From NiMoO 4 to γ-NiOOH: Detecting the Active Catalyst Phase by Time Resolved in Situ and Operando Raman Spectroscopy

Water electrolysis powered by renewable energies is a promising technology to produce sustainable fossil free fuels. The development and evaluation of effective catalysts are here imperative; however, due to the inclusion of elements with different redox properties and reactivity, these materials un...

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Bibliographic Details
Published in:ACS nano 2021-08, Vol.15 (8), p.13504-13515
Main Authors: Dürr, Robin N, Maltoni, Pierfrancesco, Tian, Haining, Jousselme, Bruno, Hammarström, Leif, Edvinsson, Tomas
Format: Article
Language:English
Subjects:
alkaline water splitting
Catalysis
Chemical Sciences
electrocatalysis
in situ catalyst formation
Material chemistry
molybdenum leaching
nanostructures
nickel molybdate
time-resolved operando Raman spectroscopy
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Summary:Water electrolysis powered by renewable energies is a promising technology to produce sustainable fossil free fuels. The development and evaluation of effective catalysts are here imperative; however, due to the inclusion of elements with different redox properties and reactivity, these materials undergo dynamical changes and phase transformations during the reaction conditions. NiMoO is currently investigated among other metal oxides as a promising noble metal free catalyst for the oxygen evolution reaction. Here we show that at applied bias, NiMoO ·H O transforms into γ-NiOOH. Time resolved Raman spectroscopy is utilized to follow the potential dependent phase transformation and is collaborated with elemental analysis of the electrolyte, confirming that molybdenum leaches out from the as-synthesized NiMoO ·H O. Molybdenum leaching increases the surface coverage of exposed nickel sites, and this in combination with the formation of γ-NiOOH enlarges the amount of active sites of the catalyst, leading to high current densities. Additionally, we discovered different NiMoO nanostructures, nanoflowers, and nanorods, for which the relative ratio can be influenced by the heating ramp during the synthesis. With selective molybdenum etching we were able to assign the varying X-ray diffraction (XRD) pattern as well as Raman vibrations unambiguously to the two nanostructures, which were revealed to exhibit different stabilities in alkaline media by time-resolved and Raman spectroscopy. We advocate that a similar approach can beneficially be applied to many other catalysts, unveiling their structural integrity, characterize the dynamic surface reformulation, and resolve any ambiguities in interpretations of the active catalyst phase.
ISSN:1936-0851
1936-086X
1936-086X
DOI:10.1021/acsnano.1c04126