mass and a specific surface area of 1 to 100 m ² / g.

  Examples of precursor substances that are converted to oxides by thermal decomposition of Li and Eu include metal salts such as carbonates, oxalates, citrates, basic carbonates, and hydroxides.

  In the present invention, it is preferable that the amount of metal impurities other than the constituent components of the Li-containing α-sialon phosphor is 0.01% by mass or less. In particular, for a nitrogen-containing silane compound and / or amorphous silicon nitride powder and / or crystalline silicon nitride, and aluminum oxide and AlN with a large addition amount, the content of metal impurities is 0.01% by mass or less. Preferably, 0.005% by mass or less, more preferably 0.001% by mass or less is used. The metal impurity content in the case of the oxide of the metal Li oxide or the precursor material that becomes an oxide by thermal decomposition and the metal Eu oxide or the precursor material that becomes an oxide by thermal decomposition is 0. It is preferable to use one having a mass of 0.01% by mass or less.

  The method for mixing each of the starting materials is not particularly limited. For example, a method known per se, for example, a dry mixing method, a wet mixing in an inert solvent that does not substantially react with each component of the starting material, and then the solvent is added. A removal method or the like can be employed. As the mixing device, a V-type mixer, a rocking mixer, a ball mill, a vibration mill, a medium stirring mill, or the like is preferably used. However, since the nitrogen-containing silane compound and / or amorphous silicon nitride powder is extremely sensitive to moisture and moisture, it is necessary to mix the starting materials in a controlled inert gas atmosphere. .

  The mixture of starting materials is, for example, fired at 1400 to 1800 ° C., more preferably 1500 to 1700 ° C. in a nitrogen-containing inert gas atmosphere at normal pressure, and the target Li-containing α-sialon-based phosphor powder is obtained. can get. Further, not a normal pressure but a pressurized gas atmosphere may be used. Examples of the inert gas include helium, argon, neon, and krypton. In the present invention, these gases and a small amount of hydrogen gas can be mixed and used. When the firing temperature is lower than 1400 ° C., it takes a long time to produce the desired Li-containing α-sialon phosphor powder, which is not practical, and Li-containing α-sialon phosphor in the produced powder. There is also a possibility that the production rate of the body phase may be lowered. When the firing temperature exceeds 1800 ° C., silicon nitride and sialon may be sublimated and decomposed to generate free silicon.

  There are no particular restrictions on the heating furnace used for firing the powder mixture. For example, a batch-type electric furnace, rotary kiln, fluidized firing furnace, pusher-type electric furnace, or the like using a high-frequency induction heating system or a resistance heating system is used. be able to. An alumina crucible is used for the firing crucible. In a BN crucible, a silicon nitride crucible, a graphite crucible, or a silicon carbide crucible, a Li-containing α-sialon phosphor that achieves both high fluorescence intensity and a short wavelength cannot be obtained.

  The Li-containing α-sialon phosphor thus obtained has a glass layer attached to the surface, and in order to obtain a phosphor with higher fluorescence intensity, it is preferable to remove the glass layer. For removal of the glass layer on the surface of the phosphor particles, cleaning with an acid is easiest. In other words, the sialon particles are placed in an acid solution selected from sulfuric acid, hydrochloric acid or nitric acid to remove the glass layer on the surface. The concentration of the acid solution is preferably 0.1 N to 7 N, and more preferably 1 N to 3 N. If the concentration is excessively high, the oxidation proceeds remarkably and good fluorescence characteristics cannot be obtained. 5 mass% of sialon phosphor powder is added to the acid solution with the adjusted concentration, and the mixture is kept for a desired time while stirring. After washing, the solution containing the sialon phosphor powder can be filtered and washed with water to wash away the acid and dry.

  The Li-containing α-sialon phosphor activated by the rare earth element produced by the production method of the present invention is kneaded with a transparent resin such as an epoxy resin or an acrylic resin by a known method to produce a coating agent. A light emitting diode whose surface is coated with an agent can be used as a light emitting element in various lighting fixtures.

  In particular, a light emission source having a peak wavelength of excitation light in the range of 330 to 500 nm is suitable for a Li-containing α-sialon phosphor. In the ultraviolet region, the luminous efficiency of the Li-containing α-sialon-based phosphor is high, and a light-emitting element with good performance can be configured. Moreover, the luminous efficiency is high even with a blue light source, and a good daylight to daylight light-emitting element can be configured by combining the yellow fluorescence of the Li-containing α-sialon phosphor and the blue excitation light.

  Further, in combination with a red phosphor having a wavelength of 600 nm to 650 nm for color tone adjustment, the daylight white or daylight emission color can be controlled to a warm light bulb color region. Such a light-emitting element having a light bulb color can be widely used for general household lighting.

  It is also possible to make an image display element using Li-containing α-sialon phosphor. In this case, the light-emitting element described above can be used, but it is also possible to directly emit light by exciting the Li-containing α-sialon-based phosphor using an excitation source such as an electron beam, an electric field, or ultraviolet light. For example, it can be used on the principle of a fluorescent lamp. Such a light emitting element can also constitute an image display device.

Below, a specific example is given and this invention is demonstrated in more detail.
(Examples 1-4, Comparative Examples 1-3)
Amorphous silicon nitride powder, europium oxide powder, lithium carbonate powder, aluminum oxide powder, and aluminum nitride powder obtained by reacting silicon tetrachloride with ammonia were weighed with the compositions shown in Table 1. A nylon ball for stirring and a weighed powder were put in a container and mixed by a vibration mill for 1 hour in a nitrogen atmosphere. After mixing, the powder was taken out and filled into an alumina crucible. The packing density at this time was 0.18 g / cm ³ . The alumina crucible used has a relative density of 95% and an alumina purity of 98% by mass. Table 1 shows the relative density and purity of the alumina crucible used.

  Alumina crucible filled with raw material powder is set in a resistance heating furnace, and under normal pressure nitrogen gas flow atmosphere, room temperature to 1000 ° C for 1 hour, 1000 ° C to 1250 ° C for 2 hours, 1250 ° C to 1650 ° C Was heated at a temperature rising schedule of 200 ° C./h and held at 1650 ° C. for 12 hours to obtain phosphor powder. Since the obtained powder was a weakly sintered lump, it was lightly crushed using an alumina mortar until it became a powder without a large lump. Subsequently, it was immersed in a 2N-nitric acid solution for 5 hours and stirred for acid treatment. The obtained powder was dried at a temperature of 110 ° C. for 5 hours. Examples 2 to 4 were also fired in the same manner except for the relative density and purity of the alumina crucible. In Comparative Example 1, firing was performed using a boron nitride crucible. The boron nitride crucible used in the prior art has not been studied in detail on the relative density. In Comparative Examples 2 and 3, firing was performed using a porous alumina crucible.

  The fluorescence characteristics of the obtained powder were measured using a FP-6500 with an integrating sphere manufactured by JASCO Corporation. The fluorescence spectrum and excitation spectrum of Example 1 are shown in FIGS. The excitation wavelength of the fluorescence spectrum was 450 nm. The fluorescence wavelength of the excitation spectrum was 580 nm. The peak wavelength and peak intensity of the fluorescence spectrum were evaluated for all examples. The results are shown in Table 2. In Example 1, a high fluorescence intensity ratio of 100% or more is obtained. Further, Li-containing α-sialon having a peak wavelength of 575 nm is obtained. In other Examples 2 to 4, a high fluorescence intensity of 90% or more was obtained. On the other hand, in Comparative Example 1, the fluorescence intensity ratio is 27%, and the peak wavelength is increased to 582 nm.

  Next, the particle morphology will be described. The particle form of the Li-containing α-sialon phosphor obtained in Example 1 is shown in FIG. It turns out that it is a uniform granular particle with a small aspect ratio with a particle size of about 2-3 micrometers. As a comparison, FIG. 2 (b) shows the particle morphology of Li-containing α-sialon produced using a nitride crucible. In addition to the granular particles having a particle size of 2-3 μm, rod-like particles having a length of 5 μm or more are generated, and the shape of the particles is not uniform.

  Next, the crystal phase will be described. X-ray diffraction (XRD) was performed to investigate the crystal phase identification and crystal quality. The results are shown in FIG. Whether using an alumina crucible or a nitride crucible, it was confirmed that Li-containing α-sialon was produced. When a nitride crucible was used, AlN was confirmed as a slight heterogeneous phase. It is presumed that the generation of such heterogeneous phase is caused by deviation from the stoichiometric composition of Li-containing α-sialon due to the evaporation of Li during firing. The quality of the crystal can be judged from the intensity of the peak. Regarding the peak intensity, it can be confirmed that the alumina crucible is higher than the nitride crucible and the crystallinity is high. This is because, as can be seen from the results of quantitative analysis described later, the alumina crucible suppresses Li evaporation by firing and suppresses Li defects.

Subsequently, the Li-containing α-sialon obtained in Example 1 and Comparative Example 1 was quantitatively analyzed.
Oxygen and nitrogen analysis was performed with a LECO Co. oxygen / nitrogen simultaneous analyzer.

  Li, after subjecting the sample to acid decomposition with nitric acid and hydrofluoric acid, adding sulfuric acid, heating and concentrating until white smoke is generated, adding hydrochloric acid to this and heating to dissolve, SII Nanotechnology Inc. Quantitative analysis was performed by ICP-AES method using SPS5100 type. For Si, the sample was melted by heating with sodium carbonate and boric acid, then dissolved in hydrochloric acid, and quantitative analysis was performed according to the coagulation weight method. For Al and Eu, the filtrate obtained by the pretreatment for the quantitative analysis of Si was collected and subjected to quantitative analysis by ICP-AES.

Table 3 shows the results of the composition analysis.
It can be seen that the Li-containing α-sialon produced using an alumina crucible has a larger oxygen and Li content, and has a greater effect of suppressing the evaporation of oxygen and Li.

  As described above, when Li-containing α-sialon is produced using an alumina crucible, Li-containing α-sialon with high crystallinity and uniform particle shape is obtained by suppressing Li evaporation and preventing Li defects. It is done.

(Comparative Examples 4-6)
In addition to the dense alumina crucible, Li-containing α-sialon was fired using a porous alumina crucible, carbon crucible, and MgO crucible. Table 1 shows the material, relative density and purity of the crucible used.

  The fluorescence characteristics of the obtained powder were measured. The results are shown in Table 2. The fluorescence spectra and excitation spectra of Comparative Examples 4 to 6 are shown in FIGS. 4 (a) and 4 (b). The result of Example 4 is also shown for comparison. In the alumina crucible having a relative density of 75% shown in Comparative Example 4, the fluorescence intensity is low, and it is impossible to obtain both short wavelength and high fluorescence intensity. The carbon crucible of Comparative Example 5 and the MgO crucible of Comparative Example 6 also have low fluorescence intensity and cannot achieve both short wavelength and high fluorescence intensity.

Next, the crystal phase will be described. X-ray diffraction (XRD) was performed to investigate the crystal phase identification and crystal quality. The results are shown in FIG. In Comparative Example 4, crystallization to Li-containing α-sialon is in progress, and the O ′ sialon phase remains. In Comparative Example 5, the O ′ sialon phase and the LiAlO ₂ phase remain. A delay in crystal growth is undesirable because it leads to a decrease in the production efficiency of the phosphor. In Comparative Example 6, O ′ sialon and AlN are produced, which is not preferable for producing Li-containing α-sialon.

(Example 5)
The phosphor of Example 1 and the epoxy resin were mixed at a weight ratio of 20: 100 to prepare a phosphor paste. This was applied to a blue light emitting diode (wavelength 460 nm) attached to the electrode, heated at 120 ° C. for 1 hour, and further heated at 150 ° C. for 12 hours to cure the epoxy resin. The obtained light emitting diode was turned on, and it was confirmed that it was white of daylight color.

Claims (3)

Silicon nitride powder, aluminum source material containing AlN, Li nitride, oxynitride, oxide, or precursor material that becomes oxide by thermal decomposition, Eu nitride, oxynitride, oxidation Or a precursor material that becomes an oxide by thermal decomposition, and the mixture is mixed with an inert gas of normal pressure or pressure containing nitrogen using an alumina crucible having a relative density of 85% or more. A method for producing a Li-containing α-sialon-based phosphor powder characterized by producing a Li-containing α-sialon-based phosphor powder activated by europium by firing at 1400 to 2000 ° C. in an atmosphere.   The method for producing a Li-containing α-sialon phosphor powder according to claim 1, wherein the relative density of the alumina crucible is 90% or more.   The method for producing a Li-containing α-sialon phosphor powder according to claim 1 or 2, wherein the purity of the alumina crucible is 95% or more.