Oxygen Doping to Optimize Atomic Hydrogen Binding Energy on NiCoP for Highly Efficient Hydrogen Evolution

Oxygen Doping to Optimize Atomic Hydrogen Binding Energy on NiCoP for Highly Efficient Hydrogen Evolution

An outstanding hydrogen evolution electrocatalyst should have a free energy of adsorbed atomic hydrogen of approximately zero, which enables not only a fast proton/electron‐transfer step but also rapid hydrogen release. An economic and industrially viable alternative approach for the optimization of...

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Bibliographic Details
Published in:Small (Weinheim an der Bergstrasse, Germany) Vol. 14; no. 22; pp. e1800421 - n/a
Main Authors: Liu, Chunlei, Zhang, Gong, Yu, Li, Qu, Jiuhui, Liu, Huijuan
Format: Journal Article
Language:English
Published: Germany Wiley Subscription Services, Inc 01-05-2018
Subjects:
Binding energy
Density functional theory
DFT calculations
Doping
Free energy
Hydrogen
hydrogen evolution reaction
Hydrogen evolution reactions
Hydrogen-based energy
in situ Raman
Nanotechnology
Nanowires
NiCoP
Optimization
Oxygen
oxygen doping
Raman spectra
Slope stability
NiCoP
in situ Raman
oxygen doping
DFT calculations
hydrogen evolution reaction
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Summary:An outstanding hydrogen evolution electrocatalyst should have a free energy of adsorbed atomic hydrogen of approximately zero, which enables not only a fast proton/electron‐transfer step but also rapid hydrogen release. An economic and industrially viable alternative approach for the optimization of atomic hydrogen binding energy is urgently needed. Herein, guided by density functional theory (DFT) calculations, it is theoretically demonstrated that oxygen doping in NiCoP can indeed optimize the atomic hydrogen binding energy (e.g., |ΔGH*| = 0.08, 0.12 eV on Co, P sites). To confirm this, NiCoP electrodes with controllable oxygen doping are designed and fabricated via alteration of the reducing atmosphere. Accordingly, an optimal oxygen‐doped NiCoP (≈0.98% oxygen) nanowire array is found to exhibit the remarkably low hydrogen evolution reaction (HER) overpotential of 44 mV to drive 10 mA cm−2 and a small Tafel slope of 38.6 mV dec−1, and long‐term stability of 30 h in an alkaline medium. In neutral solution, only a 51 mV overpotential (@10 mA cm−2) is required, and the Tafel slope is 79.2 mV dec−1. Meanwhile, in situ Raman spectra confirm the low formation overpotential (−30 mV) of NiCo‐phosphate at the surface of ≈0.98% oxygen‐doped NiCoP, which enables the material to show better HER performance. Based on density functional theory calculations, it is found that atomic hydrogen binding energy can be optimized on NiCoP via oxygen doping. Accordingly, an optimal oxygen‐doped porous NiCoP NWAs/NF (≈0.98% oxygen) is achieved by altering reducing atmosphere, exhibiting low overpotentials of 44, 51 mV (@10 mA∙cm−2), and Tafel slopes of 38.6, 79.2 mV∙dec−1 in alkaline and neutral medium, respectively.
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ISSN:1613-6810
1613-6829
DOI:10.1002/smll.201800421