Enhancing H2 production from plasma-assisted methanol steam reforming by catalyst engineering in a MXene membrane reactor

Shaowei Chen; Zong Lu; Jiangqi Niu; Yan Shao; Yi Chen; Yaru Ni; Xiaoying Liu; Xiaoyang Wei; Xiaoxia Ou; Xiaolei Fan; Yanying Wei; Huanhao Chen

doi:10.1002/aic.18685

Enhancing H₂ production from plasma-assisted methanol steam reforming by catalyst engineering in a MXene membrane reactor

Shaowei Chen, Zong Lu, Jiangqi Niu, Yan Shao, Yi Chen, Yaru Ni, Xiaoying Liu, Xiaoyang Wei, Xiaoxia Ou, Xiaolei Fan, Yanying Wei, Huanhao Chen

材料科学与工程学院

科研成果: 期刊稿件 › 文章 › 同行评审

摘要

Electrified methanol steam reforming (MSR) assisted by nonthermal plasma (NTP) is a pivotal enabler for clean hydrogen production at ambient conditions with several advantages. This study optimizes the NTP-assisted MSR by catalyst engineering, as well as membrane technology (via a 2D MXene nanosheet membrane reactor). Our findings reveal that active-phase engineering in catalyst design is crucial in regulating MSR pathways under NTP conditions with the bimetallic Ni–Cu alloys enhancing the H₂ production via surface water–gas shift reaction (WGSR). Additionally, integrating a MXene membrane within a dielectric barrier discharge (DBD) NTP reactor enabled the reactive-separation process, improving methanol conversion, H₂ formation rate with higher purity, as well as showing a good stability.

源语言	英语
文章编号	e18685
期刊	AIChE Journal
卷	71
期	3
DOI	https://doi.org/10.1002/aic.18685
出版状态	已出版 - 3月 2025

联合国可持续发展目标

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10.1002/aic.18685

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引用此

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title = "Enhancing H2 production from plasma-assisted methanol steam reforming by catalyst engineering in a MXene membrane reactor",

abstract = "Electrified methanol steam reforming (MSR) assisted by nonthermal plasma (NTP) is a pivotal enabler for clean hydrogen production at ambient conditions with several advantages. This study optimizes the NTP-assisted MSR by catalyst engineering, as well as membrane technology (via a 2D MXene nanosheet membrane reactor). Our findings reveal that active-phase engineering in catalyst design is crucial in regulating MSR pathways under NTP conditions with the bimetallic Ni–Cu alloys enhancing the H2 production via surface water–gas shift reaction (WGSR). Additionally, integrating a MXene membrane within a dielectric barrier discharge (DBD) NTP reactor enabled the reactive-separation process, improving methanol conversion, H2 formation rate with higher purity, as well as showing a good stability.",

keywords = "MXene membrane, hydrogen (H) production, methanol steam reforming (MSR), nonthermal plasma (NTP) catalysis, process integration",

author = "Shaowei Chen and Zong Lu and Jiangqi Niu and Yan Shao and Yi Chen and Yaru Ni and Xiaoying Liu and Xiaoyang Wei and Xiaoxia Ou and Xiaolei Fan and Yanying Wei and Huanhao Chen",

note = "Publisher Copyright: {\textcopyright} 2024 American Institute of Chemical Engineers.",

year = "2025",

month = mar,

doi = "10.1002/aic.18685",

language = "英语",

volume = "71",

journal = "AIChE Journal",

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TY - JOUR

T1 - Enhancing H2 production from plasma-assisted methanol steam reforming by catalyst engineering in a MXene membrane reactor

AU - Chen, Shaowei

AU - Lu, Zong

AU - Niu, Jiangqi

AU - Shao, Yan

AU - Chen, Yi

AU - Ni, Yaru

AU - Liu, Xiaoying

AU - Wei, Xiaoyang

AU - Ou, Xiaoxia

AU - Fan, Xiaolei

AU - Wei, Yanying

AU - Chen, Huanhao

PY - 2025/3

Y1 - 2025/3

N2 - Electrified methanol steam reforming (MSR) assisted by nonthermal plasma (NTP) is a pivotal enabler for clean hydrogen production at ambient conditions with several advantages. This study optimizes the NTP-assisted MSR by catalyst engineering, as well as membrane technology (via a 2D MXene nanosheet membrane reactor). Our findings reveal that active-phase engineering in catalyst design is crucial in regulating MSR pathways under NTP conditions with the bimetallic Ni–Cu alloys enhancing the H2 production via surface water–gas shift reaction (WGSR). Additionally, integrating a MXene membrane within a dielectric barrier discharge (DBD) NTP reactor enabled the reactive-separation process, improving methanol conversion, H2 formation rate with higher purity, as well as showing a good stability.

AB - Electrified methanol steam reforming (MSR) assisted by nonthermal plasma (NTP) is a pivotal enabler for clean hydrogen production at ambient conditions with several advantages. This study optimizes the NTP-assisted MSR by catalyst engineering, as well as membrane technology (via a 2D MXene nanosheet membrane reactor). Our findings reveal that active-phase engineering in catalyst design is crucial in regulating MSR pathways under NTP conditions with the bimetallic Ni–Cu alloys enhancing the H2 production via surface water–gas shift reaction (WGSR). Additionally, integrating a MXene membrane within a dielectric barrier discharge (DBD) NTP reactor enabled the reactive-separation process, improving methanol conversion, H2 formation rate with higher purity, as well as showing a good stability.

KW - MXene membrane

KW - hydrogen (H) production

KW - methanol steam reforming (MSR)

KW - nonthermal plasma (NTP) catalysis

KW - process integration

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U2 - 10.1002/aic.18685

DO - 10.1002/aic.18685

M3 - 文章

AN - SCOPUS:85212042264

SN - 0001-1541

VL - 71

JO - AIChE Journal

JF - AIChE Journal

IS - 3

M1 - e18685

ER -

Enhancing H2 production from plasma-assisted methanol steam reforming by catalyst engineering in a MXene membrane reactor

摘要

联合国可持续发展目标

访问文件

其它文件与链接

指纹

引用此

Enhancing H₂ production from plasma-assisted methanol steam reforming by catalyst engineering in a MXene membrane reactor