Direct conversion of natural gases in solid oxide cells: A mini-review

Direct conversion of natural gases in solid oxide cells: A mini-review

The direct one-step electrochemical conversion of natural gas is an attractive and economic approach to the synthesis of the higher value-added alkenes with co-product hydrogen or hydrocarbons, which is enabled by the combination of solid oxide cells (SOCs) and catalysts. Compared to traditional che...

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Bibliographic Details
Main Authors: Peng-Xi Zhu, Lu-Cun Wang, Frederick Stewart, Dong Ding, John Matz, Pei Dong, Hanping Ding
Format: Article
Language:English
Published: Elsevier 2021-07-01
Series:Electrochemistry Communications
Subjects:
Electrochemical conversion
Alkene synthesis
Methane
Solid oxide cell
Benzene
Online Access:http://www.sciencedirect.com/science/article/pii/S1388248121001521
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spelling doaj-d167aad9e9764700ac03407280fd33ba2021-06-25T04:46:56ZengElsevierElectrochemistry Communications1388-24812021-07-01128107068Direct conversion of natural gases in solid oxide cells: A mini-reviewPeng-Xi Zhu0Lu-Cun Wang1Frederick Stewart2Dong Ding3John Matz4Pei Dong5Hanping Ding6Idaho National Laboratory, Idaho Falls, ID 83415, USA; Department of Mechanical Engineering, George Mason University, Fairfax, VA 22030, USAIdaho National Laboratory, Idaho Falls, ID 83415, USAIdaho National Laboratory, Idaho Falls, ID 83415, USAIdaho National Laboratory, Idaho Falls, ID 83415, USADepartment of Mechanical Engineering, George Mason University, Fairfax, VA 22030, USADepartment of Mechanical Engineering, George Mason University, Fairfax, VA 22030, USA; Corresponding authors.Idaho National Laboratory, Idaho Falls, ID 83415, USA; Corresponding authors.The direct one-step electrochemical conversion of natural gas is an attractive and economic approach to the synthesis of the higher value-added alkenes with co-product hydrogen or hydrocarbons, which is enabled by the combination of solid oxide cells (SOCs) and catalysts. Compared to traditional chemical alkene synthesis, the integration of SOC as a membrane reactor can overcome the thermodynamic equilibrium limit by applying electrochemical current to effectively mitigate coke formation. In this scheme, the dehydrogenation reaction supplies protons from natural gas hydrocarbons for use in CO2 reduction, electricity generation, and hydrogen production. The main approaches for natural gas direct conversion have been reviewed to understand the current technology development status including catalysts and SOC system integration.http://www.sciencedirect.com/science/article/pii/S1388248121001521Electrochemical conversionAlkene synthesisMethaneSolid oxide cellBenzene
collection DOAJ
language English
format Article
sources DOAJ
author Peng-Xi Zhu
Lu-Cun Wang
Frederick Stewart
Dong Ding
John Matz
Pei Dong
Hanping Ding
spellingShingle Peng-Xi Zhu
Lu-Cun Wang
Frederick Stewart
Dong Ding
John Matz
Pei Dong
Hanping Ding
Direct conversion of natural gases in solid oxide cells: A mini-review
Electrochemistry Communications
Electrochemical conversion
Alkene synthesis
Methane
Solid oxide cell
Benzene
author_facet Peng-Xi Zhu
Lu-Cun Wang
Frederick Stewart
Dong Ding
John Matz
Pei Dong
Hanping Ding
author_sort Peng-Xi Zhu
title Direct conversion of natural gases in solid oxide cells: A mini-review
title_short Direct conversion of natural gases in solid oxide cells: A mini-review
title_full Direct conversion of natural gases in solid oxide cells: A mini-review
title_fullStr Direct conversion of natural gases in solid oxide cells: A mini-review
title_full_unstemmed Direct conversion of natural gases in solid oxide cells: A mini-review
title_sort direct conversion of natural gases in solid oxide cells: a mini-review
publisher Elsevier
series Electrochemistry Communications
issn 1388-2481
publishDate 2021-07-01
description The direct one-step electrochemical conversion of natural gas is an attractive and economic approach to the synthesis of the higher value-added alkenes with co-product hydrogen or hydrocarbons, which is enabled by the combination of solid oxide cells (SOCs) and catalysts. Compared to traditional chemical alkene synthesis, the integration of SOC as a membrane reactor can overcome the thermodynamic equilibrium limit by applying electrochemical current to effectively mitigate coke formation. In this scheme, the dehydrogenation reaction supplies protons from natural gas hydrocarbons for use in CO2 reduction, electricity generation, and hydrogen production. The main approaches for natural gas direct conversion have been reviewed to understand the current technology development status including catalysts and SOC system integration.
topic Electrochemical conversion
Alkene synthesis
Methane
Solid oxide cell
Benzene
url http://www.sciencedirect.com/science/article/pii/S1388248121001521
work_keys_str_mv AT pengxizhu directconversionofnaturalgasesinsolidoxidecellsaminireview
AT lucunwang directconversionofnaturalgasesinsolidoxidecellsaminireview
AT frederickstewart directconversionofnaturalgasesinsolidoxidecellsaminireview
AT dongding directconversionofnaturalgasesinsolidoxidecellsaminireview
AT johnmatz directconversionofnaturalgasesinsolidoxidecellsaminireview
AT peidong directconversionofnaturalgasesinsolidoxidecellsaminireview
AT hanpingding directconversionofnaturalgasesinsolidoxidecellsaminireview
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