在气泡塔中使用熔融锡镍合金作为催化剂生产多层石墨烯

IF 5.5 3区材料科学 Q2 CHEMISTRY, MULTIDISCIPLINARY

Carbon Letters Pub Date : 2024-07-22 DOI:10.1007/s42823-024-00776-4

Yangdong He, Shaomu Wen, Wei Yang, Changcang Qiao, Ming Xie, Li Chen, Xinqi Yang, Yongliang Tang

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引用次数: 0

摘要

如何经济地制造高质量石墨烯一直是石墨烯大规模应用的重大挑战。此前，我们使用熔融锡和铜作为热传导剂，在气泡塔中的气泡表面制备多层石墨烯。然而，Sn 和 Cu 元素对甲烷热解的催化活性较差。为了进一步提高石墨烯的产量，我们在锡中加入了活性镍，从而构建了锡镍合金。结果表明，Sn-Ni 合金对甲烷热解的活性更高，因此能获得更多的石墨烯。不过，由于生长速度更快，石墨烯产品的缺陷更多，厚度更大。使用 300 毫升熔融 Sn-Ni 合金（70 毫米高）和 500 sccm 源气（CH4:Ar = 1:9），在 1250 ℃ 和环境压力下，石墨烯的生产率为 0.61 克/小时，甲烷到碳的转化率为 37.9%。生成的石墨烯平均原子层数为 22，具有皱缩结构和良好的导电性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Production of multilayer graphene using molten Sn–Ni alloy as catalyst in a bubble column

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Production of multilayer graphene using molten Sn–Ni alloy as catalyst in a bubble column

The economical manufacturing of high-quality graphene has been a significant challenge in its large-scale application. Previously, we used molten Sn and Cu as the heat-transfer agent to produce multilayer graphene on the surface of gas bubbles in a bubble column. However, element Sn and Cu have poor catalytic activity toward methane pyrolysis. To further improve the yield of graphene, we have added active Ni into Sn to construct a Sn–Ni alloy in this work. The results show that Sn–Ni alloy is much more active for methane pyrolysis, and thus more graphene is obtained. However, the graphene product is more defective and thicker because of the faster growth rate. By using 300 ml molten Sn–Ni alloy (70 mm height) and 500 sccm source gas (CH₄:Ar = 1:9), this approach produces graphene with a rate of 0.61 g/hr and a conversion rate of methane to carbon of 37.9% at 1250 ℃ and ambient pressure. The resulting graphene has an average atom layer number of 22, a crumpled structure and good electrical conductivity.

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来源期刊

Carbon Letters CHEMISTRY, MULTIDISCIPLINARY-MATERIALS SCIENCE, MULTIDISCIPLINARY

CiteScore

7.30

自引率

20.00%

发文量

118

期刊介绍： Carbon Letters aims to be a comprehensive journal with complete coverage of carbon materials and carbon-rich molecules. These materials range from, but are not limited to, diamond and graphite through chars, semicokes, mesophase substances, carbon fibers, carbon nanotubes, graphenes, carbon blacks, activated carbons, pyrolytic carbons, glass-like carbons, etc. Papers on the secondary production of new carbon and composite materials from the above mentioned various carbons are within the scope of the journal. Papers on organic substances, including coals, will be considered only if the research has close relation to the resulting carbon materials. Carbon Letters also seeks to keep abreast of new developments in their specialist fields and to unite in finding alternative energy solutions to current issues such as the greenhouse effect and the depletion of the ozone layer. The renewable energy basics, energy storage and conversion, solar energy, wind energy, water energy, nuclear energy, biomass energy, hydrogen production technology, and other clean energy technologies are also within the scope of the journal. Carbon Letters invites original reports of fundamental research in all branches of the theory and practice of carbon science and technology.