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Mg/Zn/Al类水滑石的热分解和水化性能研究 总被引:1,自引:0,他引:1
采用共沉淀法制备了Mg2Al1、Zn2Al1和Mg1Zn1Al1LDHs,利用XRD和SEM表征手段,对它们的热分解及焙烧物在Na2CO3溶液中恢复层状结构的能力进行了对比研究。结果表明,在400~700℃温度范围内,Zn2Al1LDH和Mg2Al1LDH的焙烧物中均出现氧化物相(ZnO和MgO)和尖晶石相(ZnAl2O4和MgAl2O4相);而Mg1Zn1Al1LDH的焙烧物中始终以ZnO相为主,仅在700℃时出现微弱的MgAl2O4相。三种焙烧物恢复层状结构的能力为:Mg1Zn1Al1LDO>Mg2Al1LDO>Zn2Al1LDO,其与焙烧物组成有关。原始LDHs和水化LDHs均呈片状。 相似文献
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使用不同浓度(0~67%)的硝酸对活性炭载体进行预处理,以H2PdCl4为前驱体,用浸渍法制备理论负载量为5%的Pd/C催化剂.浸渍过程中的吸附实验表明,Pd前驱体的平衡吸附量随预处理硝酸浓度的增加而逐渐减小,尤其是浓硝酸预处理的活性炭载体,其上仅有62.54%的Pd前驱体吸附,而37.46%的Pd前驱体仍在水浆液中.分析发现,Pd前驱体的平衡吸附量主要取决于活性炭的零电荷点,表面电荷模型能较好地描述Pd前驱体的吸附规律.当使用浓度≤5%的硝酸进行预处理时,Pd的粒径随硝酸浓度的增加而减小;当硝酸浓度继续增加时,Pd粒径急剧增大.Pd前驱体的平衡吸附量与Pd粒径的大小无直接关系,而Pd前驱体在活性炭表面上吸附物种及数量的不同也对Pd粒径的大小产生影响.活性炭表面基团的增加抑制了PdClyx-吸附物种的生成.当使用≤5%的硝酸处理活性炭时,Pd前驱体的吸附形态主要为PdClxy-和Pd0;当硝酸浓度>5%时,没有检测到PdClyx-的存在. 相似文献
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Shape apprearance and crystallite characterization of magnesium hydroxide at different hydrothermal tempera-tures have been investigated by SEM, XRD and DSC methods. The grain size, cell parameter and lattice distortion rate of powders under each condition were obtained. The results show that the grains had grown up, especially along the (001) surface as the hydrothermal temperature was raised, accompanying the shrinkage of lattice and the de-scending of distortion rate. These could be relate to the re-crystallization of Mg(OH)2, as well as the thermal dif-fusion of OH- with lower charges, resulting in good dispersion, high thermal decomposition temperature and en-thalpy of Mg(OH)2. Moreover, it is helpful for the increase of the retardant behavior of Mg(OH)2. 相似文献
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分别以乙二醇/去离子水为溶剂,通过溶剂热/水热法分别制备了具有不同主导晶面的BiOIO3/{110}BiOCl和BiOIO3/{001}BiOCl异质结。采用X射线衍射、扫描电子显微镜、能量色散谱和紫外可见漫反射光谱对制备的BiOIO3/BiOCl光催化剂进行了表征。在可见光照射下,通过对罗丹明 B和苯酚水溶液的光催化降解,考察了 BiOIO3/BiOCl异质结的光催化活性。结果显示25% BiOIO3/{110}BiOCl异质结具有最高的光催化效率。BiOIO3/{110}BiOCl较好的光催化性能是由于其在可见光区较强的光吸收,以及异质结结构和BiOCl所具有的(110)主导晶面有利于光生载流子的分离。超氧自由基(·O2-)和空穴(h+)是光催化过程中的主要活性物质。此外,根据实验结果探讨了光催化性能增强的机理。 相似文献
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MoS2 nanotube coated SWNT (Single wall carbon nanotube) bundles have been successfully prepared by adsorbing (NH4)2MoS4 onto SWNT bundles and subsequent heat treatment under H2 at 900 ℃ in a tube furnace. The morphologies, structure and composition of the as-prepared sample were investigated by XRD, SEM, HRTEM coupled with EDS. The formation mechanism has also been preliminarily discussed. 相似文献
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