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515825903931(½ð±Ò+80,VIP+0):лл 4-22 17:48
515825903931(½ð±Ò+80,VIP+0):лл 4-22 17:48
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Study on the Synthesis of Barium Ferrite with Self-Propagating Combustion Technology Abstract: Magnetic lead-type (M type) barium ferrite (BaFe12O19) is widely used as millimeter-band microwave materials, microwave absorbing materials and high-density perpendicular magnetic recording medias for its superior advantage in terms of lower prices of raw material, excellent chemical stability, higher coercivity and energy product as well as its uniaxial magnetic anisotropy etc. In this paper, Magnetic lead-type barium ferrite was synthesized with two different approaches respectively, namely self-propagating high-temperature synthesis (SHS) and self-propagating low temperature synthesis (LCS). In terms of SHS, the influence of the iron content, pressing density, replacement of the barium, doped lanthanum as well as magnetic field inspiration on SHS were investigated. In terms of LCS, the influence of sintering temperature, sol pH, molar ratio of citric acid to metal ions as well as surfactants on LCS were investigated, respectively. The barium ferrite phase composition, microstructure and magnetic properties were also characterized with the help of XRD, SEM, VSM. Our study showed that both of the two approaches could be used in preparing M-type barium ferrite effectively. In the study of SHS, the iron powder content had a relatively closer connection with the magnetic properties of samples. As an example, magnetic properties of barium ferrite reached the optimal point when iron mass fraction was 25.74%, in which condition the coercivity was 644.8Oe, saturated magnetization (Ms) was 26.26emu/g, residual magnetization (Mr) was 7.292emu / g, respectively. However, once the iron mass fraction exceeded 25.74%, coercivity, Ms and Mr would drop significantly. In addition, the replacement of BaO2 with BaO was better than with BaCO3, as the replaceing effect of the former was superior to the latter. To replace BaO2, extra oxygen was needed. The pressing density in barium ferrite also had an optimal value of 1.888 g/cm3. Doped lanthanum could obviously change the magnetic properties of barium ferrite and barium ferrite exhibited the best comprehensive magnetic properties when the replacing capacity of La3+ was 0.3. It was possible to synthesize BaFe12O19 with the help of SHS under external magnetic field conditions, and the increase of magnetic field strength would be helpful for the improvement of magnetic properties. Degree of magnetization would exert certain influence on the composition and magnetic properties of the final products. Moreover, the crucial period that magnetic field played its role in SHS synthesis was during the course of self-propagating combustion. When magnetic field strength was 20T, the relationship between magnetic properties of BaFe12O19 and magnetic field direction was shown as follows: positive magnetic field> vertical magnetic field> reverse magnetic field. In the study of LCS, sintering temperature had a major impact on the magnetic properties of samples. And with the increase of sintering temperature, magnetic properties were improved accordingly. Coercivity reached its maximum of 5.509kOe at 900¡æ, while Ms and Mr both reached their maximum of 59.84emu/g and 31.99emu/g at 1000¡æ, respectively. When the sintering temperature exceeded 1000¡æ, coercivity, Ms and Mr dropped significantly. The optimal conditions of the synthesis of barium ferrite with LCS approach were shown as follows: pH of former solution was 7.00; ratio of citric acid to metal ions was 2£º1; sintering temperature was 1180¡æ. Addition of appropriate surfactants could also help enhance the magnetic properties. In comparison with SHS, barium ferrite powder characterized by a smaller particle size, uniform distribution and better magnetic properties could be prepared with LCS. To sum up, synthesis of barium ferrite with LCS technology had a broad prospect. Key words: BaFe12O19, self-propagating high temperature synthesis, self-propagating low temperature synthesis, magnetic properties, magnetic field  ¾Ü¾øÔÚÏß·Òë[ Last edited by zhaomei2007 on 2009-4-22 at 16:58 ] |
3Â¥2009-04-22 15:19:56
wwjlf
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- ×¢²á: 2008-08-22
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Study on Self-propagating combustion synthesis barium ferrite
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515825903931(½ð±Ò+20,VIP+0):ллÄúµÄ°ï棬µ«ÊǾ¹ý¶Ô±È¥ϵÄÒ©¸ü¼Ó׼ȷ¡¢ºÏÀí¡£ 4-22 17:48
515825903931(½ð±Ò+20,VIP+0):ллÄúµÄ°ï棬µ«ÊǾ¹ý¶Ô±È¥ϵÄÒ©¸ü¼Ó׼ȷ¡¢ºÏÀí¡£ 4-22 17:48
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Abstract: The magnetic lead-type (M type) barium ferrite (BaFe12O19) due to cheaper raw materials, excellent chemical stability, high coercivity and energy product, uniaxial magnetic anisotropy and good chemical stability etc., which are widely used as a millimeter-band microwave materials, microwave absorbing materials and high-density perpendicular magnetic recording media. In this paper, self-propagating high-temperature synthesis (SHS) and self-propagating high temperature synthesis (LCS) of two chemically synthesized magnetic-type barium ferrite lead. Self-propagating high-temperature synthesis, the study of the iron content, to suppress the density of the source replace the barium, lanthanum-doped magnetic field to stimulate the effects of SHS.Self-propagating high temperature synthesis to study the sintering temperature, sol pH, metal ions and citric acid molar ratio, as well as surfactants on the impact of LCS. Using XRD, SEM, VSM on the barium ferrite phase composition, microstructure and magnetic properties were characterized. The study found that use of self-propagating high temperature synthesis and self-propagating high temperature synthesis can be prepared M-type barium ferrite. In the SHS, the iron content on the magnetic properties of samples a greater impact when the quality of iron content of 25.74% per cent when the magnetic powder prepared by the best, the coercivity for 644.8Oe, saturation magnetization (Ms) to 26.26 emu / g, residual magnetization (Mr) for 7.292emu / g, when the quality of iron concentration of more than 25.74% percent, the saturation magnetization, residual magnetization and coercivity are small quickly.In addition, the use of BaCO3 to BaO than to replace BaO2 is feasible. Replace the effect of BaO is better than the BaCO3. To BaO2 to replace the need to respond to provide additional oxygen atmosphere. SHS in the suppression of the density of barium ferrite, there are also the best density for the 1.888 g/cm3. Lanthanum-doped barium ferrite can be significant changes in the magnetic properties, when the La3 + ions replace the capacity of x = 0.3, the barium ferrite integrated with the best magnetic properties. External magnetic field under the conditions of SHS Synthesis BaFe12O19 is feasible. The increase in magnetic field strength BaFe12O19 help improve the magnetic properties. Degree of magnetization different products with the composition and magnetic properties have had a certain impact. In addition, magnetic field on the SHS synthesis play a major role in the ferrite during the period of self-propagating combustion.20T when the magnetic field strength, BaFe12O19 magnetic field direction with the relationship: a positive magnetic field> vertical magnetic field> magnetic field reverse. In the LCS, the sintering temperature on the magnetic properties of samples can affect the larger, with the sintering temperature, the magnetic properties of the samples also increased, at 900 ¡æ Hcj maximum appears 5.509kOe, 1000 ¡æ when saturation magnetization (Ms), residual magnetization (Mr) there were maximum 59.84emu / g and 31.99emu / g, when the sintering temperature is above 1000 ¡æ, the saturation magnetization, residual magnetization and coercivity are small quickly. Synthesis of barium ferrite LCS the best conditions were as follows: pre-body solution pH value of 7.00, citric acid and metal ions in the volume of the material ratio of 2:1, since the spread of the powder in the post-combustion temperature of 1180 ¡æ sintering for calcination. The addition of appropriate surfactants can enhance performance. Through comparative analysis of two methods, using low-temperature self-propagating combustion synthesis of the powder prepared by a smaller particle size distribution more uniform and better magnetic properties. Self-propagating high temperature synthesis of more prospects for development. Key words: BaFe12O19, SHS, self-propagating high temperature synthesis, magnetic properties, magnetic field |
2Â¥2009-04-22 13:31:50
zw0912
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4Â¥2009-04-22 20:44:45
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5Â¥2010-03-29 09:05:23
