CN101955354A - Giant dielectric-nonlinear low-voltage difunctional varistor ceramic material and preparation method thereof - Google Patents
Giant dielectric-nonlinear low-voltage difunctional varistor ceramic material and preparation method thereof Download PDFInfo
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Abstract
The invention relates to the field of materials of electronic information components, and discloses giant dielectric-nonlinear low-voltage varistor ceramic material and a preparation method thereof. The giant dielectric-nonlinear low-voltage varistor ceramic material of the invention is prepared by a sol-gel method in which a citric acid serves as a complexing agent, and has the molecular formula of Bi0.5-xNa0.5-xBa2xCu3Ti4O12, wherein x is more than 0 and less than or equal to 0.075. The ceramic material prepared by the method has a giant dielectric constant and nonlinear low-voltage varistor effect, is a multifunctional ceramic material with vast application prospect, and has dielectric properties and voltage-sensitive characteristics which are adjusted according to the ratio of Ba. The preparation method of the invention has the characteristics of simple process operation, short cycle, low cost, environmental friendliness, nontoxicity, no need of atmosphere reduction and the like.
Description
Technical field
The present invention relates to pressure-sensitive, the non-linear pressure sensitive of the huge dielectric field in the electronic information component.
Background technology
Multi-functional dielectric materials is the critical material that turns to the microelectronics upgrading of feature with the miniaturization of electron device and high speed.The pressure-sensitive dual-function ceramic material of huge dielectric be meant stupalith have concurrently huge specific inductivity (
) and non-linear piezo resistance effect (be non-linear volt-ampere characteristic, the resistance that refers to material is to voltage-sensitive, and the resistance of material is along with electric current changes in certain electric current and voltage scope).Develop rapidly along with microelectronic industry, the integrated level of electron device improves constantly, electronics is to integrated, miniaturization, the multifunction development, the operating voltage and the withstand voltage of various electronic components constantly lower, for the miniaturization and the integrated while of realizing microelectronic device guarantees that again these electronic security circuits move reliably, reduce because overvoltage, electric subpulse such as human body discharge disturbs the influence that circuit is caused, we need adopt huge dielectric-low-voltage piezoresistor (scope of pressure sensitive voltage generally speaking is that 4.7-68V(electric current is 1mA)) absorb inner or outside surge voltage or the electric current of circuit, this just makes low voltage varistor have a wide range of applications and scientific research is worth.The main non-linear based varistor of low pressure mainly is ZnO system, TiO at present
2System, SrTiO
3System etc., for present employed ZnO is low voltage varistor, its specific inductivity is lower usually, and the stray capacity that the electric capacity of itself and its reach object on every side over the ground is suitable, ability abates the noise, and the zinc oxide pressure-sensitive ceramic resistance defective that can cause because of the multiple reasons such as environment of preparation technology and production and use causes and scraps, and influenced its normal use thereby shortened its work-ing life.TiO
2, SrTiO
3Can be used as electric capacity-pressure-sensitive double functional ceramics device after semiconductor, its specific inductivity can reach several thousand usually; But its preparation technology's relative complex and wayward.Therefore seek simple, the stable high dielectric of preparation technology-pressure-sensitive double-function device of low pressure constant for realizing in the microelectronics that device miniaturization and function integration have great importance.
People such as Subramanian went up report perovskite-like material C aCu at " J.Solid.Stat.Chem " first in 2000
3Ti
4O
12Have huge specific inductivity and good temperature stability, its potential application prospect has caused people's attention.2004, people such as Chung went up report, CaCu at " Nat. Mater "
3Ti
4O
12Possess good non-linear pressure-sensitive character, nonlinear factor reaches 900, is one of good varistor device candidate material.2006, people such as Ferrarelli went up report at " Appl.Phys.Lett ", are possessing the Bi of perovskite-like
0.5Na
0.5Cu
3Ti
4O
12Observe characteristic in the pottery equally with high-k.At present, about Bi
0.5-xNa
0.5-xBa
2xCu
3Ti
4O
12Ceramic and huge dielectric-non-linear low voltage varistor characteristic at home with external document in all less than record.
Summary of the invention
Technical problem of the present invention provides a kind of huge dielectric--non-linear low-pressure pressure-sensitive dual-function ceramic material and preparation method thereof, and this stupalith has big specific inductivity and non-linear low voltage varistor characteristic.
For solving the problems of the technologies described above, the invention provides a kind of huge dielectric--the preparation method of non-linear low-pressure pressure-sensitive dual-function ceramic material, it is characterized in that may further comprise the steps:
Step 1, in first beaker that is being placed with analytically pure butyl (tetra) titanate, slowly add aqueous citric acid solution, ceaselessly stir simultaneously and form transparent titanium ion solution, add ethylene glycol with the viscosity of regulator solution with make solution-stabilized, the concentration of gained Ti liquid is 0.5~1.5mol/L, above-mentioned analytically pure butyl (tetra) titanate is as the Ti ion source, citric acid is as complexing agent, and both mol ratios are between 1:1.5~2;
Step 2, in second beaker that is placed with aqueous citric acid solution, add analytically pure cupric nitrate respectively successively, SODIUMNITRATE, Bismuth trinitrate, barium acetate, ultrasonic dispersing is impelled dissolving, form clear solution, the total concn of each metal ion is 0.5~1mol/L, as the ion source of Cu, Na, Bi and Ba, citric acid is a complexing agent respectively for above-mentioned analytically pure cupric nitrate, SODIUMNITRATE, Bismuth trinitrate, barium acetate, and citric acid is 1:1~1:1.5 than the mol ratio with above-mentioned four metal ion species quantity sums;
Step 3, two kinds of solution stirring that above-mentioned first, second beaker is interior are mixed, and regulating the pH value with ammoniacal liquor is 6.5~7.5, mixing solutions ageing 10~12 hours; Then in water-bath 80
oC~100
oC removes moisture with the solution evaporate to dryness, in baking oven 140
oC~160
oThe C drying is until forming the black xerogel;
Step 4, xerogel is ground, in air 500
oC~600
oC thermal treatment 4~6 hours is got rid of organism and is obtained precursor powder; With precursor powder grinding, compressing tablet sintering, sintering temperature is 1000 then
oC, sintering time is 3~5 hours, obtaining molecular formula is Bi
0.5-xNa
0.5-xBa
2xCu
3Ti
4O
12Stupalith, wherein, 0<X≤0.075.
Adopt a kind of huge dielectric--the non-linear low-pressure pressure-sensitive dual-function ceramic material of above-mentioned citrate sol gel method preparation, it is characterized in that the molecular formula of this stupalith is Bi
0.5-xNa
0.5-xBa
2xCu
3Ti
4O
12, wherein, 0<X≤0.075.
Preferably, described huge dielectric--non-linear low-pressure pressure-sensitive dual-function ceramic material is characterized in that the molecular formula of this stupalith is Bi
0.475Na
0.475Ba
0.05Cu
3Ti
4O
12
Preferably, described huge dielectric--non-linear low-pressure pressure-sensitive dual-function ceramic material is characterized in that the molecular formula of this stupalith is Bi
0.45Na
0.45Ba
0.1Cu
3Ti
4O
12
Preferably, described huge dielectric--non-linear low-pressure pressure-sensitive dual-function ceramic material is characterized in that the molecular formula of this stupalith is Bi
0.425Na
0.425Ba
0.15Cu
3Ti
4O
12
The pottery that the present invention prepares has huge specific inductivity and non-linear low voltage varistor effect, is the multifunctional ceramic material that a class has broad prospect of application, and can regulate the dielectric properties and the pressure-sensitive character of material by the ratio that changes Ba; Preparation method's technological operation of the present invention is simple, and the cycle is short, and with low cost, environment-protecting asepsis need not characteristics such as reducing atmosphere.
Description of drawings
Fig. 1 is X=0,0.025,0.05 among the embodiment, 0.075 Bi
0.5-xNa
0.5-xBa
2xCu
3Ti
4O
12The XRD figure spectrum of ceramics sample.
Fig. 2 is X=0,0.025,0.05 among the embodiment, 0.075 Bi
0.5-xNa
0.5-xBa
2xCu
3Ti
4O
12The dielectric frequency collection of illustrative plates of ceramics sample.
Fig. 3 is X=0,0.025 among the embodiment, 0.075 Bi
0.5-xNa
0.5-xBa
2xCu
3Ti
4O
12The I-V of ceramics sample concerns collection of illustrative plates.
Embodiment
Embodiment 1:
Utilize citric acid to prepare Bi as the sol-gel method of complexing agent
0.5-xNa
0.5-xBa
2xCu
3Ti
4O
12(x=0) pottery.At first, take by weighing the beaker 1 that the 0.08mol citric acid is put into 100mL, add deionized water 35mL, under ultrasonic dispersing, dissolve, form clear solution; Take by weighing 0.04mol metatitanic acid fourth fat again and put into the beaker 2 of 100mL, then the citric acid solution in 1 beaker is transferred in 2 beakers in the titanium liquid; Constantly stir and make the dissolving of titanium liquid down, ultra-sonic dispersion 30min then adds the ethylene glycol of 5mL, formation clear solution then.The mol ratio of metatitanic acid fourth fat and aqueous citric acid solution is 1:2.In second step, the citric acid that takes by weighing 0.05mol is put in the beaker of 500mL, adds deionized water 20mL, dissolves under ultrasonic dispersing, forms clear solution; Take by weighing 0.03mol cupric nitrate, 0.005mol SODIUMNITRATE, 0.005mol Bismuth trinitrate then successively and join above-mentioned solution, ultra-sonic dispersion forms clear solution, and the mol ratio of the mol ratio of citric acid and above-mentioned three metal ion species is 1:1.25.The 3rd step, above-mentioned two solution are mixed and continuous the stirring 15 minutes, regulating the pH value with ammoniacal liquor is 7, mixing solutions ageing 10 hours.Then, in water-bath 95
oC removes moisture with the solution evaporate to dryness, in baking oven 160
oThe C drying is until forming the black xerogel.In the 4th step, xerogel was ground 30 minutes, in air 550
oC thermal treatment 5 hours is got rid of organism and is obtained precursor powder, then with precursor powder grinding, compressing tablet, 1000
oC sintering 5 hours obtains Bi
0.5Na
0.5Cu
3Ti
4O
12Pottery.
Utilize embodiment 1 to prepare Bi
0.5Na
0. 5Cu
3Ti
4O
12The pottery XRD as shown in Figure 1, sample has formed good perovskite-like phase structure as can be seen from Figure 1.Fig. 2, Fig. 3 have provided Bi respectively
0.5Na
0.5Cu
3Ti
4O
12Dielectric and I/V concern collection of illustrative plates.
Embodiment 2:
Utilize citric acid to prepare Bi as the sol-gel method of complexing agent
0.5-xNa
0.5-xBa
2xCu
3Ti
4O
12(x=0.025) pottery.At first, take by weighing the beaker 1 that the 0.08mol citric acid is put into 100mL, add deionized water 35mL, under ultrasonic dispersing, dissolve, form clear solution; Take by weighing 0.04mol metatitanic acid fourth fat again and put into the beaker 2 of 100mL, then the citric acid solution in 1 beaker is transferred in 2 beakers in the titanium liquid; Constantly stir and make the dissolving of titanium liquid down, ultra-sonic dispersion 30min then adds the ethylene glycol of 5mL, formation clear solution then.The mol ratio of metatitanic acid fourth fat and aqueous citric acid solution is 1:2.In second step, the citric acid that takes by weighing 0.05mol is put in the beaker of 500mL, adds deionized water 20mL, dissolves under ultrasonic dispersing, forms clear solution; The barium acetate that takes by weighing 0.03mol cupric nitrate, 0.00475mol SODIUMNITRATE, 0.00475mol Bismuth trinitrate and 0.0005mol then successively joins above-mentioned solution, ultra-sonic dispersion forms clear solution, and the mol ratio of the mol ratio of citric acid and above-mentioned three metal ion species is 1:1.25.The 3rd step, above-mentioned two solution are mixed and continuous the stirring 15 minutes, regulating the pH value with ammoniacal liquor is 7, mixing solutions ageing 10 hours.Then, in water-bath 95
oC removes moisture with the solution evaporate to dryness, in baking oven 160
oThe C drying is until forming the black xerogel.In the 4th step, xerogel was ground 30 minutes, in air 550
oC thermal treatment 5 hours is got rid of organism and is obtained precursor powder, then with precursor powder grinding, compressing tablet, 1000
oC sintering 5 hours obtains Bi
0.475Na
0.475Ba
0.05Cu
3Ti
4O
12Pottery.
Utilize embodiment 2 to prepare Bi
0.475Na
0.475Ba
0.05Cu
3Ti
4O
12The pottery XRD as shown in Figure 1, sample has formed good perovskite-like phase structure as can be seen from Figure 1.Fig. 2, Fig. 3 have provided Bi respectively
0.475Na
0.475Ba
0.05Cu
3Ti
4O
12Dielectric and I/V concern collection of illustrative plates.
Embodiment 3:
Utilize citric acid to prepare Bi as the sol-gel method of complexing agent
0.5-xNa
0.5-xBa
2xCu
3Ti
4O
12(x=0.005) pottery.At first, take by weighing the beaker 1 that the 0.08mol citric acid is put into 100mL, add deionized water 35mL, under ultrasonic dispersing, dissolve, form clear solution; Take by weighing 0.04mol metatitanic acid fourth fat again and put into the beaker 2 of 100mL, then the citric acid solution in 1 beaker is transferred in 2 beakers in the titanium liquid; Constantly stir and make the dissolving of titanium liquid down, ultra-sonic dispersion 30min then adds the ethylene glycol of 5mL, formation clear solution then.The mol ratio of metatitanic acid fourth fat and aqueous citric acid solution is 1:2.In second step, the citric acid that takes by weighing 0.05mol is put in the beaker of 500mL, adds deionized water 20mL, dissolves under ultrasonic dispersing, forms clear solution; The barium acetate that takes by weighing 0.03mol cupric nitrate, 0.0045mol SODIUMNITRATE, 0.0045mol Bismuth trinitrate and 0.001mol then successively joins above-mentioned solution, ultra-sonic dispersion forms clear solution, and the mol ratio of the mol ratio of citric acid and above-mentioned three metal ion species is 1:1.25.The 3rd step, above-mentioned two solution are mixed and continuous the stirring 15 minutes, above-mentioned two solution are mixed, regulating the pH value with ammoniacal liquor is 7, mixing solutions ageing 10 hours.Then, in water-bath 95
oC removes moisture with the solution evaporate to dryness, in baking oven 160
oThe C drying is until forming the black xerogel.In the 4th step, xerogel was ground 30 minutes, in air 550
oC thermal treatment 5 hours is got rid of organism and is obtained precursor powder, then with precursor powder grinding, compressing tablet, 1000
oC sintering 5 hours obtains Bi
0.45Na
0.45Ba
0.1Cu
3Ti
4O
12Pottery.
Utilize embodiment 3 to prepare Bi
0.45Na
0.45Ba
0.1Cu
3Ti
4O
12The pottery XRD as shown in Figure 1, sample has formed good perovskite-like phase structure as can be seen from Figure 1.Fig. 2, Fig. 3 have provided Bi respectively
0.45Na
0.45Ba
0.1Cu
3Ti
4O
12Dielectric and I/V concern collection of illustrative plates.
Embodiment 4:
Utilize citric acid to prepare Bi as the sol-gel method of complexing agent
0.5-xNa
0.5-xBa
2xCu
3Ti
4O
12(x=0.075) pottery.At first, take by weighing the beaker 1 that the 0.08mol citric acid is put into 100mL, add deionized water 35mL, under ultrasonic dispersing, dissolve, form clear solution; Take by weighing 0.04mol metatitanic acid fourth fat again and put into the beaker 2 of 100mL, then the citric acid solution in 1 beaker is transferred in 2 beakers in the titanium liquid; Constantly stir and make the dissolving of titanium liquid down, ultra-sonic dispersion 30min then adds the ethylene glycol of 5mL, formation clear solution then.The mol ratio of metatitanic acid fourth fat and aqueous citric acid solution is 1:2.In second step, the citric acid that takes by weighing 0.05mol is put in the beaker of 500mL, adds deionized water 20mL, dissolves under ultrasonic dispersing, forms clear solution; The barium acetate that takes by weighing 0.03mol cupric nitrate, 0.0047mol SODIUMNITRATE, 0.0047mol Bismuth trinitrate and 0.0006mol then successively joins above-mentioned solution, ultra-sonic dispersion forms clear solution, and the mol ratio of the mol ratio of citric acid and above-mentioned three metal ion species is 1:1.25.The 3rd step, above-mentioned two solution are mixed and continuous the stirring 15 minutes, above-mentioned two solution are mixed, regulating the pH value with ammoniacal liquor is 7, mixing solutions ageing 10 hours.Then, in water-bath 95
oC removes moisture with the solution evaporate to dryness, in baking oven 160
oThe C drying is until forming the black xerogel.In the 4th step, xerogel was ground 30 minutes, in air 550
oC thermal treatment 5 hours is got rid of organism and is obtained precursor powder, then with precursor powder grinding, compressing tablet, 1000
oC sintering 5 hours obtains Bi
0.425Na
0.425Ba
0.15Cu
3Ti
4O
12Pottery.
Utilize embodiment 4 to prepare Bi
0.425Na
0.425Ba
0.15Cu
3Ti
4O
12The pottery XRD as shown in Figure 1, sample has formed good perovskite-like phase structure as can be seen from Figure 1.Fig. 2, Fig. 3 have provided Bi respectively
0.425Na
0.425Ba
0.15Cu
3Ti
4O
12Dielectric and I/V concern collection of illustrative plates.
Adopt the Bi of above method preparation
0.5-xNa
0.5-xBa
2xCu
3Ti
4O
12(0≤x≤0.075) pottery possesses huge dielectric constant and non-linear low voltage varistor characteristic, is a kind of huge dielectric-non-linear low-pressure pressure-sensitive ceramic material with broad prospect of application.To the sample The characterization of microstructure, adopt X-ray diffractometer (XRD) to its material phase analysis.Adopt the dielectric properties of the accurate electric impedance analyzer measure sample of Wk6500B.Adopt Keithley2400 to measure the I/V characteristic of sample.
As shown in Figure 1, provided x=0,0.025,0.05,0.075 sintering temperature is 1000
oXRD figure spectrum during C, as can be seen from the figure all samples have formed good perovskite-like phase structure.When doping ratio is that the sample of X=0.025 can mate fully.As the x=0.05 that brings up to of doping ratio, 0.75 o'clock sample a spot of assorted peak occurred but main peak can be good at coupling.
Fig. 2 is the specific inductivity of x=0,0.025,0.075 sample and the graph of a relation of frequency.As can be seen from the figure the sample of x=0 has maximum specific inductivity, and along with the raising of Ba doping ratio, downward trend has appearred in specific inductivity, but 10
2-10
6Range of frequency in the specific inductivity of all samples all remain on 10
3-10
4Between, all samples have still kept huge specific inductivity.
Fig. 3 is the I-V graph of a relation of x=0,0.025,0.05,0.075 sample, and all samples have all shown non-linear piezo resistance effect.From figure, can be clearly seen that with the unadulterated pressure sensitive voltage of comparing adulterated sample and significantly reduce, wherein the pressure sensitive voltage of the sample of X=0 is 61V, the pressure sensitive voltage minimum of the sample of X=0.025 is 8V, the pressure sensitive voltage of the sample of X=0.05 is 16V, and the pressure sensitive voltage of the sample of X=0.075 is 25V.
It should be noted last that, above embodiment only in order to illustrate this material the technology implementation scheme but not the restriction, although the present invention is had been described in detail with reference to preferred embodiment, those of ordinary skill in the art is to be understood that, can make amendment or be equal to replacement technical scheme of the present invention, and not breaking away from the spirit and scope of technical solution of the present invention, it all should be encompassed in the middle of the claim scope of the present invention.
Claims (4)
1. a huge dielectric--the preparation method of non-linear low-pressure pressure-sensitive dual-function ceramic material is characterized in that may further comprise the steps:
Step 1, in first beaker that is being placed with analytically pure butyl (tetra) titanate, slowly add aqueous citric acid solution, ceaselessly stir simultaneously and form transparent titanium ion solution, add ethylene glycol with the viscosity of regulator solution with make solution-stabilized, the concentration of gained Ti liquid is 0.5~1.5mol/L, above-mentioned analytically pure butyl (tetra) titanate is as the Ti ion source, citric acid is as complexing agent, and both mol ratios are between 1:1.5~2;
Step 2, in second beaker that is placed with aqueous citric acid solution, add analytically pure cupric nitrate respectively successively, SODIUMNITRATE, Bismuth trinitrate, barium acetate, ultrasonic dispersing is impelled dissolving, form clear solution, the total concn of each metal ion is 0.5~1mol/L, as the ion source of Cu, Na, Bi and Ba, citric acid is a complexing agent respectively for above-mentioned analytically pure cupric nitrate, SODIUMNITRATE, Bismuth trinitrate, barium acetate, and citric acid is 1:1~1:1.5 than the mol ratio with above-mentioned four metal ion species quantity sums;
Step 3, two kinds of solution stirring that above-mentioned first, second beaker is interior are mixed, and regulating the pH value with ammoniacal liquor is 6.5~7.5, mixing solutions ageing 10~12 hours; Then in water-bath 80
oC~100
oC removes moisture with the solution evaporate to dryness, in baking oven 140
oC~160
oThe C drying is until forming the black xerogel;
Step 4, xerogel is ground, in air 500
oC~600
oC thermal treatment 4~6 hours is got rid of organism and is obtained precursor powder; With precursor powder grinding, compressing tablet sintering, sintering temperature is 1000 then
oC, sintering time is 3~5 hours, obtaining molecular formula is Bi
0.5-xNa
0.5-xBa
2xCu
3Ti
4O
12Pottery, wherein, 0<X≤0.075.
2. the non-linear low-pressure pressure-sensitive dual-function ceramic material of huge dielectric according to claim 1--huge dielectric that the preparation method of non-linear low-pressure pressure-sensitive dual-function ceramic material is prepared--is characterized in that the molecular formula of this stupalith is Bi
0.5-xNa
0.5-xBa
2xCu
3Ti
4O
12, wherein, 0≤X≤0.075, it has high specific inductivity and non-linear piezo resistance effect.
3. according to claim 1 or 2 described huge dielectrics--non-linear low-pressure pressure-sensitive dual-function ceramic material, it is characterized in that the molecular formula of this stupalith is Bi
0.475Na
0.475Ba
0.05Cu
3Ti
4O
12
4. according to claim 1 or 2 described huge dielectrics--non-linear low-pressure pressure-sensitive dual-function ceramic material, it is characterized in that the molecular formula of this stupalith is Bi
0.45Na
0.45Ba
0.1Cu
3Ti
4O
12,
5, according to claim 1 or 2 described huge dielectrics--non-linear low-pressure pressure-sensitive dual-function ceramic material, it is characterized in that the molecular formula of this stupalith is Bi
0.425Na
0.425Ba
0.15Cu
3Ti
4O
12
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103482974A (en) * | 2013-09-29 | 2014-01-01 | 哈尔滨理工大学 | Preparation method of CaCu3Ti4O12 ceramic powder |
CN107602116A (en) * | 2017-09-28 | 2018-01-19 | 天津大学 | A kind of method that copper titanate strontium bismuth sodium dielectric material is prepared based on sol-gal process |
Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN1568295A (en) * | 2001-10-12 | 2005-01-19 | 纳幕尔杜邦公司 | Sodium copper titanate compositions containing a rare earth, yttrium or bismuth |
CN1975943A (en) * | 2006-12-20 | 2007-06-06 | 天津大学 | Doped copper titanium oxide capacitor ceramic dielectric and producing method thereof |
CN101503186A (en) * | 2008-02-04 | 2009-08-12 | 微宏科技(湖州)有限公司 | Precursor water solution for preparing CaCu3Ti4O12 and preparing method thereof |
CN101671178A (en) * | 2009-09-24 | 2010-03-17 | 华中科技大学 | Preparation method of Bi0.5Na0.5Cu3Ti4O12 giant dielectric non-linear pressure-sensitive ceramics |
-
2010
- 2010-10-21 CN CN 201010514378 patent/CN101955354B/en not_active Expired - Fee Related
Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN1568295A (en) * | 2001-10-12 | 2005-01-19 | 纳幕尔杜邦公司 | Sodium copper titanate compositions containing a rare earth, yttrium or bismuth |
CN1975943A (en) * | 2006-12-20 | 2007-06-06 | 天津大学 | Doped copper titanium oxide capacitor ceramic dielectric and producing method thereof |
CN101503186A (en) * | 2008-02-04 | 2009-08-12 | 微宏科技(湖州)有限公司 | Precursor water solution for preparing CaCu3Ti4O12 and preparing method thereof |
CN101671178A (en) * | 2009-09-24 | 2010-03-17 | 华中科技大学 | Preparation method of Bi0.5Na0.5Cu3Ti4O12 giant dielectric non-linear pressure-sensitive ceramics |
Non-Patent Citations (1)
Title |
---|
《物理学报》 20100531 陈戈等 (Na1/2Bi1/2)Cu3Ti4O12陶瓷的微观结构和电学性质 第3509-3515页 1-5 第59卷, 第5期 * |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103482974A (en) * | 2013-09-29 | 2014-01-01 | 哈尔滨理工大学 | Preparation method of CaCu3Ti4O12 ceramic powder |
CN107602116A (en) * | 2017-09-28 | 2018-01-19 | 天津大学 | A kind of method that copper titanate strontium bismuth sodium dielectric material is prepared based on sol-gal process |
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