Novel Method for Preparing a Carbon Nanotube-Supported Cobalt Catalyst for Fischer–Tropsch Synthesis:Hydrogen Dielectric-Barrier Discharge Plasma

被引：0

作者：

Zhenhua Li

Runxue Liu

Renjie Liu

Weihan Wang

Jing Lv

机构：

[1] KeyLabforGreenChemicalTechnologyofMinistryofEducation,SchoolofChemicalEngineeringandTechnology,CollaborativeInnovationCenterofChemicalScienceandEngineering(Tianjin),TianjinUniversity

来源：

Transactions of Tianjin University | 2017年 / 01期

关键词：

Fischer–Tropsch synthesis; H2 dielectricbarrier discharge; Plasma; Cobalt; Carbon nanotubes;

D O I：

暂无

中图分类号：

O643.36 [催化剂];

学科分类号：

081705 ;

摘要：

Hydrogen dielectric-barrier discharge（H2-DBD）plasma was successfully used to prepare carbon nanotubes（CNTs）-supported cobalt（Co） catalyst.The H2-DBD plasma treatment simultaneously decomposed and reduced the cobalt precursor at a lower temperature and in a shorter time than the conventional method（calcination and hydrogen reduction）.It is considered that the H2-DBD plasma method can remarkably decrease the amount of energy input compared to traditional methods used to prepare the Co-based catalyst in Fischer-Tropsch synthesis（FTS）.Results showed that the Co catalyst prepared by H2-DBD plasma had an equivalent catalytic performance for FTS as that prepared using the conventional method in calcination and hydrogen reduction,thereby determining that H2-DBD plasma was an effective alternative treatment for preparing the Co/CNTs catalyst for FTS.This technology will provide a new strategy for preparing catalysts in other catalysis processes.

引用

页码：20 / 25

页数：6

共 23 条

[1]

Fischer-Tropsch Performance of an SiO2-Supported Co-Based Catalyst Prepared by Hydrogen Dielectric-Barrier Discharge Plasma[J]. 付廷俊,黄承都,吕静,李振花.Plasma Science and Technology. 2014(03)

[2]

Performance of Cobalt-Based Fischer-Tropsch Synthesis Catalysts Using Dielectric-Barrier Discharge Plasma as an Alternative to Thermal Calcination[J]. 白素丽,黄承都,吕静,李振花.Plasma Science and Technology. 2012(01)

[3]

Enhancement of cobalt catalyst stability in Fischer–Tropsch synthesis using graphene nanosheets as catalyst support[J] . Saba Karimi,Ahmad Tavasoli,Yadollah Mortazavi,Ali Karimi.Chemical Engineering Research and Design . 2015

[4]

Characterization of Ru/Q10 catalysts containing Zr or Mn and their activity for Fischer–Tropsch synthesis[J] . Mohammad Nurunnabi,Scott Q. Turn.Fuel Processing Technology . 2015

[5]

Review of recent development in Co-based catalysts supported on carbon materials for Fischer–Tropsch synthesis[J] . Tingjun Fu,Zhenhua Li.Chemical Engineering Science . 2015

[6]

A preliminary evaluation of ZSM-5/SBA-15 composite supported Co catalysts for Fischer–Tropsch synthesis[J] . Liyang Wu,Zhuo Li,Dezhi Han,Jinhu Wu,Dongke Zhang.Fuel Processing Technology . 2015

[7]

Mechanism of template removal for the synthesis of molecular sieves using dielectric barrier discharge[J] . Yuan Liu,Zhao Wang,Chang-jun Liu.Catalysis Today . 2015

[8]

Design of efficient Fischer Tropsch cobalt catalysts via plasma enhancement: Reducibility and performance (Review)[J] . Wei Chu,Junqiang Xu,Jingping Hong,Tao Lin,A. Khodakov.Catalysis Today . 2015

[9]

Enhanced Fischer–Tropsch synthesis performance of iron-based catalysts supported on nitric acid treated N-doped CNTs[J] . Zhenhua Li,Renjie Liu,Yan Xu,Xinbin Ma.Applied Surface Science . 2015

[10]

Fischer–Tropsch synthesis: EXAFS study of Ru and Pt bimetallic Co based catalysts[J] . C. Pirola,M. Scavini,F. Galli,S. Vitali,A. Comazzi,F. Manenti,P. Ghigna.Fuel . 2014

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