Abstract:
Green luminescent materials and their preparing methods. The luminescent materials are the compounds of the following general formula: M 3 Y 1-x Tb x Si 3 O 9  or M 5 Y 1-x Tb x Si 4 O 12 , wherein 0&lt;x≦1 and M is one of Na, K and Li, or wherein Y is replaced by one of Gd, Sc, Lu and La in part or in whole. The luminescent materials are prepared by Sol-Gel method, microwave synthesis or high temperature solid phase method using one of oxide, chloride, nitrite, carbonate or oxalate of Y 3+ , one of oxide, chloride, nitrate, carbonate and oxalate of Tb 3+  and SiO 2  as raw materials. The materials of the present invention have high stability, high color purity and high luminous efficiency and the preparing methods are easy to conduct, which have high product quality and low cost, and may be widely used in luminescent materials production.

Description:
FIELD OF THE INVENTION 
       [0001]    The present invention relates to a luminescent material and its preparing method, more particularly, to a green luminescent material and its preparing method. 
       BACKGROUND OF THE INVENTION 
       [0002]    In the 1960s, Ken Shoulder put forward a hypothesis of cathode ray micro device on the basis of the field emission cathode assay (FEAs). Accordingly, the researches on the design and manufacture of panel display and light source device utilizing FEAs have aroused people&#39;s great interest. The operating principle of the new-type field emission device of this type is similar to that of the traditional cathode-ray tube (CRT), which achieves imaging or lighting applications through the bombardment of the cathode ray on red, green and blue three-colored fluorescent powder. There are potential advantages in the aspects of luminosity, visual angle, response time, operating temperature range and energy consumption for the device of this type. 
         [0003]    One key factor to manufacture the field emission device with excellent performance is the preparation of high-performance fluorescent powder. At present, the fluorescent materials applied in the field emission device are mainly the sulfides, oxides and sulfur oxides fluorescent powders for traditional cathode-ray tube and projection television kinescope. For sulfides and sulfur oxides fluorescent powders, they have higher brightness and certain conductivity. However, they are easy to decompose when bombarded by a large beam of cathode ray, thus releasing elementary sulfur to “poison” the cathode needle point and generating any other precipitate to cover the surface of the fluorescent powder, which would reduce the luminous efficiency of the fluorescent powder and the service life of the field emission device. The oxides fluorescent powder has high stability, but their luminous efficiency is not high enough and they are generally insulators. Accordingly performances of both sulfides and sulfur oxides fluorescent powder and oxides fluorescent powder are required to be improved and enhanced. 
       SUMMARY OF THE INVENTION 
       [0004]    The objective of the present invention is to provide a green luminescent material which has high stability and high luminous efficiency and can emit a green light when excited by the cathode ray, aiming at the problems in the prior art that the sulfides and sulfur oxides fluorescent powders are easy to decompose when bombarded by a large beam of cathode ray, thus releasing elementary sulfur to “poison” the cathode needle point and generating any other precipitate to cover the surface of the fluorescent powder, which would reduce the luminous efficiency of the fluorescent powder and the service life of the field emission device, and the problems in the prior art that the oxides fluorescent powder has luminous efficiency not high enough and no conductivity. 
         [0005]    Another objective of the present invention is to provide a preparing method for green luminescent material which is easy to conduct, has high product quality and low cost and can be widely used in luminescent material production. 
         [0006]    According to an aspect, first green luminescent materials are compounds of a following general formula: M 3 Y 1-x Tb x Si 3 O 9  or M 5 Y 1-x Tb x Si 4 O 12 , wherein a range of x is 0&lt;x≦1 and M is one selected from a group of Na, K and Li; wherein the range of x is preferably 0.1≦x≦0.6. 
         [0007]    Second green luminescent materials are compounds of a following general formula: M 3 Y 1-x Tb x Si 3 O 9  or M 5 Y 1-x Tb x Si 4 O 12 , wherein a range of x is 0&lt;x≦1, M is one selected from a group of Na, K and Li, and Y is replaced by one of Gd, Sc, Lu and La in part or in whole; wherein the range of x is preferably 0.1≦x≦0.6. 
         [0008]    According to another aspect, a preparing method for the first green luminescent materials is provided, which comprising following steps: 
         [0009]    (1) taking silicate of M + , one of oxide, chloride, nitrate, carbonate or oxalate of Y 3+ , one of oxide, chloride, nitrate, carbonate and oxalate of Tb 3+  and SiO 2  as raw materials, weighing the raw materials in accordance with a molar ratio of each element in the chemical formula of M 3 Y 1-x Tb x Si 3 O 9  or M 5 Y 1-x Tb x Si 4 O 12 , wherein the range of x is 0&lt;x≦1 and M is one selected from a group of Na, K and Li; 
         [0010]    (2) dissolving the raw materials in a hydrochloric acid or a nitric acid to form a solution when taking the oxide, carbonate or oxalate of Y 3+  and the oxide, carbonate or oxalate of Tb 3+  as the raw materials in step (1); directly dissolving the raw materials in water to form a solution when taking the chloride or nitrite of Y 3+  and the chloride or nitrite of Tb 3+  as the raw materials; 
         [0011]    (3) dissolving the silicate of M +  in water, adding the SiO 2  with stirring, then adding the solution in step (2) slowly with stirring, keeping stirring for 0.5˜1.5 h to obtain a sol, heating the sol at 100˜150° C. for 4˜24 h and then obtaining a xerogel; 
         [0012]    (4) grinding the xerogel into powder, calcining the powder at a constant temperature for 4˜20 h after the temperature has been risen to 900˜1200° C. at a heating rate of 60˜1000° C./h and then obtaining the green luminescent materials; 
         [0013]    or else, grinding the xerogel into powder, processing the powder for 5-30 min under microwave with a frequency of 2450 MHz and a power of 500˜1000 W and then obtaining the green luminescent materials; 
         [0014]    wherein the step (4) preferably comprises: grinding the xerogel into powder, calcining the powder at a constant temperature for 6˜15 h after the temperature has been risen to 1000˜1150° C. at a heating rate of 300˜800° C./h and then obtaining the green luminescent materials. 
         [0015]    According to another aspect, a preparing method for the second green luminescent materials is provided, which comprising following steps: 
         [0016]    (1) taking silicate of M + , one of oxide, chloride, nitrate, carbonate or oxalate of Y 3+ , one of oxides, chloride, nitrate, carbonate and oxalate of Tb 3+  and SiO 2  as raw materials, weighing the raw materials in accordance with a molar ratio of each element in the chemical formula of M 3 Y 1-x Tb x Si 3 O 9  or M 5 Y 1-x Tb x Si 4 O 12 , wherein the range of x is 0&lt;x≦1 and M is one selected from a group of Na, K and Li; 
         [0017]    (2) dissolving the raw materials in a hydrochloric acid or a nitric acid to form a solution when taking the oxide, carbonate or oxalate of Y 3+  and the oxide, carbonate or oxalate of Tb 3+  as the raw materials in step (1); directly dissolving the raw materials in water to form a solution when taking the chloride or nitrite of Y 3+  and the chloride or nitrite of Tb 3+  as the raw materials; 
         [0018]    (3) dissolving the silicate of M +  in water, adding the SiO 2  with stirring, then adding the solution in step (2) slowly with stirring, keeping stirring for 0.5˜1.5 h to obtain a sol, heating the sol at 100˜150° C. for 4˜24 h and then obtaining a xerogel; 
         [0019]    (4) grinding the xerogel into powder, calcining the powder at a constant temperature for 4˜20 h after the temperature has been risen to 900˜1200° C. at a heating rate of 60˜1000° C./h and then obtaining the green luminescent materials; 
         [0020]    or else, grinding the xerogel into powder, processing the powder for 5-30 min under microwave with a frequency of 2450 MHz and a power of 500˜1000 W and then obtaining the green luminescent materials; 
         [0021]    Y 3+  in the step (1) and (2) is replaced by one of Gd 3+ , Sc 3+ , Lu 3+  and La 3+  in part or in whole; 
         [0022]    wherein the step (4) preferably comprises: grinding the xerogel into powder, calcining the powder at a constant temperature for 6˜15 h after the temperature has been risen to 1000˜1150° C. at a heating rate of 300˜800° C./h and then obtaining the green luminescent materials. 
         [0023]    According to another aspect, another preparing method for the first green luminescent materials is provided, which comprising following steps: 
         [0024]    (1) taking one of silicate and oxalate of M + , one of oxides, chloride, nitrate, carbonate or oxalate of Y 3+ , one of oxides, chloride, nitrate, carbonate and oxalate of Tb 3+  and SiO 2  as raw materials, weighing the raw materials in accordance with a molar ratio of each element in the chemical formula of M 3 Y 1-x Tb x Si 3 O 9  or M 5 Y 1-x Tb x Si 4 O 12 , wherein the range of x is 0&lt;x≦1 and M is one selected from a group of Na, K and Li; 
         [0025]    (2) grinding the raw materials into powder, sintering the powder at 1000˜1200° C. for 4˜20 h, cooling the powder to room temperature and then obtaining the green luminescent materials. 
         [0026]    According to another aspect, another preparing method for the second green luminescent materials, the method comprising the following steps: 
         [0027]    (1) taking one of silicate and oxalate of M + , one of oxide, chloride, nitrate, carbonate or oxalate of Y 3+ , one of oxide, chloride, nitrate, carbonate and oxalate of Tb 3+  and SiO 2  as raw materials, weighing the raw materials in accordance with a molar ratio of each element in the chemical formula of M 3 Y 1-x Tb x Si 3 O 9  or M 5 Y 1-x Tb x Si 4 O 12 , wherein the range of x is 0&lt;x≦1, M is one selected from a group of Na, K and Li and Y 3+  is replaced by one of Gd 3+ , Sc 3+ , Lu 3+  and La 3+  in part or in whole; 
         [0028]    (2) grinding the raw materials into powder, sintering the powder at 1000˜1200° C. for 4˜20 h, cooling the powder to room temperature and then obtaining the green luminescent materials. 
         [0029]    The luminescent material of the present invention is the silicate green luminescent material doped with Tb 3+  and Y 3+ . Such material has features of high stability, high color purity and high luminous efficiency, and can emit a green light when excited by the cathode ray. 
         [0030]    The green luminescent material prepared by the replacement of Tb 3+  and Y 3+  by one of Gd 3+ , Sc 3+ , Lu 3+  and La 3+  in part or in whole also has features of high stability, high color purity and high luminous efficiency, and can emit a green light when excited by the cathode ray. 
         [0031]    For the preparing method of the present invention, the process is relatively easy with few processing steps and process conditions easily to realize. None impurity is introduced in the present method to achieve a high product quality. The cost is low as a result of the non-rough process condition, thus the method can be widely applied in luminescent material production. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0032]    The present invention will be further described with reference to the accompanying drawings and embodiments in the following. In the Figures: 
           [0033]      FIG. 1  is the comparison diagram for the cathodoluminescence spectra of existing commercial green fluorescent powder (ZnS: Cu, Au, Al) and the sodium silicate luminescent material doped with rare earth ions prepared in the example 27; 
           [0034]      FIG. 2  is the comparison diagram for the cathodoluminescence spectra&#39;s of existing commercial green fluorescent powder (ZnS: Cu, Au, Al) and the sodium silicate luminescent material doped with rare earth ions prepared in the example 34; 
           [0035]    wherein the Shimadzu RF-5301 spectrometer is used for the luminescent spectrum determination. The test condition is as follows: the excitation voltage of the cathode ray is 7.5 kV. 
       
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     Example 1 
     Na 3 Y 0.9 Tb 0.1 Si 3 O 9  Prepared by Sol-Gel Method 
       [0036]    At room temperature, 0.9 mmol Y(NO 3 ) 3  and 0.1 mmol Tb(NO 3 ) 3  are dissolved in 2 ml deionized water in a vessel as a standby rare earth solution. 1.5 mmol SiO 2  are added into 1.22 g Na 2 SiO 3  solution with a mass percent concentration of 15% with stirring. After that, the prepared rare earth solution is slowly added while keeping stirring, so that the molar ratio of the alkali metal Na ion, the sum of the Y ion and Tb ion of rare earth ions and the silicon in the mixed solution is 3:1:3. A sol is obtained through continuous stirring for 1 h. Then the obtained sol is dried at 120° C. for 12 h to volatilize the solvent and obtain a xerogel. Subsequently, the xerogel is ground into powder and placed in a corundum crucible. Afterwards, the powder is placed into a high temperature furnace, in which the temperature is risen to 1100° C. at a heating rate of 100° C./h. The powder is calcined for 6 h at 1100° C. therein, and the luminescent material Na 3 Y 0.9 Tb 0.1 Si 3 O 9  that can emit a green light when excited by the cathode ray is obtained after the following cooling and grinding. 
       Example 2 
     Na 3 Y 0.5 Gd 0.2 Tb 0.3 Si 3 O 9  Prepared by Sol-Gel Method 
       [0037]    At room temperature, 0.5 mmol Y(NO 3 ) 3 , 0.2 mmol Gd(NO 3 ) 3  and 0.3 mmol Tb(NO 3 ) 3  are dissolved in 2 ml deionized water in a vessel as a standby rare earth solution. The remaining steps are the same as those in example 1. Then the luminescent material Na 3 Y 0.5 Gd 0.2 Tb 0.3 Si 3 O 9  which can emit a green light when excited by the cathode ray is obtained. 
       Example 3 
     Na 3 Y 0.4 Tb 0.6 Si 3 O 9  Prepared by Sol-Gel Method 
       [0038]    At room temperature, 0.4 mmol YCl 3  and 0.6 mmol TbCl 3  are dissolved in 2 ml deionized water in a vessel as standby. The remaining steps are the same as those in example 1. Then the luminescent material Na 3 Y 0.4 Tb 0.6 Si 3 O 9  which can emit a green light when excited by the cathode ray is obtained. 
       Example 4 
     Na 3 TbSi 3 O 9  Prepared by Sol-Gel Method 
       [0039]    At room temperature, 1 mmol Tb(NO 3 ) 3  is dissolved in 2 ml deionized water in a vessel as standby. The remaining steps are the same as those in example 1. Then the luminescent material Na 3 TbSi 3 O 9  which can emit a green light when excited by the cathode ray is obtained. 
       Example 5 
     K 3 Sc 0.74 Tb 0.26 Si 3 O 9  Prepared by Sol-Gel Method 
       [0040]    At room temperature, 0.74 mmol Sc(NO 3 ) 3  and 0.26 mmol Tb(NO 3 ) 3  are dissolved in 2 ml deionized water in a vessel as a standby rare earth solution. 1.5 mmol SiO 2  are added into 1.55 g K 2 SiO 3  solution with a mass percent concentration of 15% with stirring. After that, the prepared rare earth solution is slowly added while keeping stirring, so that the molar ratio of the alkali metal K ion, the sum of the Sc ion and Tb ion of rare earth ions and the silicon in the mixed solution is 3:1:3. A sol is obtained through continuous stirring for 0.5 h. Then the obtained sol is dried at 100° C. for 24 h to volatilize the solvent and obtain a xerogel. Subsequently, the xerogel is ground into powder and placed in a corundum crucible. Afterwards, the powder is placed into a high temperature furnace, in which the temperature is risen to 1200° C. at a heating rate of 800° C./h. The powder is calcined for 4 h at 1200° C. therein, and the luminescent material K 3 Sc 0.74 Tb 0.26 Si 3 O 9  that can emit a green light when excited by the cathode ray is obtained after the following cooling and grinding. 
       Example 6 
     Li 3 Y 0.74 Tb 0.26 Si 3 O 9  Prepared by Sol-Gel Method 
       [0041]    At room temperature, 0.37 mmol Y 2 (C 2 O 4 ) 3  and 0.13 mmol Tb 2 (C 2 O 4 ) 3  are dissolved in 0.21 ml analytically pure concentrated nitric acid in a vessel as a standby rare earth solution. 1.22 g Na 2 SiO 3  solution with a mass percent concentration of 15% is replaced with 0.9 g Li 2 SiO 3  solution with a mass percent concentration of 15%. The remaining steps are the same as those in example 1. Then the luminescent material Li 3 Y 0.74 Tb 0.26 Si 3 O 9  which can emit a green light when excited by the cathode ray is obtained. 
       Example 7 
     Na 5 Y 08 Lu 0.1 Tb 0.1 Si 4 O 12  Prepared by Sol-Gel Method 
       [0042]    At room temperature, 0.4 mmol Y 2 O 3 , 0.05 mmol Lu 2 O 3  and 0.025 mmol Tb 4 O 7  are dissolved in 0.3 ml analytically pure concentrated hydrochloric acid in a vessel as a standby rare earth solution. 1.5 mmol SiO 2  are added into 2.04 g Na 2 SiO 3  solution with a mass percent concentration of 15% with stirring. After that, the prepared rare earth solution is slowly added while keeping stirring, so that the molar ratio of the alkali metal Na ion, the sum of the Y ion, Lu ion and Tb ion of rare earth ions and the silicon in the mixed solution is 5:1:4. A sol is obtained through continuous stirring for 1.5 h. Then the obtained sol is dried at 150° C. for 4 h to volatilize the solvent and obtain a xerogel. Subsequently, the xerogel is ground into powder and placed in a corundum crucible. Afterwards, the powder is placed into a high temperature furnace, in which the temperature is risen to 900° C. at a heating rate of 60° C./h. The powder is calcined for 20 h at 900° C. therein, and the luminescent material Na 5 Y 0.8 Lu 0.1 Tb 0.1 Si 4 O 12  that can emit a green light when excited by the cathode ray is obtained after the following cooling and grinding. 
       Example 8 
     Na 5 TbSi 4 O 12  Prepared by Sol-Gel Method 
       [0043]    At room temperature, 1 mmol Tb(NO 3 ) 3  is dissolved in 2 ml deionized water in a vessel as a standby rare earth solution. 1.5 mmol SiO 2  are added into 2.04 g Na 2 SiO 3  solution with a mass percent concentration of 15% with stirring. After that, the prepared rare earth solution is slowly added while keeping stirring, so that the molar ratio of the alkali metal Na ion, the rare earth Tb ion and the silicon in the mixed solution is 5:1:4. A sol is obtained through continuous stirring for 1.5 h. Then the obtained sol is dried at 100° C. for 16 h to volatilize the solvent and obtain a xerogel. Subsequently, the xerogel is ground into powder and placed in a corundum crucible. Afterwards, the powder is placed into a high temperature furnace, in which the temperature is risen to 1150° C. at a heating rate of 300° C./h. The powder is calcined for 6 h at 1150° C. therein, and the luminescent material Na 5 TbSi 4 O 12  that can emit a green light when excited by the cathode ray is obtained. 
       Example 9 
     K 5 Y 0.1 La 0.8 Tb 0.1 Si 4 O 12  Prepared by Sol-Gel Method 
       [0044]    At room temperature, 0.1 mmol YCl 3 , 0.8 mmol LaCl 3  and 0.1 mmol TbCl 3  are dissolved in 2 ml deionized water in a vessel as a standby rare earth solution. 1.5 mmol SiO 2  are added into 2.57 g K 2 SiO 3  solution with a mass percent concentration of 15% with stirring. After that, the prepared rare earth solution is slowly added while keeping stirring, so that the molar ratio of the alkali metal K ion, the sum of Y ion, La ion and Tb ion of rare earth ions and the silicon in the mixed solution is 5:1:4. A sol is obtained through continuous stirring for 1.5 h. Then the obtained sol is dried at 140° C. for 6 h to volatilize the solvent and obtain a xerogel. Subsequently, the xerogel is ground into powder and placed in a corundum crucible. Afterwards, the powder is placed into a high temperature furnace, in which the temperature is risen to 1150° C. at a heating rate of 1000° C./h. The powder is calcined for 8 h at 1150° C. therein, and the luminescent material K 5 Y 0.1 La 0.8 Tb 0.1 Si 4 O 12  that can emit a green light when excited by the cathode ray is obtained after a following cooling and grinding. 
       Example 10 
     Li 5 Y 0.99 Tb 0.01 Si 4 O 12  Prepared by Sol-Gel Method 
       [0045]    At room temperature, 0.495 mmol Y 2 (CO 3 ) 3  and 0.005 mmol Tb 2 (CO 3 ) 3  are dissolved in 0.3 ml analytically pure concentrated hydrochloric acid in a vessel as a standby rare earth solution. 2.04 g Na 2 SiO 3  solution with a mass percent concentration of 15% is replaced with 1.5 g Li 2 SiO 3  solution with a mass percent concentration of 15%. The remaining steps are the same as those in example 7. Then the luminescent material Li 5 Y 0.99 Tb 0.01 Si 4 O 12  which can emit a green light when excited by the cathode ray is obtained. 
       Example 11 
     Na 3 Y 0.9 Tb 0.1 Si 3 O 9  Prepared by Microwave Synthesis Method 
       [0046]    At room temperature, 0.9 mmol Y(NO 3 ) 3  and 0.1 mmol Tb(NO 3 ) 3  are dissolved in 2 ml deionized water in a vessel as a standby rare earth solution. 1.5 mmol SiO 2  are added into 1.22 g Na 2 SiO 3  solution with a mass percent concentration of 15% with stirring. After that, the prepared rare earth solution is slowly added while keeping stirring, so that the molar ratio of the alkali metal Na ion, the sum of the Y ion and Tb ion of rare earth ions and the silicon in the mixed solution is 3:1:3. A sol is obtained through continuous stirring for 1 h. Then the obtained sol is dried at 120° C. for 12 h to volatilize the solvent and obtain a xerogel. Subsequently, the xerogel is ground into powder and placed in a corundum crucible. Afterwards, the corundum crucible is placed in another larger crucible filled with Fe 2 O 3  which is covered with a cap thereafter. Such device is placed into a microwave oven (the frequency and maximum output power of which are respectively 2450 MHz and 1000 W) and processed for 10 min with a power of 700 W therein. Then the luminescent material Na 3 Y 0.9 Tb 0.1 Si 3 O 9  that can emit a green light when excited by the cathode ray is obtained after the following cooling and grinding. 
       Example 12 
     Na 3 Y 0.2 La 0.3 Tb 0.5 Si 3 O 9  Prepared by Microwave Synthesis Method 
       [0047]    At room temperature, 0.2 mmol YCl 3 , 0.3 mmol LaCl 3  and 0.5 mmol TbCl 3  are dissolved in 2 ml deionized water in a vessel as a standby rare earth solution. The remaining steps are the same as those in example 11. Then the luminescent material Na 3 Y 0.2 La 0.3 Tb 0.5 Si 3 O 9  that can emit a green light when excited by the cathode ray is obtained. 
       Example 13 
     Na 3 Y 0.4 Tb 0.6 Si 3 O 9  Prepared by Microwave Synthesis Method 
       [0048]    At room temperature, 0.2 mmol Y 2 (C 2 O 4 ) 3  and 0.3 mmol Tb 2 (C 2 O 4 ) 3  are dissolved in 0.21 ml analytically pure nitric acid in a vessel as standby rare earth solution. The remaining steps are the same as those in example 11. Then the luminescent material Na 3 Y 0.4 Tb 0.6 Si 3 O 9  that can emit a green light when excited by the cathode ray is obtained. 
       Example 14 
     Na 3 TbSi 3 O 9  Prepared by Microwave Synthesis Method 
       [0049]    At room temperature, 1 mmol Tb(NO 3 ) 3  are dissolved in 2 ml deionized water in a vessel as a standby rare earth solution. 1.5 mmol SiO 2  are added into 1.22 g Na 2 SiO 3  solution with a mass percent concentration of 15% with stirring. After that, the prepared rare earth solution is slowly added while keeping stirring, so that the molar ratio of the alkali metal Na ion, the rare earth Tb ion and the silicon in the mixed solution is 3:1:3. A sol is obtained through continuous stirring for 1 h. Then the obtained sol is dried at 120° C. for 12 h to volatilize the solvent and obtain a xerogel. Subsequently, the xerogel is ground into powder and placed in a corundum crucible. Afterwards, the corundum crucible is placed in another larger crucible filled with Fe 2 O 3  which is covered with a cap thereafter. Such device is placed into a microwave oven (the frequency of which is 2450 MHz) and processed for 30 min with a power of 500 W therein. Then the luminescent material Na 3 TbSi 3 O 9  that can emit a green light when excited by the cathode ray is obtained after the following cooling and grinding. 
       Example 15 
     K 3 Y 0.74 Tb 0.26 Si 3 O 9  Prepared by Microwave Synthesis Method 
       [0050]    At room temperature, 0.37 mmol Y 2 (CO 3 ) 3  and 0.13 mmol Tb 2 (CO 3 ) 3  are dissolved in 0.3 ml analytically pure hydrochloric acid in a vessel as a standby rare earth solution. 1.22 g Na 2 SiO 3  solution with a mass percent concentration of 15% is replaced with 1.55 g K 2 SiO 3  with a mass percent concentration of 15%. The remaining steps are the same as those in example 11. Then the luminescent material K 3 Y 0.74 Tb 0.26 Si 3 O 9  that can emit a green light when excited by the cathode ray is obtained. 
       Example 16 
     Li 3 Y 0.9 Sc 0.05 Tb 0.05 Si 3 O 9  Prepared by Microwave Synthesis Method 
       [0051]    At room temperature, 0.9 mmol Y(NO 3 ) 3 , 0.05 mmol Sc(NO 3 ) 3  and 0.05 mmol Tb(NO 3 ) 3  are dissolved in 2 ml deionized water in a vessel as standby. 1.22 g Na 2 SiO 3  solution with a mass percent concentration of 15% is replaced with 0.9 g Li 2 SiO 3  with a mass percent concentration of 15%. The remaining steps are the same as those in example 11. Then the luminescent material Li 3 Y 0.9 Sc 0.05 Tb 0.05 Si 3 O 9  that can emit a green light when excited by the cathode ray is obtained. 
       Example 17 
     Na 5 Gd 0.9 Tb 0.1 Si 4 O 12  Prepared by Microwave Synthesis Method 
       [0052]    At room temperature, 0.9 mmol Gd(NO 3 ) 3  and 0.1 mmol Tb(NO 3 ) 3  are dissolved in 2 ml deionized water in a vessel as a standby rare earth solution. 1.5 mmol SiO 2  are added into 2.04 g Na 2 SiO 3  solution with a mass percent concentration of 15% with stirring. After that, the prepared rare earth solution is slowly added while keeping stirring, so that the molar ratio of the alkali metal Na ion, the Gd ion and Tb ion of rare earth ions and the silicon in the mixed solution is 5:1:4. A sol is obtained through continuous stirring for 1 h. Then the obtained sol is dried at 110° C. for 14 h to volatilize the solvent and obtain a xerogel. Subsequently, the xerogel is ground into powder and placed in a corundum crucible. Afterwards, the corundum crucible is placed in another larger crucible filled with Fe 2 O 3  which is covered with a cap thereafter. Such device is placed into a microwave oven (the frequency and maximum output power of which are respectively 2450 MHz and 1000 W) and processed for 5 min with a power of 1000 W therein. Then the luminescent material Na 5 Gd 0.9 Tb 0.1 Si 4 O 12  that can emit a green light when excited by the cathode ray is obtained after the following cooling and grinding. 
       Example 18 
     Na 5 Y 0.74 Tb 0.26 Si 4 O 12  Prepared by Microwave Synthesis Method 
       [0053]    At room temperature, 0.74 mmol YCl 3  and 0.26 mmol TbCl 3  are dissolved in 2 ml deionized water in a vessel as a standby rare earth solution. The remaining steps are the same as those in example 17. Then the luminescent material Na 5 Y 0.74 Tb 0.26 Si 4 O 12  that can emit a green light when excited by the cathode ray is obtained. 
       Example 19 
     Na 5 Y 0.5 Tb 0.5 Si 4 O 12  Prepared by Microwave Synthesis Method 
       [0054]    At room temperature, 0.25 mmol Y 2 (C 2 O 4 ) 3  and 0.25 mmol Tb 2 (C 2 O 4 ) 3  are dissolved in 0.21 ml analytically pure nitric acid in a vessel as a standby rare earth solution. The remaining steps are the same as those in example 17. Then the luminescent material Na 5 Y 0.5 Tb 0.5 Si 4 O 12  that can emit a green light when excited by the cathode ray is obtained. 
       Example 20 
     Na 5 Y 0.4 Lu 0.4 Tb 0.2 Si 4 O 12  Prepared by Microwave Synthesis Method 
       [0055]    At room temperature, 0.4 mmol Y(NO 3 ) 3 , 0.4 mmol Lu(NO 3 ) 3  and 0.2 mmol Tb(NO 3 ) 3  are dissolved in 2 ml deionized water in a vessel as a standby rare earth solution. The remaining steps are the same as those in example 17. Then the luminescent material Na 5 Y 0.4 Lu 0.4 Tb 0.2 Si 4 O 12  that can emit a green light when excited by the cathode ray is obtained. 
       Example 21 
     Na 5 TbSi 4 O 12  Prepared by Microwave Synthesis Method 
       [0056]    At room temperature, 1 mmol Tb(NO 3 ) 3  are dissolved in 2 ml deionized water in a vessel as a standby rare earth solution. The remaining steps are the same as those in example 17. Then the luminescent material Na 5 TbSi 4 O 12  that can emit a green light when excited by the cathode ray is obtained. 
       Example 22 
     K 5 Y 0.74 Tb 0.26 Si 4 O 12  Prepared by Microwave Synthesis Method 
       [0057]    At room temperature, 0.37 mmol Y 2 (CO 3 ) 3  and 0.13 mmol Tb 2 (CO 3 ) 3  are dissolved in 0.3 ml analytically pure hydrochloric acid in a vessel as a standby rare earth solution. 2.04 g Na 2 SiO 3  solution with a mass percent concentration of 15% is replaced with 2.57 g K 2 SiO 3  with a mass percent concentration of 15%. The remaining steps are the same as those in example 17. Then the luminescent material K 5 Y 0.74 Tb 0.26 Si 4 O 12  that can emit a green light when excited by the cathode ray is obtained. 
       Example 23 
     Li 5 Y 0.99 Tb 0.01 Si 4 O 12  Prepared by Microwave Synthesis Method 
       [0058]    At room temperature, 0.99 mmol Y(NO 3 ) 3  and 0.01 mmol Tb(NO 3 ) 3  are dissolved in 2 ml deionized water in a vessel as a standby rare earth solution. 2.04 g Na 2 SiO 3  solution with a mass percent concentration of 15% is replaced with 1.5 g Li 2 SiO 3  with a mass percent concentration of 15%. The remaining steps are the same as those in example 17. Then the luminescent material Li 5 Y 0.99 Tb 0.01 Si 4 O 12  that can emit a green light when excited by the cathode ray is obtained. 
       Example 24 
     Na 3 Y 0.9 Tb 0.1 Si 3 O 9  Prepared by High Temperature Solid Phase Method 
       [0059]    1.5 mmol Na 2 CO 3 , 0.45 mmol Y 2 O 3 , 0.025 mmol Tb 4 O 7  and 3 mmol SiO 2  are placed in an agate mortar and ground to be uniform powder at room temperature. Then the powder is transferred to a corundum crucible and placed in a high temperature tube-type furnace with weak reducing atmosphere of 95% N 2  and 5% H 2  to be sintered at 1150° C. for 10 h. A generated product during sintering is then placed in a mortar and ground to be uniform after cooling the powder to room temperature. Then the luminescent material Na 3 Y 0.9 Tb 0.1 Si 3 O 9  which can emit a green light when excited by the cathode ray is obtained. 
       Example 25 
     Na 3 Sc 0.74 Tb 0.26 Si 3 O 9  Prepared by High Temperature Solid Phase Method 
       [0060]    1.5 mmol Na 2 CO 3 , 0.37 mmol Sc 2 O 3 , 0.065 mmol Tb 4 O 7  and 3 mmol SiO 2  are placed in an agate mortar and ground to be uniform powder at room temperature. Then the powder is transferred to a corundum crucible and placed in a high temperature tube-type furnace with weak reducing atmosphere of 95% N 2  and 5% H 2  to be sintered at 1000° C. for 20 h. A generated product during sintering is then placed in a mortar and ground to be uniform after cooling the powder to room temperature. Then the luminescent material Na 3 Sc 0.74 Tb 0.26 Si 3 O 9  which can emit a green light when excited by the cathode ray is obtained. 
       Example 26 
     Na 3 Y 0.1 Lu 0.5 Tb 0.4 Si 3 O 9  Prepared by High Temperature Solid Phase Method 
       [0061]    1.5 mmol Na 2 C 2 O 4 , 0.05 mmol Y 2 O 3 , 0.25 mmol Lu 2 O 3 , 0.1 mmol Tb 4 O 7  and 3 mmol SiO 2  are placed in an agate mortar and ground to be uniform powder at room temperature. Then the powder is transferred to a corundum crucible and placed in a high temperature tube-type furnace with weak reducing atmosphere of 95% N 2  and 5% H 2  to be sintered at 1200° C. for 4 h. A generated product during sintering is then placed in a mortar and ground to be uniform after cooling the powder to room temperature. Then the luminescent material Na 3 Y 0.1 Lu 0.5 Tb 0.4 Si 3 O 9  which can emit a green light when excited by the cathode ray is obtained. 
       Example 27 
     Na 3 Y 0.6 Tb 0.4 Si 3 O 9  Prepared by High Temperature Solid Phase Method 
       [0062]    1.5 mmol Na 2 CO 3 , 0.3 mmol Y 2 O 3 , 0.1 mmol Tb 4 O 7  and 3 mmol SiO 2  are placed in an agate mortar and ground to be uniform powder at room temperature. The remaining steps are the same as those in example 24. Then the luminescent material Na 3 Y 0.6 Tb 0.4 Si 3 O 9  which can emit a green light when excited by the cathode ray is obtained. As shown in  FIG. 1 ,  FIG. 1  is the comparison diagram for the cathodoluminescence spectra&#39;s of existing commercial green fluorescent powder (ZnS: Cu, Au, Al) and the sodium silicate luminescent material doped with rare earth ions prepared in the example. Among them, the existing commercial green fluorescent powder (ZnS: Cu, Au, Al) is the ZnS green fluorescent powder doped with Cu, Au and Al ions. From the figure it can be seen that the luminescent material of the present invention has a strong emission peak at 544 nm, and its luminous intensity is equal to that of the commercial green fluorescent powder (ZnS: Cu, Au, Al). The luminescent material of the present invention has the features of high stability, high color purity and high luminous efficiency. 
         [0063]    It should be illustrated that the luminescent spectrums for both the existing commercial green fluorescent powder (ZnS: Cu, Au, Al) provided in the example and the sodium silicate luminescent material doped with rare earth ions prepared in the example are analyzed on Shimadzu RF-5301 spectrometer through the excitation by the cathode ray under an acceleration voltage of 7.5 kV. 
       Example 28 
     Na 3 Y 0.4 Gd 0.2 Tb 0.1 Si 3 O 9  Prepared by High Temperature Solid Phase Method 
       [0064]    1.5 mmol Na 2 CO 3 , 0.2 mmol Y 2 O 3 , 0.1 mmol Gd 2 O 3 , 0.1 mmol Tb 4 O 7  and 3 mmol SiO 2  are placed in an agate mortar and ground to be uniform powder at room temperature. The remaining steps are the same as those in example 24. Then the luminescent material Na 3 Y 0.4 Gd 0.2 Tb 0.4 Si 3 O 9  which can emit a green light when excited by the cathode ray is obtained. 
       Example 29 
     Na 3 TbSi 3 O 9  Prepared by High Temperature Solid Phase Method 
       [0065]    1.5 mmol Na 2 CO 3 , 0.25 mmol Tb 4 O 7  and 3 mmol SiO 2  are placed in an agate mortar and ground to be uniform powder at room temperature. The remaining steps are the same as those in example 24. Then the luminescent material Na 3 TbSi 3 O 9  which can emit a green light when excited by the cathode ray is obtained. 
       Example 30 
     K 3 Y 0.3 La 0.3 Tb 0.4 Si 3 O 9  Prepared by High Temperature Solid Phase Method 
       [0066]    1.5 mmol K 2 C 2 O 4 , 0.15 mmol Y 2 O 3 , 0.15 mmol La 2 O 3 , 0.1 mmol Tb 4 O 7  and 3 mmol SiO 2  are placed in an agate mortar and ground to be uniform powder at room temperature. The remaining steps are the same as those in example 24. Then the luminescent material K 3 Y 0.3 La 0.3 Tb 0.4 Si 3 O 9  which can emit a green light when excited by the cathode ray is obtained. 
       Example 31 
     Li 3 Y 0.74 Tb 0.26 Si 3 O 9  Prepared by High Temperature Solid Phase Method 
       [0067]    1.5 mmol Li 2 CO 3 , 0.37 mmol Y 2 O 3 , 0.065 mmol Tb 4 O 7  and 3 mmol SiO 2  are placed in an agate mortar and ground to be uniform powder at room temperature. The remaining steps are the same as those in example 24. Then the luminescent material Li 3 Y 0.74 Tb 0.26 Si 3 O 9  which can emit a green light when excited by the cathode ray is obtained. 
       Example 32 
     Na 5 Y 0.74 Tb 0.26 Si 4 O 12  Prepared by High Temperature Solid Phase Method 
       [0068]    2.5 mmol Na 2 CO 3 , 0.37 mmol Y(NO 3 ) 3 , 0.065 mmol Tb 2 (CO 3 ) 3  and 4 mmol SiO 2  are placed in an agate mortar and ground to be uniform powder at room temperature. Then the powder is transferred to a corundum crucible and placed in a high temperature tube-type furnace with weak reducing atmosphere of 95% N 2  and 5% H 2  to be sintered at 1115° C. for 6 h. A generated product during sintering is then placed in a mortar and ground to be uniform after cooling the powder to room temperature. Then the luminescent material Na 5 Y 0.74 Tb 0.26 Si 4 O 12  which can emit a green light when excited by the cathode ray is obtained. 
       Example 33 
     Na 5 Y 0.2 Lu 0.6 Tb 0.2 Si 4 O 12  Prepared by High Temperature Solid Phase Method 
       [0069]    2.5 mmol Na 2 CO 3 , 0.2 mmol YCl 3 , 0.6 mmol LuCl 3 , 0.2 mol TbCl 3  and 4 mmol SiO 2  are placed in an agate mortar and ground to be uniform powder at room temperature. The remaining steps are the same as those in example 32. Then the luminescent material Na 5 Y 0.2 Lu 0.6 Tb 0.2 Si 4 O 12  which can emit a green light when excited by the cathode ray is obtained. 
       Example 34 
     Na 5 Y 0.6 Tb 0.1 Si 4 O 12  Prepared by High Temperature Solid Phase Method 
       [0070]    2.5 mmol Na 2 CO 3 , 0.3 mmol Y 2 (C 2 O 4 ) 3 , 0.2 mmol Tb 2 (C 2 O 4 ) 3  and 4 mmol 
         [0071]    SiO 2  are placed in an agate mortar and ground to be uniform powder at room temperature. The remaining steps are the same as those in example 32. Then the Na 5 Y 0.6 Tb 0.1 Si 4 O 12  luminescent material which can emit a green light when excited by the cathode ray is obtained. As shown in  FIG. 2 ,  FIG. 2  is the comparison diagram for the cathodoluminescence spectra&#39;s of existing commercial green fluorescent powder (ZnS: Cu, Au, Al) and the sodium silicate luminescent material doped with rare earth ions prepared in the example. From the figure it can be seen that the luminescent material of the present invention has a strong emission peak at 544 nm, and its luminous intensity reaches 73% of that of the commercial green fluorescent powder (ZnS: Cu, Au, Al). The luminescent material of the present invention has the features of high stability, high color purity and high luminous efficiency. 
         [0072]    It should be illustrated that the luminescent spectrums for both the existing commercial green fluorescent powder (ZnS: Cu, Au, Al) provided in the example and the sodium silicate luminescent material doped with rare earth ions prepared in the example are analyzed on Shimadzu RF-5301 spectrometer through the excitation by the cathode ray under an acceleration voltage of 7.5 kV. 
       Example 35 
     K 3 Y 0.74 Tb 0.26 Si 4 O 12  Prepared by High Temperature Solid Phase Method 
       [0073]    2.5 mmol K 2 CO 3 , 0.37 mmol Y 2 O 3 , 0.065 mmol Tb 4 O 7  and 4 mmol SiO 2  are placed in an agate mortar and ground to be uniform powder at room temperature. The remaining steps are the same as those in example 32. Then the luminescent material K 3 Y 0.74 Tb 0.26 Si 4 O 12  which can emit a green light when excited by the cathode ray is obtained. 
       Example 36 
     Li 5 Y 0.74 Tb 0.26 Si 4 O 12  Prepared by High Temperature Solid Phase Method 
       [0074]    2.5 mmol Li 2 CO 3 , 0.37 mmol Y 2 O 3 , 0.065 mmol Tb 4 O 7  and 4 mmol SiO 2  are placed in an agate mortar and ground to be uniform powder at room temperature. The remaining steps are the same as those in example 32. Then the luminescent material Li 5 Y 0.74 Tb 0.26 Si 4 O 12  which can emit a green light when excited by the cathode ray is obtained. 
       Example 37 
     Na 5 Y 0.8 Gd 0.1 Tb 0.1 Si 4 O 12  Prepared by High Temperature Solid Phase Method 
       [0075]    2.5 mmol Na 2 CO 3 , 0.4 mmol Y 2 (CO 3 ) 3 , 0.05 mmol Gd 2 (CO 3 ) 3 , 0.1 mmol Tb(NO 3 ) 3  and 4 mmol SiO 2  are placed in an agate mortar and ground to be uniform powder at room temperature. The remaining steps are the same as those in example 32. Then the luminescent material Na 5 Y 0.8 Gd 0.1 Tb 0.1 Si 4 O 12  which can emit a green light when excited by the cathode ray is obtained.