Heterostructuring Mesoporous 2D Iridium Nanosheets with Amorphous Nickel Boron Oxide Layers to Improve Electrolytic Water Splitting

Yunqing Kang; Bo Jiang; Victor Malgras; Yanna Guo; Ovidiu Cretu; Koji Kimoto; Aditya Ashok; Zhe Wan; Hexing Li; Yoshiyuki Sugahara; Yusuke Yamauchi; Toru Asahi

doi:10.1002/smtd.202100679

Heterostructuring Mesoporous 2D Iridium Nanosheets with Amorphous Nickel Boron Oxide Layers to Improve Electrolytic Water Splitting

Yunqing Kang, Bo Jiang^*, Victor Malgras^*, Yanna Guo, Ovidiu Cretu, Koji Kimoto, Aditya Ashok, Zhe Wan, Hexing Li, Yoshiyuki Sugahara, Yusuke Yamauchi, Toru Asahi^*

^*この研究の対応する著者

研究成果: Article › 査読

36 被引用数 (Scopus)

抄録

2D heterostructures exhibit a considerable potential in electrolytic water splitting due to their high specific surface areas, tunable electronic properties, and diverse hybrid compositions. However, the fabrication of well-defined 2D mesoporous amorphous-crystalline heterostructures with highly active heterointerfaces remains challenging. Herein, an efficient 2D heterostructure consisting of amorphous nickel boron oxide (Ni-B_i) and crystalline mesoporous iridium (meso-Ir) is designed for water splitting, referred to as Ni-B_i/meso-Ir. Benefiting from well-defined 2D heterostructures and strong interfacial coupling, the resulting mesoporous dual-phase Ni-B_i/meso-Ir possesses abundant catalytically active heterointerfaces and boosts the exposure of active sites, compared to their crystalline and amorphous mono-counterparts. The electronic state of the iridium sites is tuned favorably by hybridizing with Ni-B_i layers. Consequently, the Ni-B_i/meso-Ir heterostructures show superior and stable electrochemical performance toward both oxygen evolution reaction (OER) and hydrogen evolution reaction (HER) in an alkaline electrolyte.

本文言語	English
論文番号	2100679
ジャーナル	Small Methods
巻	5
号	10
DOI	https://doi.org/10.1002/smtd.202100679
出版ステータス	Published - 2021 10月 13

ASJC Scopus subject areas

化学 (全般)
材料科学（全般）

UN SDG

この成果は、次の持続可能な開発目標に貢献しています

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10.1002/smtd.202100679

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引用スタイル

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AU - Malgras, Victor

AU - Guo, Yanna

AU - Cretu, Ovidiu

AU - Kimoto, Koji

AU - Ashok, Aditya

AU - Wan, Zhe

AU - Li, Hexing

AU - Sugahara, Yoshiyuki

AU - Yamauchi, Yusuke

AU - Asahi, Toru

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N2 - 2D heterostructures exhibit a considerable potential in electrolytic water splitting due to their high specific surface areas, tunable electronic properties, and diverse hybrid compositions. However, the fabrication of well-defined 2D mesoporous amorphous-crystalline heterostructures with highly active heterointerfaces remains challenging. Herein, an efficient 2D heterostructure consisting of amorphous nickel boron oxide (Ni-Bi) and crystalline mesoporous iridium (meso-Ir) is designed for water splitting, referred to as Ni-Bi/meso-Ir. Benefiting from well-defined 2D heterostructures and strong interfacial coupling, the resulting mesoporous dual-phase Ni-Bi/meso-Ir possesses abundant catalytically active heterointerfaces and boosts the exposure of active sites, compared to their crystalline and amorphous mono-counterparts. The electronic state of the iridium sites is tuned favorably by hybridizing with Ni-Bi layers. Consequently, the Ni-Bi/meso-Ir heterostructures show superior and stable electrochemical performance toward both oxygen evolution reaction (OER) and hydrogen evolution reaction (HER) in an alkaline electrolyte.

AB - 2D heterostructures exhibit a considerable potential in electrolytic water splitting due to their high specific surface areas, tunable electronic properties, and diverse hybrid compositions. However, the fabrication of well-defined 2D mesoporous amorphous-crystalline heterostructures with highly active heterointerfaces remains challenging. Herein, an efficient 2D heterostructure consisting of amorphous nickel boron oxide (Ni-Bi) and crystalline mesoporous iridium (meso-Ir) is designed for water splitting, referred to as Ni-Bi/meso-Ir. Benefiting from well-defined 2D heterostructures and strong interfacial coupling, the resulting mesoporous dual-phase Ni-Bi/meso-Ir possesses abundant catalytically active heterointerfaces and boosts the exposure of active sites, compared to their crystalline and amorphous mono-counterparts. The electronic state of the iridium sites is tuned favorably by hybridizing with Ni-Bi layers. Consequently, the Ni-Bi/meso-Ir heterostructures show superior and stable electrochemical performance toward both oxygen evolution reaction (OER) and hydrogen evolution reaction (HER) in an alkaline electrolyte.

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