1) Mesocarbon microbeads (MCMBs)
中间相炭微球(MCMBs)
2) MCMB
中间相炭微球
1.
Research on Preparation and Formation Mechanism of MCMB;
中间相炭微球制备与形成机理的研究
2.
Effects of pre-oxidation and the temperature of heat treatment on composition and microstructure of MCMB
预氧化及热处理温度对中间相炭微球组成和结构的影响
3.
The carbon/graphite molding blocks with high density and strength were prepared from mesocarbon microbeads (MCMB) molded at 100 MPa and then heat-treated.
以中间相炭微球(MCMB)为原料,在100MPa的压力下冷模压成型后,再经过热处理得到高密高强炭/石墨材料。
4) mesocarbon microbeads
中间相炭微球
1.
The influence of mesocarbon microbeads with different structure on their electrochemical performance;
中间相炭微球的结构对其电化学性能的影响
2.
Electrochemical performance of Ag-coated mesocarbon microbeads;
石墨化中间相炭微球表面镀银的电化学性能
3.
Mesocarbon microbeads (MCMB), discovered in the research of mesophase, is one of the new carbon materials and its research has laid the foundation of the mesophase theory.
中间相炭微球是一种新型炭材料 ,它是在研究中间相的过程中发展起来的 ,其理论基础是中间相理论。
5) mesocarbon microbeads (MCMBs)
中间相炭微球
1.
Activated carbons were prepared from mesocarbon microbeads (MCMBs) by means of different carbonization conditions and chemical activations.
以中间相炭微球作为前驱体,在不同条件下进行炭化预处理,再经过化学活化热处理制备活性中间相炭微球,以此为电极材料组装超级电容器并进行电化学测试。
2.
Activated mesocarbon microbeads (MCMBs) were prepared by KOH chemical activation method, the effect of activation conditions on the absorb capability and pore structure of activated MCMBs was investigated by changing KOH/MCMBs ratio, activation temperature and holding time, and a better regulation between the pore structure changing and active agent ratio was found.
利用KOH化学活化方法制备活性中间相炭微球(MCMBs),通过改变活化剂比例、活化温度及活化停留时间,考察活化条件对活性炭微球吸附性能和孔结构的影响,发现活性炭微球孔结构的变化与活化剂添加量之间存在良好的相关性;未经过炭化处理的中间相炭微球具有独特的各向异性结构,其碳层取向性强,活化产物对小分子(如碘分子)吸附质具有良好的吸附性能,最大值可达到2383mg/g;以活性中间相炭微球为电极材料制备的水系双电层电容器循环性能良好,最大质量比电容可达271F/g。
3.
In this paper, activated mesocarbon microbeads (MCMBs) made with different activation conditions including KOH/MCMBs ratio, activation temperature and holding time were investigated and there is a better regulation between the pore structure changing and active agent ratio.
本文利用KOH化学活化方法制备活性中间相炭微球,通过改变活化剂比例、活化温度及活化停留时间,考察活化条件对活性炭微球吸附性能和孔结构的影响,发现活性炭微球孔结构的变化与活化剂添加量之间存在良好的相关性;未经过炭化处理的中间相炭微球具有独特的各向异性结构,其碳层取向性强,活化产物对小分子(如碘分子)吸附质具有良好的吸附性能,最大值可达到2383mg/g;以活性中间相炭微球为电极材料制备的水系双电层电容器循环性能良好,最大质最比电容可达271 F/g。
6) mesocarbon microbeads
中间相沥青炭微球
1.
C/C composites using mesocarbon microbeads (MCMB) as matrix and pitch based carbon fibers (CF) as reinforcement were prepared through simple oxidation treatment,mechanical blend,hot press molding and carbonization.
以自烧结性中间相沥青炭微球 (MCMB)为基体 ,以沥青基磨碎炭纤维为增强体 ,采用简单的氧化处理、混合、热压成型、炭化等工艺一步制备C/C复合材料。
2.
High density isotropic carbon cakes were obtained from mesocarbon microbeads with variousβ resin content by heat pressure molding and carbonization at 1000℃ for 1 h.
以不同β树脂含量的中间相沥青炭微球(Mesocarbon microbeads,MCMBs)为原料制备高密度各向同性炭块。
3.
In this paper the status and development of mesocarbon microbeads are reviewed.
介绍中间相沥青炭微球的制备方法和发展现状,分析了其在锂离子二次电池等方面的应用及国内外市场前景。
补充资料:可降解淀粉微球和生物降解白蛋白微球阻滞法
可降解淀粉微球和生物降解白蛋白微球阻滞法
介入放射学技术。介入性局部化疗之前,把二者注入靶动脉,可暂时减少动脉血流,再行化疗药物灌注,以减少血液冲刷,保持局部化疗药物浓度的技术。与其他中期和长期栓塞微球不同,DSM和BAM仅造成数十分钟的血流量减少,待其被降解后血流可恢复至以前水平。
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参考词条