Catalysis Meets Spintronics; Spin Potentials Associated with Open-Shell Orbital Configurations Enhance the Activity of Pt<sub>3</sub>Co Nanostructures for Oxygen Reduction: A Density Functional Theory Study

Biz, Chiara; Fianchini, Mauro; Gracia, José

doi:10.1021/acsanm.9b02067

Cited by 45 publications

(65 citation statements)

References 60 publications

(124 reference statements)

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“…Here, we would like to highlight the challenges and opportunities of spintronic oxygen electrocatalysis, which might provide some inspirations for the development of this field. Spin‐polarized DFT calculations with oriented spin ordering. Spin‐polarized DFT calculations are able to precisely reflect most of the thermodynamic feature of reactions on magnetic materials, and Gracia and co‐workers [ 17 ] have demonstrated that catalyst with different spin ordering exhibits different binding affinity to the reactants and intermediates of ORR. Thus, to accurately describe the spin‐related catalysis phenomena and provide more reliable predictions for catalyst design, spin‐polarized DFT calculations with oriented spin ordering should be employed.…”

Section: The Future Of Spintronic Oxygen Electrocatalysis: Challengesmentioning

confidence: 99%

“…It has been demonstrated theoretically by Gracia and co‐workers that materials with dominating FM spin orderings generally exhibit better spin‐selected charge transport mobility. [ 17 ] The oxygen electrocatalysis could benefit significantly if materials dominated by FM spin orderings can be synthesized through simple and practicable processes. However, to date, one‐step synthesis of the commonly employed transition metal oxides (TMOs), such as perovskite and spinel oxides, with dominant FM ordering is technically difficult.…”

Section: The Future Of Spintronic Oxygen Electrocatalysis: Challengesmentioning

confidence: 99%

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Spin‐Related Electron Transfer and Orbital Interactions in Oxygen Electrocatalysis

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renewable and ecofriendly energy technologies, such as fuel cells and water splitting. Currently, theoretical insights of oxygen electrocatalysis mainly focus on the thermodynamic features of the adsorption/desorption of reactants and intermediates. Besides the thermodynamic features, the electron transfer between the adsorbed reactants/intermediates and the active sites, and the charge transport within the catalysts during the electrocatalysis, are also a crucial factor influencing the reaction kinetics. That is, a comprehensible understanding of oxygen electrocatalysis should consider both the orbital interactions and the electron transfer behavior. In the domain of oxygen electrocatalysis (at room temperature in water), the electron transfer exhibits highly spin-related character because the ground state of O 2 mole cule is a triplet state (↑OO↑) (Figure 1). That is why O 2 is paramagnetic. Therefore, either from H 2 O/OH − to O 2 (oxygen evolution reaction, OER) or from O 2 to H 2 O/OH − (oxygen reduction reaction, ORR), the involvement of the triplet O 2 requires spin-related electron transfer along these oxygen reactions, which plays a considerable role in the reaction kinetics. The aspect of spin-related electron transfer has been unintentionally neglected and only a few pioneer works have noticed and emphasized its role. An early attempt can be traced back Oxygen evolution and reduction reactions play a critical role in determining the efficiency of the water cycling (H 2 O ⇔ H 2 + 1 2 O 2), in which the hydrogen serves as the energy carrier. That calls for a comprehensive understanding of oxygen electrocatalysis for efficient catalyst design. Current opinions on oxygen electrocatalysis have been focused on the thermodynamics of the reactant/intermediate adsorption on the catalysts. Because the oxygen molecule is paramagnetic, its production from or its reduction to diamagnetic hydroxide/water involves spin-related electron transfer. Both electron transfer and orbital interactions between the catalyst and the reactant/intermediate show spin-dependent character, making the reaction kinetics and thermodynamics sensitive to the spin configurations. Herein, a brief introduction on the spintronic explanation of the catalytic phenomena on oxygen evolution reaction (OER) and oxygen reduction reaction (ORR) is given. The local spin configurations and orbital interactions in the benchmark transition-metalbased catalysts for OER and ORR are analyzed as examples. To further understand the spintronic oxygen electrocatalysis and to develop more efficient spintronic catalysts, the challenges are summarized and future opportunities proposed. Spin electrocatalysis may emerge as an important topic in the near future and help integrate a comprehensive understanding of oxygen electrocatalysis.

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Section: The Future Of Spintronic Oxygen Electrocatalysis: Challengesmentioning

confidence: 99%

Section: The Future Of Spintronic Oxygen Electrocatalysis: Challengesmentioning

confidence: 99%

Spin‐Related Electron Transfer and Orbital Interactions in Oxygen Electrocatalysis

et al. 2020

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“…Magnetic catalysts are considered to be environmentally friendly as they can be easily and completely separated from reactants using an external magnet without any loss, unlike other heterogeneous catalysts requiring filtration, centrifugation and other techniques that might be quite sophisticated [70]. It is also known that not only charge transfer but also spin transfer may occur when the molecule is adsorbed on magnetic surface, enhancing its catalytic properties [71] and expanding the area of potential applications in spintronic devices [72]. Non-stoichiometric ones are presented both for the reference and as an intermediate step of thin films formation.…”

Section: Resultsmentioning

confidence: 99%

Theoretical Investigation of the Prospect to Tailor ZnO Electronic Properties with VP Thin Films

et al. 2021

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The atomic and electronic structure of vanadium phosphide one- to four-atomic-layer thin films and their composites with zinc oxide substrate are modelled by means of quantum chemistry. Favorable vanadium phosphide to ZnO orientation is defined and found to remain the same for all the structures under consideration. The electronic structure of the composites is analyzed in detail. The features of the charge and spin density distribution are discussed.

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“…[ 55,62–66 ] Meanwhile, ferromagnetic couplings in inorganic catalysts with magnetic ordering structure were demonstrated to selectively accumulate/remove appropriate e‐spins in the O 2 generation/conversion process (Figure 2b). [ 57,67–71 ] These pioneer works highlight the significance of spin‐related effect in oxygen electrocatalysis. [ 72–77 ]…”

Section: Introductionmentioning

confidence: 99%

Spin Effect on Oxygen Electrocatalysis

et al. 2021

Adv Energy and Sustain Res

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Oxygen involved reactions, including oxygen reduction (ORR) and oxygen evolution reactions (OERs), play a key role in electrochemical energy devices, such as fuel cells and metal–air batteries. Recent theoretical calculations and experimental investigations reveal that the energy loss in ORR/OER is closely related to the triplet O2 generation/conversion step. However, the spin‐related phenomena have long been neglected in understanding of the ORR/OER mechanism. This review highlights recent advances in understanding and application of the spin‐related effect in oxygen electrocatalysis. It is demonstrated that the exchange interaction in magnetic catalysts can build a spin‐selective channel to filter the electron spins with appropriate orientation in the O2 generation/conversion step during ORR/OER. It is believed that the introduction of spin effect can establish a more comprehensive understanding of oxygen electrocatalysis and assist designing more reactive oxygen electrocatalysts.

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Catalysis Meets Spintronics; Spin Potentials Associated with Open-Shell Orbital Configurations Enhance the Activity of Pt₃Co Nanostructures for Oxygen Reduction: A Density Functional Theory Study

Cited by 45 publications

References 60 publications

Spin‐Related Electron Transfer and Orbital Interactions in Oxygen Electrocatalysis

Spin‐Related Electron Transfer and Orbital Interactions in Oxygen Electrocatalysis

Theoretical Investigation of the Prospect to Tailor ZnO Electronic Properties with VP Thin Films

Spin Effect on Oxygen Electrocatalysis

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Catalysis Meets Spintronics; Spin Potentials Associated with Open-Shell Orbital Configurations Enhance the Activity of Pt3Co Nanostructures for Oxygen Reduction: A Density Functional Theory Study

Cited by 45 publications

References 60 publications

Spin‐Related Electron Transfer and Orbital Interactions in Oxygen Electrocatalysis

Spin‐Related Electron Transfer and Orbital Interactions in Oxygen Electrocatalysis

Theoretical Investigation of the Prospect to Tailor ZnO Electronic Properties with VP Thin Films

Spin Effect on Oxygen Electrocatalysis

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Catalysis Meets Spintronics; Spin Potentials Associated with Open-Shell Orbital Configurations Enhance the Activity of Pt₃Co Nanostructures for Oxygen Reduction: A Density Functional Theory Study