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A Brief Overview of the Microstructural Engineering of Inorganic–Organic Composite Membranes Derived from Organic Chelating Ligands

Membranes

2023-03-30 | Journal article

DOI: 10.3390/membranes13040390

Contributors: Sulaiman Oladipo Lawal; Masakoto Kanezashi

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Design of carbon–ceramic composite membranes with tunable molecular cut-offs from a carboxylic benzoxazine ligand chelated to silica–zirconia

Molecular Systems Design & Engineering

2022 | Journal article

DOI: 10.1039/D2ME00078D

Contributors: Sulaiman Oladipo Lawal; Hiroki Nagasawa; Toshinori Tsuru; Masakoto Kanezashi

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Enhancement of the H<sub>2</sub>-permselectivity of a silica-zirconia composite membrane enabled by ligand-ceramic to carbon-ceramic transformation

Journal of Membrane Science

2022 | Journal article

DOI: 10.1016/j.memsci.2021.119948

EID:

2-s2.0-85116599257

Part of ISSN: 18733123 03767388

Contributors: Lawal, S.O.; Nagasawa, H.; Tsuru, T.; Kanezashi, M.

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Sulaiman Lawal via Scopus - Elsevier

Facile development of microstructure-engineered, ligand-chelated SiO2–ZrO2 composite membranes for molecular separations

Molecular Systems Design & Engineering

2021 | Journal article

DOI: 10.1039/D1ME00011J

Contributors: Sulaiman O. Lawal; Hiroki Nagasawa; Toshinori Tsuru; Masakoto Kanezashi

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A carbon–silica–zirconia ceramic membrane with CO2 flow-switching behaviour promising versatile high-temperature H2/CO2 separation

Journal of Materials Chemistry A

2020 | Journal article

DOI: 10.1039/D0TA07065C

Contributors: Sulaiman Oladipo Lawal; Liang Yu; Hiroki Nagasawa; Toshinori Tsuru; Masakoto Kanezashi

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Development of an acetylacetonate-modified silica-zirconia composite membrane applicable to gas separation

Journal of Membrane Science

2020 | Journal article

DOI: 10.1016/j.memsci.2020.117844

EID:

2-s2.0-85078160843

Part of ISSN: 18733123 03767388

Contributors: Lawal, S.; Kanezashi, M.; Nagasawa, H.; Tsuru, T.

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Sulaiman Lawal via Scopus - Elsevier

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https://orcid.org/0000-0001-5837-0889

Activities

Works (6)

A Brief Overview of the Microstructural Engineering of Inorganic–Organic Composite Membranes Derived from Organic Chelating Ligands

Design of carbon–ceramic composite membranes with tunable molecular cut-offs from a carboxylic benzoxazine ligand chelated to silica–zirconia

Enhancement of the H<sub>2</sub>-permselectivity of a silica-zirconia composite membrane enabled by ligand-ceramic to carbon-ceramic transformation

Facile development of microstructure-engineered, ligand-chelated SiO2–ZrO2 composite membranes for molecular separations

A carbon–silica–zirconia ceramic membrane with CO2 flow-switching behaviour promising versatile high-temperature H2/CO2 separation

Development of an acetylacetonate-modified silica-zirconia composite membrane applicable to gas separation

https://orcid.org/0000-0001-5837-0889

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Activities

Works (6)

A Brief Overview of the Microstructural Engineering of Inorganic–Organic Composite Membranes Derived from Organic Chelating Ligands

Design of carbon–ceramic composite membranes with tunable molecular cut-offs from a carboxylic benzoxazine ligand chelated to silica–zirconia

Enhancement of the H<sub>2</sub>-permselectivity of a silica-zirconia composite membrane enabled by ligand-ceramic to carbon-ceramic transformation

Facile development of microstructure-engineered, ligand-chelated SiO2–ZrO2 composite membranes for molecular separations

A carbon–silica–zirconia ceramic membrane with CO2 flow-switching behaviour promising versatile high-temperature H2/CO2 separation

Development of an acetylacetonate-modified silica-zirconia composite membrane applicable to gas separation