CN110295043A - The manufacturing method of fluoride red-emitting phosphors - Google Patents

Abstract

The issue of the present invention is to provide a kind of manufacturing methods of fluoride red-emitting phosphors that can be manufactured in the case where not using hydrogen fluoride.The manufacturing method of fluoride red-emitting phosphors is characterised by comprising following process: preparing the process of potassium fluoride as potassium resource and Fluorine source；Prepare polysilazane, TEOS, SiO as silicon source₂, at least one of potassium silicate process；Prepare K as manganese source₂MnF₆、Mn(HPO₄)₂、Mn(CH₃COO)₂·4H₂O、MnO(OH)₂、Na₂MnF₆Or KMnO₄At least one of process；Prepare the process of the solution of alkalescent, neutrality or acidity；The process that the potassium resource and Fluorine source, the silicon source, the manganese source and the solution are mixed；And the mixture is made to react and K is precipitated₂SiF₆Process, also, in the process for preparing the solution, using by removing HF and KHF₂Acidity, neutrality or the weakly alkaline solution of compound preparation in addition.

Description

The manufacturing method of fluoride red-emitting phosphors

Technical field

The present invention relates to the manufacturing methods of fluoride red-emitting phosphors, more specifically, are related to without using harmful fluorination With regard to producing with K in the case where hydrogen, fluorine gas₂SiF₆For the manufacturing method of the fluorophor of matrix.

Background technique

(KSF)

Potassium fluosilicate K₂SiF₆(taking the initial of composition formula, also referred to as " KSF ") is to help weldering in casting aluminium soldering Fluoride materials used in raw material of agent, optical lens and synthetic mica etc., useful.

(using KSF as the purposes of the fluorophor of matrix)

The manganese (Mn) of 4 valences is added in KSF as fluorophor (K obtained by light emitting ionic₂SiF₆: Mn⁴⁺), because being penetrated from LED Near ultraviolet~blue region light out and can be excited, and then issue red light from excitation state.According to such feature, Mn swashs KSF fluorophor living is used as the backlight light source (example of liquid crystal display, mobile phone and portable information terminal etc. in recent years Such as, referring to patent document 1).

(about using KSF as the existing manufacturing method of the fluorophor of matrix)

Then, to about K₂SiF₆: Mn⁴⁺Existing manufacturing method be illustrated.In existing manufacturing method, usually Use hydrogen fluoride (HF), fluorine gas as one of raw material (for example, referring to Patent Documents 1 to 5).Especially it is suitble to the existing of volume production Manufacturing method is that other raw materials are dissolved in hydrofluoric acid aqueous solution, generates the method (also referred to as solwution method) of KSF precipitating.

(the problem of existing solwution method)

However, as in a kind of above method of solwution method due to largely using the hydrogen fluoride being harmful to the human body, Careful attention is needed to handle, it is difficult to ensure the safety of producer.

(without using (fluoride-free hydrogen) substitution manufacturing method of hydrogen fluoride)

In order to solve the above problem, the substitution manufacturing method without using hydrogen fluoride is proposed in recent years.For example, non-special It discloses in sharp document 1 using potassium bifluoride KHF₂Manufacture K₂SiF₆: Mn⁴⁺Method.However, the KHF₂Not only there is toxicity, and And corrosivity is strong, therefore above-mentioned alternative is also difficult to be the preparation method that can really ensure producer et al. safety.

As described above, existing manufacturing method exists can not exclude hydrogen fluoride, fluorine gas, potassium bifluoride in its manufacturing process Etc. harmful substances, safety, producing rate variance or cost such as get higher at the projects, unsatisfactory.

Prior art document

Patent document

Patent document 1: Japanese Unexamined Patent Publication 2017-50525 bulletin

Patent document 2: Japanese Unexamined Patent Application Publication 2009-528429 bulletin

Patent document 3: Japanese Unexamined Patent Publication 2016-053178 bulletin

Patent document 4: Japanese Unexamined Patent Publication 2015-212374 bulletin

Patent document 5: Japanese Unexamined Patent Publication 2016-088949 bulletin

Non-patent literature

Non-patent literature 1:Lin Huang etc., " HF-Free Hydrothermal Route for Synthesis of Highly Efficient Narrow-Band Red Emitting Phosphor K₂Si_1-xF₆:xMn⁴⁺for Warm White Light-Emitting Diodes”Chemistry of Materials 28 1495-1502(2016)

Summary of the invention

Therefore, in view of the foregoing, the purpose of the present invention is to provide a kind of (no HF's) fluorine without using hydrogen fluoride HF The manufacturing method of compound red-emitting phosphors.

Another object of the present invention also resides in a kind of safety for enough ensuring producer of offer energy, improves productivity, inhibits life Produce the manufacturing method of the fluoride red-emitting phosphors of cost.

Another object of the present invention is to provide the manufacturer of KSF that is a kind of with high purity and being capable of commercial scale mass production Method.

The inventors of the present invention are to without using harmful hydrogen fluoride (HF), potassium bifluoride (KHF₂) in the case where be able to bear The synthetic method of the commercial scale of KSF has carried out exploration and detailed research, as a result, it has been found that by using silica (SiO₂), the silicate of polysilazane and/or alkali metal as silicon source, use alkali metal fluoride and/or ammonium fluoride as fluorine Source is then just able to carry out the mass production of KSF in the case where not using hydrogen fluoride, fluorine gas, potassium bifluoride, and this completes this hairs It is bright.

The present invention for example has composition and feature below.

(scheme 1)

A kind of manufacturing method of fluoride red-emitting phosphors, which is characterized in that comprise the following steps: as potassium resource and Fluorine source Prepare the process of potassium fluoride；Prepare polysilazane, TEOS, SiO as silicon source₂, at least one of potassium silicate process；As Manganese source prepares K₂MnF₆、Mn(HPO₄)₂、Mn(CH₃COO)₂·4H₂O、MnO(OH)₂、Na₂MnF₆Or KMnO₄At least one of Process；The process for preparing the solution of alkalescent, neutrality or acidity, by the potassium resource and Fluorine source, the silicon source, the manganese source and The process that the solution is mixed；And the mixture is made to react and K is precipitated₂SiF₆Process, also, described in the preparation In the process of solution, using by removing HF and KHF₂Acidity, neutrality or the weakly alkaline solution of compound preparation in addition.

(scheme 2)

The manufacturing method of fluoride red-emitting phosphors according to scheme 1, which is characterized in that preparing the solution In process, HCl, H are used₃PO₄、CH₃COOH or H₂O。

(scheme 3)

A kind of manufacturing method of fluoride red-emitting phosphors, which is characterized in that comprise the following steps: as potassium resource and Fluorine source Prepare the process of potassium fluoride；Prepare polysilazane, TEOS, SiO as silicon source₂, at least one of potassium silicate process；As Manganese source prepares K₂MnF₆、Mn(HPO₄)₂、Mn(CH₃COO)₂·4H₂O、MnO(OH)₂、Na₂MnF₆Or KMnO₄At least one of Process；Contact the potassium resource and Fluorine source, the silicon source and the manganese source and mixed process in gas；And make The mixture reacts and K is precipitated₂SiF₆Process.

(scheme 4)

A kind of manufacturing method of fluoride red-emitting phosphors, which is characterized in that comprise the following steps: as potassium resource and Fluorine source Prepare the process of potassium fluoride；Prepare polysilazane, TEOS, SiO as silicon source₂, at least one of potassium silicate process；As Manganese source prepares K₂MnF₆、Mn(HPO₄)₂、Mn(CH₃COO)₂·4H₂O、MnO(OH)₂、Na₂MnF₆Or KMnO₄At least one of Process；It contacts the potassium resource and Fluorine source, the silicon source and the manganese source in gas, a small amount of water or acid solution is added The process mixed afterwards；And the mixture is made to react and K is precipitated₂SiF₆Process.

(scheme 5)

A kind of manufacturing method of fluoride red-emitting phosphors, which is characterized in that comprise the following steps: as potassium resource and Fluorine source Prepare the process of potassium fluoride；Prepare polysilazane, TEOS, SiO₂, the process of at least one of potassium silicate as silicon source；As Manganese source prepares K₂MnF₆、Mn(HPO₄)₂、Mn(CH₃COO)₂·4H₂O、MnO(OH)₂、Na₂MnF₆Or KMnO₄At least one of Process；By the potassium resource and Fluorine source, the silicon source, the manganese source and water or acid solution receiving, it is closed in a reservoir, make it Contacted and mixed process in the container；And the mixture is made to react and K is precipitated₂SiF₆Process.

(scheme 6)

According to the manufacturing method of the described in any item fluoride red-emitting phosphors of scheme 1~5, which is characterized in that the work Prepare to be also prepared for ammonium fluoride in addition to the potassium fluoride in the process of potassium fluoride for potassium resource and Fluorine source.

(scheme 7)

The manufacturing method of the fluoride red-emitting phosphors according to any one of scheme 1~6, which is characterized in that selection SiO₂As the silicon source.

(scheme 8)

The manufacturing method of the fluoride red-emitting phosphors according to any one of scheme 1~6, which is characterized in that selection Amorphous SiO₂As the silicon source.

It can be substituted by the fluorophor of the invention that above preparation method synthesizes and be used in showing for three wave length type white light LEDs Some red-emitting phosphors, it can be expected that the improvement of the colour rendering of white light LEDs.

Especially the present invention can manufacture fluoride red fluorescence without using (the no HF's) of hydrogen fluoride HF etc. Body and its host crystal.Thereby, it is possible to ensure the safety of producer, productivity is improved, inhibits production cost.Moreover, can make It makes purity is high and is capable of the fluoride red-emitting phosphors of commercial scale mass production.

In addition, in the present invention, not only propose using acid solution (the small acid of the influence to human body etc.) solwution method or Person does not use the solwution method of acid completely, and demonstrates and can by other methods (solid phase method, hydro-thermal method or low-temperature solid-phase method) yet Enough synthesize fluoride red-emitting phosphors.These preparation methods proposed in the present invention can synthesize object at low temperature.

According to the present invention, such as solid product can be generated in a low temperature of 100 DEG C or less and by consolidating thereafter Liquid separates and manufactures KSF.The manufacturing method is easy and is not likely to produce problem for security, therefore, can volume production, it can be achieved that cost It reduces.In addition, by with K₂MnF₆、Mn(HPO₄)₂、Mn(CH₃COO)₂·4H₂O、MnO(OH)₂、Na₂MnF₆Or KMnO₄It is represented Manganese compound reaction, can be obtained doped with 4 valence Mn KSF fluorophor.Obtained KSF has high crystalline.It is produced from it The partial size of fluorophor, shape of particle are uniform, show excellent fluorescent characteristic.

Detailed description of the invention

Fig. 1 is the flow chart of the manufacturing method of the host crystal of the fluorophor of embodiment 1 and the examination that is obtained by this method The x-ray diffractogram of powder of sample is composed.

Fig. 2 is the flow chart of the manufacturing method of the host crystal of the fluorophor of embodiment 2 and as obtained from this method The x-ray diffractogram of powder of sample is composed.

Fig. 3 is the x-ray diffractogram of powder spectrum of the sample as obtained from the manufacturing method of embodiment 1,3~4.

Fig. 4 is the powder X-ray of the flow chart of the manufacturing method of the fluorophor of embodiment 6 and the sample as obtained from this method X ray diffraction map.

Fig. 5 is the excitation and emission spectra of the sample as obtained from the manufacturing method of embodiment 6.

Fig. 6 is the flow chart of the manufacturing method of the fluorophor of embodiment 7.

Fig. 7 is the x-ray diffractogram of powder spectrum of the sample as obtained from the manufacturing method of embodiment 7 and excites and send out Penetrate spectrum.

Fig. 8 is the flow chart for indicating the manufacturing method of fluorophor of embodiment 8.

Fig. 9 is the x-ray diffractogram of powder spectrum of the sample as obtained from the manufacturing method of embodiment 8 and excites and send out Penetrate spectrum.

Figure 10 is the flow chart for the manufacturing method of the host crystal of fluorophor for indicating embodiment 9 and is obtained by this method Sample x-ray diffractogram of powder spectrum.

Figure 11 is the flow chart for indicating the manufacturing method of fluorophor of embodiment 10.

Figure 12 be the sample as obtained from the manufacturing method of embodiment 10 x-ray diffractogram of powder spectrum and excitation and Emission spectrum.

Figure 13 is the flow chart for indicating each manufacturing method of fluorophor of embodiment 11.

Figure 14 be the sample as obtained from the manufacturing method of embodiment 11 x-ray diffractogram of powder spectrum and excitation and Emission spectrum.

The flow chart and the examination as obtained from this method that Figure 15 is each manufacturing method of fluorophor for indicating embodiment 12 The x-ray diffractogram of powder of sample is composed.

Figure 16 is the excitation and emission spectra of the sample as obtained from the manufacturing method of embodiment 12.

Specific embodiment

(fluorophor K of the invention₂SiF₆: Mn⁴⁺)

It is a kind of K to the end product for belonging to the manufacturing method of the present invention of Mn activation red-emitting phosphors₂SiF₆: Mn^{4 +}It is illustrated.K₂SiF₆: Mn⁴⁺By the blue light of 450nm excitation and sharp emission spectrum is shown near 630nm, therefore, It is the material for being expected to the red-emitting phosphors as three wave length type white light LEDs.

(Fluorine source and potassium resource of the invention)

It, can be " merely with potassium fluoride KF " as the Fluorine source and potassium resource of embodiment 1 (embodiment 2~6 is also identical).Such as this hair Bright (Examples 1 to 6) is such, if it is possible to only supply Fluorine source and potassium resource with single raw material (compound), then involved in production Process becomes very simple, is particular enable to inhibit production cost, labour etc..

On the other hand, it also can choose different compounds as Fluorine source and potassium resource of the invention.For example, aftermentioned implementation Example 7~12 like that, can be additional to use ammonium fluoride NH mainly using potassium fluoride KF as potassium resource₄F is as Fluorine source.As a result, at this It, can be to end product (K in the manufacture of invention₂SiF₆: Mn⁴⁺) or host crystal (K₂SiF₆) in be efficiently directed into fluorine, potassium member Element.In addition, if using potassium silicate (for example, K₂SiO₃、K₄SiO₄) be used as potassium resource and aftermentioned silicon source, then it can not use fluorine Change potassium KF and ammonium fluoride NH is used only as Fluorine source₄F。

(silicon source of the invention)

Furthermore it is possible to utilize SiO₂As silicon source of the invention.The particularly preferably SiO of selection noncrystalline shape (amorphous)₂。 SiO as a result,₂Hydroxyl on the surface of raw material easily causes the synthetic reaction of object of the invention.It, can be with as other silicon sources Utilize polysilazane (hereinafter also referred to as " PSZ "), Si (OC₂H₅)₄(hereinafter also referred to as " TEOS "), potassium silicate (for example, K₂SiO₃、K₄SiO₄).The inventors of the present invention have been acknowledged by the silicon source stated in use and replace SiO₂In the case where can also manufacture K₂SiF₆。

(manganese source of the invention)

As manganese source of the invention, such as it can use K₂MnF₆、Mn(HPO₄)₂、Mn(CH₃COO)₂·4H₂O、MnO (OH)₂、Na₂MnF₆Or KMnO₄At least one of.

As described above, existing KSF manufacturing method exist can not its manufacturing process exclude hydrogen fluoride (HF), fluorine gas, Potassium bifluoride (KHF₂) etc. harmful substances, safety, producing rate variance or cost the projects such as get higher, may not can be satisfactory.

Embodiment 1

(manufacture of the host crystal of KSF fluorophor)

Whether the inventors of the present invention have first verified that can only use the matrix of other Material synthesis fluorophor without using manganese source Crystal (K₂SiF₆) (embodiment 1).Fig. 1 (a) shows the flow chart of the manufacturing method of the host crystal of embodiment 1.

(1 solwution method of embodiment (LSR))

In terms of various dissolution of raw material are mixed in solution, the manufacturing method and existing method of embodiment 1 It is identical, therefore, belong to the scope of solwution method (LSR (Liquid State Reaction), also referred to as liquid phase method).It should be noted that According to the existing common sense of fluorophor industry, in order to activate the Mn of 4 valences in host crystal, needed for being preferably used to mix in advance The solution of each raw material is set as acidic region (especially highly acid).

However, the inventors of the present invention consider and toxic hydrogen fluoride HF high without using volatility used in the prior art, and It is using substituting its acid solution (for example, harmfulness and few acid solution of influence to human body).In turn, the inventors of the present invention Also contemplate violate above-mentioned common sense, using the water (neutral, weakly alkaline solution) of unused acid manufacture above-mentioned matrix crystalline substance Body.

(preparation or adjustment of the acidity of embodiment 1, neutrality or weakly alkaline solution)

The inventors of the present invention prepare the HCl (Northeast chemistry strain formula meeting that 2ml is further added in ion exchange water (8ml) Society's system, 36%) or CH₃Solution obtained by the acid of COOH (Kanto Kagaku K. K.'s system, 36%).That is, by ion exchange water with Acid is according to the acid solution (referring to Fig.1 (a)) for being adjusted to total amount 10ml in such a way that weight ratio meter becomes 4:1.In addition, being also prepared for 2ml ion exchange water (H is only further added instead of above-mentioned acid solution₂O neutral solution) (referring to following tables 1).Though here, It is so not shown, but the example as acid, H can be added₃PO₄、HNO₃Equal acid, although it is not shown, but having confirmed and obtaining and implement The same result of example 1.

(acid degree of solution)

Here, solution used in solwution method of the invention not only can be used by except HF and KHF₂Compound system in addition Standby acid solution, and the neutral solutions such as water or weakly alkaline solution can be used.In other words, solution of the invention can be used The liquid of PH≤11.Here, " removing HF and KHF₂Refer to the state for being entirely free of these harmful substances or being substantially free of in addition " (10 weight % or less).

(embodiment 1 for try raw material)

Firstly, weighing potassium fluoride KF (Kanto Kagaku K. K. according to stoichiometric ratio below as shown in Fig. 1 (a) System, 99.0%, aftermentioned embodiment it is also identical) and SiO₂(Kanto Kagaku K. K.'s system, noncrystalline, 99.9%, aftermentioned reality It is also identical to apply example).Prepare according to K⁺Ratio of components weighed the potassium fluoride of KF and according to F^?Ratio of components weighed the fluorination of KF Potassium (also referring to table 1).The table 1 shows the type and KF and SiO of acid solution₂Mixing ratio combination, add up to 6 kinds of moulds Each combination is named as sample 1~6 by formula.

In addition, in the present invention, preparing in advance and being adjusted to the solution of alkalescent, neutrality or acidity (is acid in Fig. 1 (a) Or neutral solution), it (is SiO in Fig. 1 (a) by potassium resource and Fluorine source (being KF in Fig. 1 (a)) and silicon source₂) addition of both raw materials In above-mentioned solution, but the sequence of prep solution, the sequence mixed with other raw materials etc., however it is not limited to above-mentioned example.For example, can The raw material (for example, KF) either in above-mentioned potassium resource and Fluorine source and above-mentioned silicon source is first dissolved in water, which is adjusted to After the solution of alkalescent, neutrality or acidity, by the other raw materials not dissolved in above-mentioned water (for example, SiO₂) make an addition to State solution (for example, acid solution).

In addition, the mixed processes about each raw material and solution, also identical in the manufacture of aftermentioned fluorophor.I.e., it is possible to Prepare to pre-adjust the solution for alkalescent, neutrality or acidity, above-mentioned potassium resource and Fluorine source, above-mentioned silicon source and above-mentioned manganese source are added It is added on above-mentioned solution, it can also be by the dissolution of raw material either in above-mentioned potassium resource and Fluorine source, above-mentioned silicon source and above-mentioned manganese source Yu Shui, after above-mentioned water to be adjusted to the solution of alkalescent, neutrality or acidity, the remaining raw material that will not dissolved in above-mentioned water Make an addition to above-mentioned solution.

[table 1]

Acid	KF∶SiO2=2: 1	KF∶SiO2=6: 1
			Water	Sample 1	Sample 2
HCl	Sample 3	Sample 4
			CH3COOH	Sample 5	Sample 6

(synthesis condition of embodiment 1)

Above-mentioned each raw material is put into above-mentioned solution, using magnetic stirring apparatus at room temperature by above-mentioned mixture stirring 2 Hour, it is filtered.Then, 5 hours dry at 80 DEG C, thus obtain synthetic (powder).

(XRD spectrum of the KSF host crystal of embodiment 1)

Fig. 1 (b) shows the sample (K obtained by the above-mentioned sample 1~6 of embodiment 1₂SiF₆) powder x-ray diffraction (XRD) map.If by the target product (target compound) of the X ray diffracting spectrum of each sample of embodiment 1 and simulation Crystal map (lowermost of (b) referring to Fig.1) be compared, then observe that each peak is consistent with each other.Therefore, pass through embodiment The powder that 1 each condition obtains is accredited as belonging to the K of object₂SiF₆Phase (lowermost of (b) referring to Fig.1).

But in Fig. 1 (b), observe the condition (sample 3~6) synthesized using acid solution then with use it is not sour The condition (sample 1 and 2) of neutral solution (that is, only ion exchange water) synthesis compares the peak for more specific KSF occur.That is, sample 3 In, it may be said that KSF is obtained with single-phase.In addition, not observing KF and SiO₂Mixing ratio variation caused by the synthesis of KSF It influences.In addition, although whole signal noise occur, also observed the peak of KSF in the XRD of sample 1 and 2.Think sample 1 In 2, SiO₂Input amount the synthesis for being partially used for KSF to a certain degree, but unreacted and remaining SiO₂Also more.Thus It is found that being then possible to promote the synthetic reaction of KSF to acidity is assigned in solution in embodiment 1.

Embodiment 2

(influence of drying condition)

Then, the inventors of the present invention have attempted the drying condition of change embodiment 1 to manufacture the host crystal (embodiment of KSF 2).Specifically, being heated 5 hours at 80 DEG C, but in the drying process of embodiment 2, in the drying process of embodiment 1 only in room Temperature keeps synthetic 3 days dry.Other manufacturing conditions are identical as the sample 2 of embodiment 1.Fig. 2 (a) shows the KSF matrix of embodiment 2 The flow chart of the manufacturing method of crystal.

(XRD spectrum of the KSF host crystal of embodiment 2)

Fig. 2 (b) shows the sample (K obtained by embodiment 2₂SiF₆) powder x-ray diffraction (XRD) map.Pass through reality The sample that example 2 obtains is applied also to be accredited as belonging to the K of object₂SiF₆Phase (referring to the lower section of Fig. 2 (b)).It follows that even if Object can also be obtained by not assigning heat in drying process, it is therefore contemplated that the imparting of heat only helps to the shortening of drying time.

(research of the manufacturing method other than solwution method)

Embodiment 1,2, the manufacturing method of the prior art have been all made of above-mentioned solwution method (LSR), but the inventors of the present invention are also Can have studied be made by the way that the method (aftermentioned solid phase method, hydro-thermal method and low-temperature solid-phase method, also referring to Fig. 3) of solution is not used Make fluorophor of the invention (aftermentioned embodiment 3~5).

Embodiment 3

(3 solid phase method of embodiment (SSR))

In embodiment 3, fluorophor of the invention has been manufactured by solid phase method (SSR (Solid State Reaction)) Host crystal.Specifically, the various raw material powders prepared by method similarly to Example 1 are contacted in gas (mixed Close), it reacts above-mentioned mixture 6 hours at 200 DEG C and has obtained powder.

Embodiment 4

(4 hydro-thermal method of embodiment (HTR))

In embodiment 4, fluorophor of the invention has been manufactured by hydro-thermal method (HTR (Hydrothermal Reaction)) Host crystal.Specifically, the various raw material powders prepared by method similarly to Example 1 are mixed, it will be above-mentioned Mixture is contained in closed container together with the water of 0.1ml (10wt% of object).Make the above-mentioned mixing in the closed container Object reacts 6 hours at 200 DEG C and has obtained powder.

In addition, will be mixed obtained in above-mentioned mixed processes in the autofrettage (HTR) of embodiment 4 and aftermentioned embodiment It closes object and is contained in closed or semi-hermetic container.Then, the temperature in the container is preferably maintained 50 DEG C~250 DEG C one on one side While carrying out low-temperature heat to said mixture.

Embodiment 5

(5 low-temperature solid-phase method of embodiment (WASSR))

In embodiment 5, pass through low-temperature solid-phase method (WASSR (Water Assisted Solid State Reaction)) Fluorophor of the invention is manufactured.Specifically, the various raw material powders prepared by method similarly to Example 1 are carried out Contact, is added the water or acid solution (for example, vinegar) of a small amount of 0.1ml (10wt% of object), makes above-mentioned mixture in room Temperature mixes (solid phase reaction) 5 minutes and obtains powder.

Wherein, the above-mentioned autofrettage of embodiment 5 and aftermentioned embodiment (that is, description and claims of this specification) (WASSR) range of " a small amount of water " that adds in is discussed further below.That is, being characterized in that, total weight of raw material powder is set It is 1 or less (more preferably 0.001~0.1) by the weight set of the water of addition when being 1.Further, since being used in embodiment 5 Raw material powder total weight be 1g, therefore, when total weight of raw material powder is set as 1, the above-mentioned imparting amount of water is 0.1。

It should be noted that becoming following state: with general solid phase reaction when the amount of water is more than the lower limit of above-mentioned preferred scope Similarly, form stable intermediate product in the mutual contact surface of raw material powder particle, as a result, raw material powder it is interparticle from Sub- expansion rate is slack-off, and reaction is not easy to carry out.On the other hand, when the amount of water is more than the upper limit of above-mentioned preferred scope, become as follows State: raw material powder suspends in a solvent, and the mutual contact area of raw material powder particle is reduced, and therefore, is not susceptible to react.

(comparison of the XRD spectrum of the KSF host crystal of embodiment 1,3~4)

After the sample (synthetic) of the embodiment 1,3~5 synthesized by above-mentioned method is crushed with aluminium oxide mortar, benefit The identification of sample is carried out with powder x-ray diffraction device.Fig. 3 shows the sample (K obtained by embodiment 1,3~4₂SiF₆) Powder x-ray diffraction (XRD) map.Which kind of, no matter the sample manufactured by method, it is accredited as belonging to the K of object₂SiF₆ Phase (referring to the lowermost of Fig. 3).It should be noted that although it is not shown, but embodiment 5 obtained by low-temperature solid-phase method (WASSR) Sample also obtained same XRD spectrum.

Embodiment 6

(manufacture of embodiment 6KSF fluorophor)

Then, the host crystal manufactured into Examples 1 to 5 adds the K as manganese source₂MnF₆And mix (embodiment 6). Fig. 4 (a) shows the manufacturing method of the fluorophor of embodiment 6.Make manganese source relative to host crystal 99.7% about mixing ratio 0.3%.Then, it is small to be heated 6 in closed container by the water for adding 1ml (100wt% of object) at 200 DEG C for mixture When.

(XRD spectrum of the KSF fluorophor of embodiment 6)

Fig. 4 (b) shows the sample (K obtained by the preparation method of embodiment 6₂SiF₆) powder x-ray diffraction (XRD) map. The said sample of embodiment 6 is accredited as belonging to the K of object₂SiF₆Phase (referring to the lower section of Fig. 4 (b)).It should be noted that Fig. 4 (b) sample (fluorophor) identified in is used in the host crystal obtained under conditions of the sample 6 of embodiment 1 as raw material And manufacture.

(fluorescent characteristic of the KSF fluorophor of embodiment 6)

Fig. 5 is the figure for indicating the fluorescent characteristic (excitation spectrum and emission spectrum) of the sample of embodiment 6.The horizontal axis of Fig. 4 The curve of short wavelength side indicates the excitation spectrum of the sample of embodiment 6, and on the other hand, the curve of long wavelength side indicates to swash with above-mentioned The emission spectrum for the sample that clockwork spring part is corresponding and shines.According to the figure significantly, it is thus identified that the sample of embodiment 6 absorbs about The blue light of 450nm, being shown in about 630nm nearby has the emitting red light of maximum peak (from Mn⁴⁺Shine).

It should be noted that, using the host crystal for manufacturing fluorophor first, then adding manganese source in embodiment 6 and synthesizing glimmering The step of as body of light the step of two stages, but not limited to this, can also use a stage.I.e., it is possible to by manganese Source is added together with other raw materials, synthesizes fluorophor of the invention from the beginning.

(ammonium fluoride NH is further added in Fluorine source and potassium resource₄The variation of F)

In the above embodiments 1~6, merely with potassium fluoride KF as Fluorine source and potassium resource, but embodiment 7~12 as be described hereinafter Like that, another compound can also be used (for example, ammonium fluoride NH " together with potassium fluoride KF "₄F).Promote object as a result, The synthesis of (host crystal of fluorophor and fluorophor).It should be noted that property raw material joined fluorine in aftermentioned embodiment 7~12 Change ammonium NH₄F simultaneously changes various conditions, so that can have studied make fluorophor of the invention, host crystal.

Embodiment 7

(potassium resource and Fluorine source of embodiment 7)

Fig. 6 is the flow chart of the manufacturing method of the fluoride red-emitting phosphors of embodiment 7.Firstly, preparing to count according to chemistry Measure the potassium fluoride KF (Kanto Kagaku K. K.'s system, 99.0%, aftermentioned embodiment is also identical) and ammonium fluoride NH than weighing₄F (Kanto Kagaku K. K.'s system, 97.0%, aftermentioned embodiment is also identical), is added in ion exchange water 8ml and keeps its molten Solution.

(being adjusted to acid or neutral solution of embodiment 7)

Then, HCl (Kanto Kagaku K. K.'s system, 36%), H are further added₃PO₄(Kanto Kagaku K. K.'s system, 85%), HNO₃(Kanto Kagaku K. K.'s system, 60%), CH₃Any one of COOH (Kanto Kagaku K. K.'s system, 36%) Or H₂O (control) (additive amount 2ml).That is, ion exchange water is adjusted to acid according in such a way that weight ratio meter becomes 4:1 The acid solution of total amount 10ml.

(manganese source of embodiment 7)

Then, the Mn as manganese source is added in a manner of becoming using the Mn in manganese source with the Si equimolar amounts in aftermentioned silicon source (HPO₄)₂。

(silicon source of embodiment 7)

Then, it is weighed according to stoichiometric ratio and adds the polysilazane as silicon source (hereinafter also referred to as " PSZ ".SHIN-ETSU HANTOTAI Chemical industry Co. Ltd. system, 5%, aftermentioned embodiment it is also identical).

Then, above-mentioned mixture is stirred 2 hours in room temperature using magnetic stirring apparatus, is filtered.Then, at 80 DEG C It is 5 hours dry, thus obtain presenting white to fair-skinned powder.

(passing through the evaluation method for the KSF fluorophor that the preparation method of embodiment 7 manufactures)

After the sample of the embodiment 7 synthesized by above-mentioned method is crushed with aluminium oxide mortar, spread out using X-ray powder The identification of injection device progress sample.In turn, using the fluorescent characteristic of the fluorophor of sepectrophotofluorometer evaluation embodiment 7.

(XRD spectrum of the KSF fluorophor of embodiment 7)

Fig. 7 (a) shows the sample (K as obtained from each condition of embodiment 7₂SiF₆: Mn⁴⁺) powder x-ray diffraction (XRD) map.The uppermost of Fig. 7 (a) and the 2nd~5 section are shown respectively that (No acid is (that is, only using not sour neutral solution Ion exchange water), acid solution (CH₃COOH、HNO₃、H₃PO₄, HCl) production sample XRD spectrum.It is obtained under the conditions of each Powder is accredited as belonging to the K of object₂SiF₆Phase (referring to the lowermost of Fig. 7 (a)).

(fluorescent characteristic of the KSF fluorophor of embodiment 7)

Fig. 7 (b) is the figure for indicating the fluorescent characteristic (excitation spectrum and emission spectrum) of each sample of embodiment 7.Fig. 7 (b) Horizontal axis short wavelength side curve indicate embodiment 7 each sample excitation spectrum, on the other hand, the curve table of long wavelength side Show corresponding with above-mentioned shooting condition and luminous sample emission spectrum.According to the figure, it is thus identified that each sample of embodiment 7 is aobvious The blue light for absorbing about 450nm is write, being shown in about 630nm nearby has the emitting red light of maximum peak (from Mn⁴⁺Shine).

Embodiment 8

(the case where using different silica sources under conditions of no acid)

According to the experimental result of embodiment 7, the influence caused by the acid degree of the solution because of used in preparation method is not observed, Therefore, in embodiment 8, (without acid) under conditions of without using the acid solution illustrated in embodiment 7, added silicon is had studied The difference of the type in source.

(silicon source of embodiment 8)

Fig. 8 is the flow chart of the manufacturing method of the fluoride red-emitting phosphors of embodiment 8.Raw material is mixed in addition In solution, all acid illustrated in embodiment 7 are not used, ion exchange water is used only.That is, the solution of embodiment 8 is adjusted to It is neutral.In addition to silicon source, embodiment 8 for examination raw material and manufacturing process it is identical as the manufacturing condition of embodiment 7.As embodiment 8 silicon source also uses Si (OC other than using PSZ used in embodiment 7₂H₅)₄(hereinafter also referred to as " TEOS ") (and Wako Pure Chemical Industries Co. Ltd. system, 95.0%, aftermentioned embodiment is also identical), SiO₂(Kanto Kagaku K. K.'s system, amorphous Matter, 99.9%, aftermentioned embodiment is also identical), K₂SiO₃Solution (Wako Pure Chemical Industries, Ltd.'s system, 50%, aftermentioned reality It is also identical to apply example).

(XRD spectrum of the KSF fluorophor of embodiment 8)

Fig. 9 (a) shows the sample (K obtained under each condition (adding each silicon source) of embodiment 8₂SiF₆: Mn⁴⁺) powder X-ray X ray diffraction (XRD) map.Uppermost~4 section of Fig. 9 (a) respectively indicate addition K₂SiO₃Solution, SiO₂, TEOS, PSZ and give birth to At sample XRD spectrum.The powder obtained under the conditions of each is accredited as belonging to the K of object₂SiF₆Phase is (referring to Fig. 9 (a) Lowermost).According to these as a result, the type of added silicon source is to K₂SiF₆Synthesis have little effect.

In addition, Fig. 9 (b) is the figure for indicating the fluorescent characteristic (excitation spectrum and emission spectrum) of each sample of embodiment 8.Really Each sample of accepting is displayed in red by blue light excitation luminous (from Mn⁴⁺Shine).It should be noted that in Fig. 9 (b), Although not significant occur using K₂SiO₃When fluorescent characteristic, but confirmed in visual, other tests apparent shine.

Embodiment 9

(manufacture of the host crystal of KSF fluorophor)

In embodiment 8, K has been synthesized while adding each raw material in the solution for not assigning acid₂SiF₆: Mn⁴⁺, but it is final Because imparting the Mn (HPO as manganese source₄)₂, acid is completely removed accordingly, it is difficult to say.Therefore, in embodiment 9, can demonstrate Host crystal (the K of fluorophor is manufactured using only other raw materials without using manganese source₂SiF₆)。

Figure 10 (a) shows the flow chart of the manufacturing method of the host crystal of the fluorophor of embodiment 9.The preparation method of embodiment 9 In, it is essentially identical with the preparation method of embodiment 8 other than there is no the process of the addition manganese source in embodiment 8.It should be noted that real It applies in example 9, also uses K similarly to Example 8₂SiO₃Solution, SiO₂, TEOS, PSZ be as silicon source.

(XRD spectrum of the KSF fluorophor of embodiment 9)

Figure 10 (b) shows the sample (K as obtained from each condition (adding each silicon source) of embodiment 9₂SiF₆) powder X-ray X ray diffraction (XRD) map.It has confirmed as a result, and has used TEOS, PSZ, K₂SiO₃When as silicon source, it can synthesize and belong to fluorescence The K of the host crystal of body₂SiF₆.Although it should be noted that the addition SiO in figure₂And letter is generated in the XRD spectrum of the sample generated Number noise, but the result (experimental data again not shown) tested again, it is thus identified that even if in the case where adding these silicon sources Also K can be synthesized₂SiF₆。

Embodiment 10

(manufacture for the KSF fluorophor that raw material is complexed)

Figure 11 is the flow chart for indicating the manufacturing method of fluorophor of embodiment 10.In the preparation method of embodiment 10, also prepare The potassium fluoride KF and ammonium fluoride NH weighed according to stoichiometric ratio₄F is simultaneously mixed.

In addition, selecting SiO in the present embodiment₂As silicon source, KMnO is selected₄As manganese source.Then, in KMnO₄Middle addition Formic acid (CH₂O₂K it) and mixes, filter, further add SiO in the filtrate₂With phosphoric acid solution (H₃PO₄) after mixed It closes, thus with PO₄ ^3-It is complexed with Mn and the Si mode being coordinated respectively, prepares (production) final Si (HPO in advance₄)₂With Mn (HPO₄)₂The solution mixed with the molar ratio of 10:1.The phosphoric acid complex solution is made an addition into KF and NH₄The mixed solution of F.

In turn, further addition, which is set as condition 1~5 shown in Figure 11, (makes imparting amount be respectively 0,5,10,20,40 (wt%)) water.Then, implement heating process shown in Figure 11, synthesize KSF fluorophor.

(XRD spectrum of the KSF fluorophor of embodiment 10)

Figure 12 (a) shows the powder X-ray of the sample as obtained from each condition (difference of the imparting amount of water) of embodiment 10 X ray diffraction (XRD) map.K has been confirmed in all samples generated under condition 1~5₂SiF₆Phase.

(fluorescent characteristic of the KSF fluorophor of embodiment 10)

In addition, Figure 12 (b) shows fluorescent characteristic (excitation spectrum and the transmitting light of the sample manufactured by embodiment 10 Spectrum).It is luminous (from Mn to confirmed that each sample is displayed in red by blue light excitation⁴⁺Shine).As a result, it can according to this To say that the amount of the water of addition does not influence luminous intensity.The difference of luminous intensity under the conditions of thinking each depends on Mn and Si in phosphoric acid Mn in complex solution⁴⁺Concentration and Si⁴⁺Concentration difference.

Embodiment 11

(manufacture of the KSF fluorophor based on solid phase method (SSR) or hydro-thermal method (HTR))

The preparation method of embodiment 7~10 is demonstrated even if without using necessary HF in existing preparation method, and it is glimmering can also to synthesize KSF Body of light or its host crystal.However embodiment 7~10 is solwution method (LTR), it is identical as existing method in this aspect.Therefore, Whether the inventors of the present invention also studied can synthesize KSF fluorophor (referring to Fig.1 3) by solid phase method or hydro-thermal method.Figure 13 is Indicate the flow chart of the manufacture of the KSF fluorophor based on solid phase method (SSR) or hydro-thermal method (HTR).

As the 1st of solid phase method (SSR), as shown in the process in the left side of Figure 13, by K₂SiF₆With MnO (OH)₂Raw material It is mixed and heated (for heating condition referring to content in figure, example below is also identical), is thus synthesized.In addition, as solid phase method (SSR) the 2nd, as shown in the process in the center of Figure 13, by KF, NH₄F、SiO₂And MnO (OH)₂It is mixed and heated, thus Synthesis.

In addition, the 1st as hydro-thermal method (HTR), as shown in the process on the right side of Figure 13, prepare KF, NH₄F、SiO₂With And Mn (HPO₄)₂(identical as each raw material used in the 2nd of solid phase method), is added in the presence of the hot water of high temperature and pressure Heat.

(XRD spectrum of the KSF fluorophor of embodiment 11)

The powder of sample obtained from Figure 14 (a) shows each condition (solid phase method or hydro-thermal method) as shown in embodiment 11 X-ray diffraction (XRD) map.It is confirmed according to the figure in all samples obtained by solid phase method with single-phase K₂SiF₆Phase.In addition, confirming K in the sample obtained by hydro-thermal method with main phase₂SiF₆Phase.According to this as a result, It was found that even the synthetic method different from the solwution method proposed all the time, can also synthesize KSF fluorophor.

(fluorescent characteristic of the KSF fluorophor of embodiment 11)

In addition, Figure 14 (b) shows the fluorescent characteristic (excitation spectrum and emission spectrum) of each sample of embodiment 11.It confirmed All samples are displayed in red by blue light excitation luminous (from Mn⁴⁺Shine).Especially synthesized by hydro-thermal method Sample in observe highest luminous intensity.It should be noted that in the 1st of the solid phase method (SSR) of embodiment 11, although in figure Do not occur fluorescent characteristic significantly, but has confirmed apparent shine in visual, other tests.

Embodiment 12

(use K₂MnF₆KSF fluorophor manufacture)

Then, it has studied using K₂MnF₆KSF fluorophor (embodiment 12) is synthesized as manganese source.It should be noted that K₂MnF₆ It is middle to there is the K with cubic structure₂MnF₆With the K with structure of hexagonal crystal₂MnF₆, can be used.But it is sent out from promotion Photoion (Mn⁴⁺) ion exchange from the viewpoint of, the host crystal (K of the fluorophor due to belonging to object₂SiF₆) base Matter crystal is cubic structure, it is therefore contemplated that it is preferable to use the K with cubic structure₂MnF₆.In embodiment below, as Manganese source uses the K with structure of hexagonal crystal₂MnF₆.In addition, using Na₂MnF₆Instead of K₂MnF₆。

As the 1st, by K₂SiF₆(it is, for example, possible to use the host crystals manufactured in Examples 1 to 5,9) and K₂MnF₆ Mixing, is further added a small amount of water (10wt% of object), is heated (heating condition referring to Fig.1 5 (a), aftermentioned example Heating condition it is also identical) and make it dry, thus synthesize sample (low-temperature solid-phase method (WASSR)).

As the 2nd, by KF, NH₄F、K₂MnF₆And the SiO as silicon source₂It is mixed, is further added on a small quantity Water (10wt% of object), is heated and is made it dry, and thus synthesizes sample (low-temperature solid-phase method (WASSR)).

As the 3rd, by KF, NH₄F and K₂MnF₆The PSZ (solid phase method) as silicon source is further added in mixing.To logical It crosses the mixture that the solid phase method obtains to be heated and made it dry, thus synthesizes sample.

4th uses TEOS as silicon source, in addition to this, essentially identical with the 3rd (solid phase method).

As the 5th, do not add the 3rd and the 4th in the feed used in KF and be used only NH₄F and K₂MnF₆And by it Mix.Then, K is further added₂SiO₃Solution is as silicon source (solid phase method).To the mixture obtained by the solid phase method into Row is heated and is made it dry, and thus synthesizes sample.

(XRD spectrum of the KSF fluorophor of embodiment 12)

Sample obtained from Figure 15 (b) shows each condition (low-temperature solid-phase method or hydro-thermal method) as shown in embodiment 12 Powder x-ray diffraction (XRD) map.According to the figure, in the sample that obtains under all conditions, K is confirmed with main phase₂SiF₆.It answers Give explanation, it is believed that impurity first is that KHF₂。

(fluorescent characteristic of the KSF fluorophor of embodiment 12)

In addition, Figure 16 (a) and (b) show the fluorescent characteristic (excitation of some samples in sample obtained in embodiment 12 Spectrum and emission spectrum).Specifically, Figure 16 (a) indicates the fluorescent characteristic of the 1st synthetic of embodiment 12, Figure 16 (b) Indicate the fluorescent characteristic of the 2nd synthetic of embodiment 12.In all cases, it confirms aobvious by blue light excitation Show emitting red light (from Mn⁴⁺Shine).It should be noted that from now on by by Mn concentration optimization, it can be expected that can further increase Luminous intensity.

In addition, the variation as the above embodiments 12, although it is not shown, but using Na₂MnF₆Instead of K₂MnF₆Make In the case where for manganese source (other conditions are identical), same XRD spectrum and fluorescent characteristic have been obtained.

Industrial availability

Fluorophor of the invention can substitute the existing red-emitting phosphors for being used in three wave length type white light LEDs, it can be expected that The improvement of the colour rendering of white light LEDs.

Fluorine can be manufactured without using (the no HF's) of the noxious materials such as hydrogen fluoride HF especially in the present invention Compound red-emitting phosphors and its host crystal.Thereby, it is possible to ensure the safety of producer, productivity is improved, inhibits production cost. Moreover, purity is high can be manufactured and be capable of the fluoride red-emitting phosphors of plant-scale mass production.

In addition, in the present invention, not only proposes and use acid (the few acid of the influence to human body etc.), neutral, weakly alkaline Solution or completely without using acid solwution method, and demonstrate by solid phase method or hydro-thermal method can also synthesize fluoride red Fluorophor.These preparation methods proposed in the present invention can synthesize object at low temperature.

The host crystal of the KSF manufactured in the present invention is not necessarily required to utilize in the form of the fluorophor for activating Mn, also can Enough it is used in other purposes such as raw material of optics lens, synthetic mica.

Therefore, the utility value in industry of the invention and utilizability are very high.

Claims (8)

1. a kind of manufacturing method of fluoride red-emitting phosphors, which is characterized in that comprise the following steps:

Prepare the process of potassium fluoride as potassium resource and Fluorine source；

Prepare polysilazane, TEOS, SiO as silicon source₂, at least one of potassium silicate process；

Prepare K as manganese source₂MnF₆、Mn(HPO₄)₂、Mn(CH₃COO)₂·4H₂O、MnO(OH)₂、Na₂MnF₆Or KMnO₄In extremely A kind of few process；

Prepare the process of the solution of alkalescent, neutrality or acidity；

The process that the potassium resource and Fluorine source, the silicon source, the manganese source and the solution are mixed；And

The mixture is set to react and K is precipitated₂SiF₆Process,

Also, in the process for preparing the solution, using by removing HF and KHF₂In addition compound preparation acidity, neutrality or Weakly alkaline solution.

2. the manufacturing method of fluoride red-emitting phosphors according to claim 1, which is characterized in that preparing the solution Process in, use HCl, H₃PO₄、CH₃COOH or H₂O。

3. a kind of manufacturing method of fluoride red-emitting phosphors, which is characterized in that comprise the following steps:

Prepare the process of potassium fluoride as potassium resource and Fluorine source；

Prepare polysilazane, TEOS, SiO as silicon source₂, at least one of potassium silicate process；

Prepare K as manganese source₂MnF₆、Mn(HPO₄)₂、Mn(CH₃COO)₂·4H₂O、MnO(OH)₂、Na₂MnF₆Or KMnO₄In extremely A kind of few process；

Contact the potassium resource and Fluorine source, the silicon source and the manganese source and mixed process in gas；And

The mixture is set to react and K is precipitated₂SiF₆Process.

4. a kind of manufacturing method of fluoride red-emitting phosphors, which is characterized in that comprise the following steps:

Prepare the process of potassium fluoride as potassium resource and Fluorine source；

Prepare polysilazane, TEOS, SiO as silicon source₂, at least one of potassium silicate process；

Prepare K as manganese source₂MnF₆、Mn(HPO₄)₂、Mn(CH₃COO)₂·4H₂O、MnO(OH)₂、Na₂MnF₆Or KMnO₄In extremely A kind of few process；

It contacts the potassium resource and Fluorine source, the silicon source and the manganese source in gas, a small amount of water or acid solution is added The process mixed afterwards；And

The mixture is set to react and K is precipitated₂SiF₆Process.

5. a kind of manufacturing method of fluoride red-emitting phosphors, which is characterized in that comprise the following steps:

Prepare the process of potassium fluoride as potassium resource and Fluorine source；

Prepare polysilazane, TEOS, SiO₂, the process of at least one of potassium silicate as silicon source；

Prepare K as manganese source₂MnF₆、Mn(HPO₄)₂、Mn(CH₃COO)₂·4H₂O、MnO(OH)₂、Na₂MnF₆Or KMnO₄In extremely A kind of few process；

By the potassium resource and Fluorine source, the silicon source, the manganese source and water or acid solution receiving, it is closed in a reservoir, make it Contacted and mixed process in the container；And

The mixture is set to react and K is precipitated₂SiF₆Process.

6. the manufacturing method of fluoride red-emitting phosphors according to any one of claims 1 to 5, which is characterized in that institute It states and prepares to be also prepared for ammonium fluoride in addition to the potassium fluoride in the process of potassium fluoride as potassium resource and Fluorine source.

7. the manufacturing method of fluoride red-emitting phosphors described according to claim 1~any one of 6, which is characterized in that choosing Select SiO₂As the silicon source.

8. the manufacturing method of fluoride red-emitting phosphors described according to claim 1~any one of 6, which is characterized in that choosing Select amorphous SiO₂As the silicon source.