Cobalt phosphide with porous multishelled hollow structure design realizing promoted ammonia borane dehydrogenation: Elucidating roles of architectural and electronic effect

Cobalt phosphide with porous multishelled hollow structure design realizing promoted ammonia borane dehydrogenation: Elucidating roles of architectural and electronic effect

Exploring advanced non-noble metal-based catalysts for H2 release from chemical hydrogen storage materials is of paramount importance to boost hydrogen economy. Rationally tailoring over architecture and electronic state promises high-efficiency catalysis. Herein we present, for the first time, deli...

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Veröffentlicht in:Applied catalysis. B, Environmental Environmental, 2022-09, Vol.313, p.121444, Article 121444
Hauptverfasser: Li, Ping, Huang, Yuqi, Huang, Quhua, Chen, Ran, Li, Jixin, Tian, Shuanghong
Format: Artikel
Sprache:eng
Schlagworte:
Ammonia
Ammonia borane dehydrogenation
Boranes
Catalysis
Catalysts
Cobalt
d-band center
Dehydrogenation
Electron states
Electronic effect
Electronic structure
Hydrogen storage materials
Hydrogen-based energy
Mass transfer
Multishelled hollow structure
Noble metals
Phosphides
System effectiveness
Transition metal phosphide
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container_issue
container_start_page 121444
container_title Applied catalysis. B, Environmental
container_volume 313
creator Li, Ping
Huang, Yuqi
Huang, Quhua
Chen, Ran
Li, Jixin
Tian, Shuanghong
description Exploring advanced non-noble metal-based catalysts for H2 release from chemical hydrogen storage materials is of paramount importance to boost hydrogen economy. Rationally tailoring over architecture and electronic state promises high-efficiency catalysis. Herein we present, for the first time, delicate engineer of cobalt phosphide with a unique porous, multishelled, and hollow architecture (multishelled Co-P) for dramatically promoting ammonia borane (AB) dehydrogenation. Featuring hollow porous structure and complex nanoconfined interior space, multishelled Co-P possesses abundant accessible active sites and facile mass transfer. Importantly, theoretical calculations decipher that P incorporation in Co-P can modulate electronic structure of Co sites to give promoted H2O adsorption and favorable H2O dissociation kinetics (rate-determining step), thereby facilitating AB dehydrogenation. This study provides a fundamental understanding of correlation between electronic state of Co-P and AB dehydrogenation behavior, and highlights that decent architectural engineering coupled with electronic modulation is an effective protocol to construct advanced catalytic systems. [Display omitted] •Co-P featuring porous, multishelled, and hollow architecture is engineered to promote AB dehydrogenation for the first time.•Multishelled Co-P is achieved from Co-MOC through self-templating conversion followed by phosphidation treatment.•P incorporation in Co-P can modulate electronic state of Co sites with upshift of the d-band center.•Electronic modulation of Co-P results to boosted H2O adsorption and favorable H2O dissociation kinetics.
doi_str_mv 10.1016/j.apcatb.2022.121444
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Rationally tailoring over architecture and electronic state promises high-efficiency catalysis. Herein we present, for the first time, delicate engineer of cobalt phosphide with a unique porous, multishelled, and hollow architecture (multishelled Co-P) for dramatically promoting ammonia borane (AB) dehydrogenation. Featuring hollow porous structure and complex nanoconfined interior space, multishelled Co-P possesses abundant accessible active sites and facile mass transfer. Importantly, theoretical calculations decipher that P incorporation in Co-P can modulate electronic structure of Co sites to give promoted H2O adsorption and favorable H2O dissociation kinetics (rate-determining step), thereby facilitating AB dehydrogenation. This study provides a fundamental understanding of correlation between electronic state of Co-P and AB dehydrogenation behavior, and highlights that decent architectural engineering coupled with electronic modulation is an effective protocol to construct advanced catalytic systems. [Display omitted] •Co-P featuring porous, multishelled, and hollow architecture is engineered to promote AB dehydrogenation for the first time.•Multishelled Co-P is achieved from Co-MOC through self-templating conversion followed by phosphidation treatment.•P incorporation in Co-P can modulate electronic state of Co sites with upshift of the d-band center.•Electronic modulation of Co-P results to boosted H2O adsorption and favorable H2O dissociation kinetics.</description><identifier>ISSN: 0926-3373</identifier><identifier>EISSN: 1873-3883</identifier><identifier>DOI: 10.1016/j.apcatb.2022.121444</identifier><language>eng</language><publisher>Amsterdam: Elsevier B.V</publisher><subject>Ammonia ; Ammonia borane dehydrogenation ; Boranes ; Catalysis ; Catalysts ; Cobalt ; d-band center ; Dehydrogenation ; Electron states ; Electronic effect ; Electronic structure ; Hydrogen storage materials ; Hydrogen-based energy ; Mass transfer ; Multishelled hollow structure ; Noble metals ; Phosphides ; System effectiveness ; Transition metal phosphide</subject><ispartof>Applied catalysis. 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This study provides a fundamental understanding of correlation between electronic state of Co-P and AB dehydrogenation behavior, and highlights that decent architectural engineering coupled with electronic modulation is an effective protocol to construct advanced catalytic systems. 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subjects Ammonia
Ammonia borane dehydrogenation
Boranes
Catalysis
Catalysts
Cobalt
d-band center
Dehydrogenation
Electron states
Electronic effect
Electronic structure
Hydrogen storage materials
Hydrogen-based energy
Mass transfer
Multishelled hollow structure
Noble metals
Phosphides
System effectiveness
Transition metal phosphide
title Cobalt phosphide with porous multishelled hollow structure design realizing promoted ammonia borane dehydrogenation: Elucidating roles of architectural and electronic effect
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