共查询到19条相似文献,搜索用时 78 毫秒
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稀土磷酸盐发光材料的微波合成 总被引:5,自引:0,他引:5
稀土磷酸盐发光材料的微波合成徐文国,田一光,刘淼,刘海堂,方光华,庞文琴(吉林大学化学系,环境科学系,长春,130023)关键词微波合成,稀土磷酸盐,微晶玻璃,玻璃态,发光材料稀土磷酸盐发光材料的研究是当前材料科学的热门研究课题。它们一般通过高温固相... 相似文献
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超级电容器纳米氧化锰电极材料的合成与表征 总被引:18,自引:0,他引:18
以聚乙二醇为分散剂,利用高锰酸钾和醋酸锰溶液之间的化学共沉淀法制备纳米水合氧化锰.借助SEM,TEM,FT-IR,XRD和BET分析手段对样品结构及性能进行表征.研究结果表明,SEM和TEM显示所得粉体为纳米粉体,粒径大约为10~30nm左右,XRD分析表明该粉体为无定型a-MnO2·nH2O,FT-IR分析表明获得的粉体为水合物,BET测试比表面积达160.7m2/g.以氧化锰为研究电极,饱和甘汞电极(SCE)为参比电极,铂片为辅助电极的三电极体系中,以1 mol/L的Na2SO4溶液为电解液,通过循环伏安法研究其电化学行为.实验结果表明,纳米氧化锰是理想的超级电容器电极材料,在电位窗口为-0.2~0.9V(vs.SCE)范围内,扫描速度为4mV/s,其比电容达到203.4 F/g. 相似文献
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锂离子电池纳米电极材料研究 总被引:29,自引:1,他引:29
采用XRD,TEM方法对纳米相电极材料的结构,形貌进行表征,并用循环伏安法,恒流充放电法对电极材料的嵌锂电化学行为进行研究。结果表明,由于纳米材料的微结构特性使萁 具有优越的嵌锂特性;1)锂离子嵌入电极材料内部的深度小,过程短,具 较大的比表面,有利于采用较大的电流对该电池进行充放电;2)具有较大的嵌锂空间位置,有利于增加电极的锂嵌容量。 相似文献
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功能高分子型活性材料结构对钆离子选择电极性能的影响 总被引:1,自引:0,他引:1
本文采用接枝共聚方法合成功能高分子型钆化合物活性材料,研究了它们的结构和某些性能,结果表明这些活性材料的结构和性能对钆离子选择电极性能有较大的影响。 相似文献
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微波诱导合成固体快离子导电材料 总被引:10,自引:0,他引:10
采用微波法合成了具有快离子传输性质的系列磷锑酸钾化合物K3Sb3P2O14、K2SbPO6、KSbP2O8、KSb2PO8和K5Sb5P2O20以及系列锗锌酸锂固熔体Li2+2xZn1-xGeO4(-0.36〈x〈0.85)。粉末X射线衍射和扫描电镜研究表明,微波合成的样品晶形规整,粒度小且均匀。与传统的高温固相反应相比,微波诱导合成具有反应速度快,易于控制和反应选择性高等特点。在一定温度下微波辐 相似文献
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超级电容器,也称电化学电容器,它具有比锂离子电池更高的功率密度和更长的循环寿命,与此同时,其能量密度也高于传统的电介质电容器,因此成为了一类具有很大应用前景的能量储存设备。随着人们对智能电子设备性能要求的提高,各类柔性可穿戴电子设备相继出现,柔性超级电容器作为一类便携式能量储存设备也受到了许多研究者的关注。在持续的研究中,二维平面结构的柔性超级电容器得到较大发展并日益成熟,与此同时,随着对柔性电子设备可穿戴性能要求的提高,一维纤维结构的柔性超级电容器应运而生,并且得到了初步发展。本文首先介绍了超级电容器的储能原理和重要性能的评估方法;接着,重点概述了二维平面结构和一维纤维结构两类柔性超级电容器器件结构和电极材料的研究进展;最后,总结了两类柔性超级电容器仍然存在并亟待解决的问题以及未来发展所面临的关键技术挑战,期望能为柔性超级电容器的研究提供参考和借鉴。 相似文献
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微波场下水滑石的快速合成及制备 总被引:9,自引:0,他引:9
水滑石以其独特的碱催化性能~[1,2]、记忆效应及阴离子交换~[3]等特性引起人们的关注,其合成多用水热法.本文研究了在微波场中水滑石的合成及制备,得到了较好的结果. 1 实验部分 1.1 仪器与试剂 Shimadzu CD-3A型X射线衍射仪(日本);Nicolet 5DX FTIR光谱仪(美国),KBr压片;蚬华E100-EA型微波炉(广东顺德).所有试剂均为分析纯. 相似文献
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Sang-Eon Park Jong-San Chang Young Kyu Hwang Dae Sung Kim Sung Hwa Jhung Jin Soo Hwang 《Catalysis Surveys from Asia》2004,8(2):91-110
Application of a microwave technique to the conventional hydrothermal process is gaining importance, especially, in the synthesis of nanoporous materials. This microwave technique is regarded as a novel synthesis tool because it gives several beneficial advantages such as homogeneous nucleation, rapid synthesis, formation of uniform crystals, and small crystallites, facile morphology control, energy efficiency and so on. Recently, it was found that it offers an efficient way to control the crystal morphology, size and orientation, and even crystalline phase which are required for many emerging applications of nanoporous materials. This review summarizes recent work on the microwave effect, supramolecular interactions and control of crystal morphology upon microwave synthesis of nanoporous materials performed by the present authors. Synthesis and morphology control of nanoporous materials such as ZSM-5, zeolite beta, metallosilicates, AlPO, MCM-41, SBA-15, SBA-16, etc. have been accomplished with microwave irradiation. In particular, the rapid nucleation and crystallization of ZSM-5 zeolite under microwave irradiation made it possible to enable the continuous microwave synthesis, implying a great industrial and technological importance. The formation of nanoporous materials, especially, silicate or aluminosilicate molecular sieves was described on the basis of supramolecular interactions between organic template molecules and silicate species under microwave irradiation. Besides decreasing synthesis time, it was duly demonstrated that the microwave technique provides an effective way to control particle size distribution and macroscopic morphology in the synthesis. Moreover, for the application of these porous materials, microwave-induced nanofabrication of microporous and mesoporous materials is more important than that of simple porous materials. 相似文献
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AIN纳米微粉的微波合成 总被引:1,自引:0,他引:1
Nanometer aluminum nitride powder with purity higher than 98wt% and diameter in the range of 5-80nm has been obtained by microwave heating using α-Al2O3、Al(OH)3、 colloidal Al(OH)3 as the source for aluminum, and phenolformaldehyde resin, char, nanometer carbon black powder as the source for carbon, respectively. The effect of the type of starting materials and synthesis conditions on the purity and the size of the nanometer AlN powder has been analyzed in this paper. 相似文献
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Dr. David M. Heard Dr. Alastair J. J. Lennox 《Angewandte Chemie (Weinheim an der Bergstrasse, Germany)》2020,132(43):19026-19044
The choice of electrode material is critical for achieving optimal yields and selectivity in synthetic organic electrochemistry. The material imparts significant influence on the kinetics and thermodynamics of electron transfer, and frequently defines the success or failure of a transformation. Electrode processes are complex and so the choice of a material is often empirical and the underlying mechanisms and rationale for success are unknown. In this review, we aim to highlight recent instances of electrode choice where rationale is offered, which should aid future reaction development. 相似文献
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微波技术在有机合成中的应用 总被引:48,自引:1,他引:48
评述了微波加热技术在有机合物的烃基化,酯化和皂化,磺化,烯烃加成,Diels-Alder缩合,氧化,环化与开环及重排等反应中的应用,参考文献73篇。 相似文献
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碳化硅纳米晶须的微波合成 总被引:4,自引:0,他引:4
SiC nanometer whisker, whose diameter was about 50nm and purity was 98.54%, was synthesized by microwave heating in an atmosphere of argon. Char pyrolyzed phenolformaldehyde resin and SiO2 nanometer powder were used as starting materials. The properties of the whisker were determined by XRD and TEM. The mechanism for synthesizing SiC nanometer whisker was discussed. 相似文献