Nanocarbon materials synthesized by solution plasma process for their catalytic activity

机译：溶液等离子体合成纳米碳材料的催化活性

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Nanocarbon materials were successfully synthesized from various organic solvents by Solution Plasma Process (SPP) at room temperature and atmospheric pressure. SPP was generated between two tungsten electrodes using a bipolar pulsed power supply at high frequencies 50, 100 and 150 kHz and 0.5 μs pulse width for 30 min. The plasma conditions influence the properties and structure of the synthesized nanocarbon materials. The synthesis rates were 48.8 (benzene), 14.5 (aniline), and 13 (nitro-benzene) mg.min~(-1) at 150 kHz frequency. The amount of nanocarbon increased when the plasma energy increased. The nanocarbon materials were characterized by X-ray powder diffraction (XRD), X-ray photoelectron spectroscopy (XPS), Raman spectroscopy, transmission electron microscopy (TEM). The properties of nanocarbon materials were evaluated by electrical conductivity, catalytic activity.

机译：在室温和大气压下，通过溶液等离子体工艺（SPP）从各种有机溶剂成功合成了纳米碳材料。使用双极脉冲电源在高频50、100和150 kHz以及0.5μs的脉冲宽度下持续30分钟，在两个钨电极之间生成SPP。等离子体条件影响合成的纳米碳材料的性质和结构。在150 kHz频率下，合成速率为48.8（苯），14.5（苯胺）和13（硝基苯）mg.min〜（-1）。当等离子体能量增加时，纳米碳的量增加。纳米碳材料通过X射线粉末衍射（XRD），X射线光电子能谱（XPS），拉曼光谱，透射电子显微镜（TEM）进行了表征。纳米碳材料的性能通过电导率，催化活性进行评估。

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《2018年第79回応用物理学会秋季学術講演会講演予稿集》|2018年|15.042|共1页
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Md. Zahidul Islam; Maria Antoaneta Bratescu; Nagahiro Saito;
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Nanocarbon materials synthesized by solution plasma process for their catalytic activity

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