Design of NiFe‐based nanostructures for efficient oxygen evolution electrocatalysis

Shi, Yue; Zhang, Dan; Miao, Hongfu; Zhan, Tianrong; Lai, Jianping

doi:10.1002/elsa.202100052

“…30 Efficient OER involves several features including cationic promotion, anion adjustment, defect sites, and ultrathin structures. 31 Extraordinarily activating OER with maximized electrocatalytic activity, individual NiSACs bond to oxygen sites on graphene-like carbon with superior activity and OER stability in Ni atom coordinating to oxygen as active sites. 32 Single Ni sites are favorable for promoting structural reconstruction into either dual metal sites or bridging with O atoms such as Ni–O–Fe bonds which creates spin channels for electron transfer.…”

Section: Introductionmentioning

confidence: 99%

Elevated temperature-driven coordinative reconstruction of an unsaturated single-Ni-atom structure with low valency on a polymer-derived matrix for the electrolytic oxygen evolution reaction

Patil,

Rajput,

Matsagar

et al. 2024

Nanoscale

1

0

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Alloying‐Triggered Phase Engineering of NiFe System via Laser‐Assisted Al Incorporation for Full Water Splitting

Liu

¹

,

Lu

²

,

Zhu

³

et al. 2023

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It is challenging to design one non-noble material with balanced bifunctional performance for hydrogen evolution reaction (HER) and oxygen evolution reaction (OER) for commercial sustainability at a low cost since the different electrocatalytic mechanisms are not easily matchable for each other. Herein, a self-standing hybrid system Ni 18 Fe 12 Al 70 , consisting of Ni 2 Al 3 and Ni 3 Fe phases, was constructed by laser-assisted aluminum (Al) incorporation towards full water splitting. It was found that the incorporation of Al could effectively tune the morphologies, compositions and phases. The results indicate that Ni 18 Fe 12 Al 70 delivers an extremely low overpotential to trigger both HER (η 100 = 188 mV) and OER (η 100 = 345 mV) processes and maintains a stable overpotential for 100 h, comparable to state-of-the-art electrocatalysts. The synergistic effect of Ni 2 Al 3 and Ni 3 Fe alloys on the HER process is confirmed based on theoretical calculation.

show abstract

Alloying‐Triggered Phase Engineering of NiFe System via Laser‐Assisted Al Incorporation for Full Water Splitting

Liu

¹

,

Lu

²

,

Zhu

³

et al. 2023

View full text Add to dashboard Cite

It is challenging to design one non-noble material with balanced bifunctional performance for hydrogen evolution reaction (HER) and oxygen evolution reaction (OER) for commercial sustainability at a low cost since the different electrocatalytic mechanisms are not easily matchable for each other. Herein, a self-standing hybrid system Ni 18 Fe 12 Al 70 , consisting of Ni 2 Al 3 and Ni 3 Fe phases, was constructed by laser-assisted aluminum (Al) incorporation towards full water splitting. It was found that the incorporation of Al could effectively tune the morphologies, compositions and phases. The results indicate that Ni 18 Fe 12 Al 70 delivers an extremely low overpotential to trigger both HER (η 100 = 188 mV) and OER (η 100 = 345 mV) processes and maintains a stable overpotential for 100 h, comparable to state-of-the-art electrocatalysts. The synergistic effect of Ni 2 Al 3 and Ni 3 Fe alloys on the HER process is confirmed based on theoretical calculation.

show abstract

Design of NiFe‐based nanostructures for efficient oxygen evolution electrocatalysis

Cited by 3 publications

References 103 publications

Elevated temperature-driven coordinative reconstruction of an unsaturated single-Ni-atom structure with low valency on a polymer-derived matrix for the electrolytic oxygen evolution reaction

Elevated temperature-driven coordinative reconstruction of an unsaturated single-Ni-atom structure with low valency on a polymer-derived matrix for the electrolytic oxygen evolution reaction

Alloying‐Triggered Phase Engineering of NiFe System via Laser‐Assisted Al Incorporation for Full Water Splitting

Alloying‐Triggered Phase Engineering of NiFe System via Laser‐Assisted Al Incorporation for Full Water Splitting

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