Ultrapermeable 2D-channeled graphene-wrapped zeolite molecular sieving membranes for hydrogen separation

Radovan Kukobat; Motomu Sakai; Hideki Tanaka; Hayato Otsuka; Fernando Vallejos-Burgos; Christian Lastoskie; Masahiko Matsukata; Yukichi Sasaki; Kaname Yoshida; Takuya Hayashi; Katsumi Kaneko

doi:10.1126/sciadv.abl3521

Ultrapermeable 2D-channeled graphene-wrapped zeolite molecular sieving membranes for hydrogen separation

Radovan Kukobat, Motomu Sakai, Hideki Tanaka, Hayato Otsuka, Fernando Vallejos-Burgos, Christian Lastoskie, Masahiko Matsukata, Yukichi Sasaki, Kaname Yoshida, Takuya Hayashi, Katsumi Kaneko^*

^*この研究の対応する著者

先進理工学部

研究成果: Article › 査読

8 被引用数 (Scopus)

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The efficient separation of hydrogen from methane and light hydrocarbons for clean energy applications remains a technical challenge in membrane science. To address this issue, we prepared a graphene-wrapped MFI (G-MFI) molecular-sieving membrane for the ultrafast separation of hydrogen from methane at a permeability reaching 5.8 × 10⁶ barrers at a single gas selectivity of 245 and a mixed gas selectivity of 50. Our results set an upper bound for hydrogen separation. Efficient molecular sieving comes from the subnanoscale interfacial space between graphene and zeolite crystal faces according to molecular dynamic simulations. The hierarchical pore structure of the G-MFI membrane enabled rapid permeability, indicating a promising route for the ultrafast separation of hydrogen/methane and carbon dioxide/methane in view of energy-efficient industrial gas separation.

本文言語	English
論文番号	eabl3521
ジャーナル	Science Advances
巻	8
号	20
DOI	https://doi.org/10.1126/sciadv.abl3521
出版ステータス	Published - 2022 5月

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10.1126/sciadv.abl3521

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title = "Ultrapermeable 2D-channeled graphene-wrapped zeolite molecular sieving membranes for hydrogen separation",

abstract = "The efficient separation of hydrogen from methane and light hydrocarbons for clean energy applications remains a technical challenge in membrane science. To address this issue, we prepared a graphene-wrapped MFI (G-MFI) molecular-sieving membrane for the ultrafast separation of hydrogen from methane at a permeability reaching 5.8 × 106 barrers at a single gas selectivity of 245 and a mixed gas selectivity of 50. Our results set an upper bound for hydrogen separation. Efficient molecular sieving comes from the subnanoscale interfacial space between graphene and zeolite crystal faces according to molecular dynamic simulations. The hierarchical pore structure of the G-MFI membrane enabled rapid permeability, indicating a promising route for the ultrafast separation of hydrogen/methane and carbon dioxide/methane in view of energy-efficient industrial gas separation.",

author = "Radovan Kukobat and Motomu Sakai and Hideki Tanaka and Hayato Otsuka and Fernando Vallejos-Burgos and Christian Lastoskie and Masahiko Matsukata and Yukichi Sasaki and Kaname Yoshida and Takuya Hayashi and Katsumi Kaneko",

note = "Funding Information: We are grateful to M. Yoshimune (AIST) for comments and suggestions. This work was supported by Japan Science Technology Agency (JST) CREST project “Creation of Innovative Functional Materials with Advanced Properties by Hyper-Nanospace Design”; Japan Science Technology Agency (JST) Open Innovation Platform with Enterprise, Research Institute and Academia (OPERA) (JPMJOP1722); and TAKAGI Co. Ltd. Publisher Copyright: Copyright {\textcopyright} 2022 The Authors,",

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doi = "10.1126/sciadv.abl3521",

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T1 - Ultrapermeable 2D-channeled graphene-wrapped zeolite molecular sieving membranes for hydrogen separation

AU - Kukobat, Radovan

AU - Sakai, Motomu

AU - Tanaka, Hideki

AU - Otsuka, Hayato

AU - Vallejos-Burgos, Fernando

AU - Lastoskie, Christian

AU - Matsukata, Masahiko

AU - Sasaki, Yukichi

AU - Yoshida, Kaname

AU - Hayashi, Takuya

AU - Kaneko, Katsumi

N1 - Funding Information: We are grateful to M. Yoshimune (AIST) for comments and suggestions. This work was supported by Japan Science Technology Agency (JST) CREST project “Creation of Innovative Functional Materials with Advanced Properties by Hyper-Nanospace Design”; Japan Science Technology Agency (JST) Open Innovation Platform with Enterprise, Research Institute and Academia (OPERA) (JPMJOP1722); and TAKAGI Co. Ltd. Publisher Copyright: Copyright © 2022 The Authors,

PY - 2022/5

Y1 - 2022/5

N2 - The efficient separation of hydrogen from methane and light hydrocarbons for clean energy applications remains a technical challenge in membrane science. To address this issue, we prepared a graphene-wrapped MFI (G-MFI) molecular-sieving membrane for the ultrafast separation of hydrogen from methane at a permeability reaching 5.8 × 106 barrers at a single gas selectivity of 245 and a mixed gas selectivity of 50. Our results set an upper bound for hydrogen separation. Efficient molecular sieving comes from the subnanoscale interfacial space between graphene and zeolite crystal faces according to molecular dynamic simulations. The hierarchical pore structure of the G-MFI membrane enabled rapid permeability, indicating a promising route for the ultrafast separation of hydrogen/methane and carbon dioxide/methane in view of energy-efficient industrial gas separation.

AB - The efficient separation of hydrogen from methane and light hydrocarbons for clean energy applications remains a technical challenge in membrane science. To address this issue, we prepared a graphene-wrapped MFI (G-MFI) molecular-sieving membrane for the ultrafast separation of hydrogen from methane at a permeability reaching 5.8 × 106 barrers at a single gas selectivity of 245 and a mixed gas selectivity of 50. Our results set an upper bound for hydrogen separation. Efficient molecular sieving comes from the subnanoscale interfacial space between graphene and zeolite crystal faces according to molecular dynamic simulations. The hierarchical pore structure of the G-MFI membrane enabled rapid permeability, indicating a promising route for the ultrafast separation of hydrogen/methane and carbon dioxide/methane in view of energy-efficient industrial gas separation.

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Ultrapermeable 2D-channeled graphene-wrapped zeolite molecular sieving membranes for hydrogen separation

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