Spin Polarization of Chiral Amorphous Fe‐Ni Electrocatalysts Enabling Efficient Electrochemical Oxygen Evolution

Feng, Tanglue; Xue, Jie; Cao, Fangfang; Chen, Zhongwei; Ye, Jichun; Xiao, Chuanxiao; Lu, Haipeng

doi:10.1002/adfm.202215051

Cited by 14 publications

(8 citation statements)

References 66 publications

(29 reference statements)

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“…It would be interesting and significant that different circularly polarized light can modulate the spin state of catalysts, thus leading to the selective catalytic production of different chiral molecules. Recent research has revealed that chiral-induced spin selectivity (CISS) can be observed in various spin-dependent optoelectronics and electrochemistry. − CISS suggests that the molecular chirality and electron spin of chiral systems are highly correlated, meaning that electron spins become polarized as they pass through chiral systems. It has been proposed that the spin-polarized electrons generated by the CISS can interact with the catalyst surface, leading to an enhanced activity in the OER/ORR.…”

Section: Discussionmentioning

confidence: 99%

Spin-Modulated Oxygen Electrocatalysis

Fang,

Zhao,

Shen

et al. 2023

Precision Chemistry

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The electrocatalysis reactions involving oxygen, such as oxygen evolution reaction (OER) and oxygen reduction reaction (ORR), play a critical role in energy storage/ conversion applications, e.g., fuel cells, metal-air batteries, and electrochemical water splitting. The high kinetic energy barrier of the OER/ORR is highly associated with the spin state interconversion between singlet OH − /H 2 O and triplet O 2 , which is influenced by the spin state and magnetism of catalysts. This Review summarizes recent progress and advances in understanding spin/magnetism-related effects in oxygen electrocatalysis to develop spin theory. It is demonstrated that the spin states (low, intermediate, and high spin) of magnetic transition metal catalysts (TMCs) can directly affect the reaction barriers of OER/ORR by tailoring the bonding of oxygen intermediates with TMCs. Besides, the spin states of TMCs can build a spin-selective channel to filter the electron spins required for the single/triplet interconversion of O species during OER/ORR. In this Review, we introduced many approaches to modulating spin state, for instance, altering the crystal field, oxidation state of active-site ions, and the morphology of TMCs. What's more, a magnetic field can drive the spin flip of magnetic ions to achieve the spin alignment (↑↑) (i.e., facilitating spin polarization), which will strengthen the spin selectivity for accelerating the filtration and transfer of the spins with the same direction for the generation and conversion of triplet ↑O�O↑. Importantly, the origin of magnetic field enhancement on OER/ORR are deeply discussed, which provides a great vision for the magnetism-assisted catalysis. Finally, the challenges and perspectives for future development of spin/magnetism catalysis are presented. This Review is expected to highlight the significance of spin/magnetism theory in breaking the bottleneck of electrocatalysis field and promote the development of high-efficientcy electrocatalysts for practical applications.

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Section: Discussionmentioning

confidence: 99%

Spin-Modulated Oxygen Electrocatalysis

Fang,

Zhao,

Shen

et al. 2023

Precision Chemistry

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“…Unlike organic molecules, chiral inorganic nanomaterials may exhibit better chiroptical activity due to high electrical polarization and magnetic susceptibility, , thus advancing multiple fields such as polarization-related imaging, biosensing, and chiral photonics. , Additionally, chiral inorganic materials with their inherent stability and conductivity hold great promise for catalysis. Recent studies have demonstrated that chiral materials can act as spin filters during electron transport, directing electrons toward favored polarization via chiral-induced spin selectivity. − This provides a novel approach to improve the photo/electrocatalytic performance, beyond the conventional methods such as modulating the binding structure of catalysts or applying magnetic fields. − Previous efforts to explore this concept often involved incorporating organic chiral components into inorganic materials such as coating or intercalating organic chiral molecules onto or into inorganic nanomaterials. ,− Electrodeposition has also been employed to fabricate chiral inorganic films. − Despite the progress made, concerns regarding chiral instability and limited control over chiroptical activity have hindered exploration of the intricate relationship between the chiroptical effect and catalysis.…”

Section: Introductionmentioning

confidence: 99%

Chirality Engineering of Colloidal Copper Oxide Nanostructures for Tailored Spin-Polarized Catalysis

Jin,

Fu,

Wen

et al. 2023

J. Am. Chem. Soc.

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The combination of the chiral concept and inorganic nanostructures holds great potential for significantly impacting catalytic processes and products. However, the synthesis of inorganic nanomaterials with engineered chiroptical activity and identical structure and size presents a substantial challenge, impeding exploration of the relationship between chirality (optical activity) and catalytic efficiency. Here, we present a facile wetchemical synthesis for achieving intrinsic and tunable chiroptical activity within colloidal copper oxide nanostructures. These nanostructures exhibit strong spin-polarization selectivity compared with their achiral counterparts. More importantly, the ability to engineer chiroptical activity within the same type of chiral nanostructures allows for the manipulation of spin-dependent catalysis, facilitating a study of the connection between the chiroptical magnitude (asymmetric factor) and catalytic performance in inorganic nanostructures. Specifically, using these materials as model catalysts in a proof-of-concept catalytic reaction, we reveal a linear correlation between the asymmetric factor of chiral nanomaterials and the efficiency of the catalytic reaction. This work paves the way for the development of chiral inorganic nanosystems and their application in catalysis through chiroptical engineering.

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“…12−16 Moreover, various intermediates like the formation of *O and *OOH have presented significant long-term challenges in devising efficient water splitting catalysts. 17 Consequently, there is an urgent need to design anode catalysts with exceptional OER performance.…”

mentioning

confidence: 99%

“…With the excessive utilization of fossil fuels and the escalating greenhouse effect, promoting energy transformation has emerged as a global objective. − The volatility and inertness of renewable energy sources, such as wind and solar energy, present a formidable challenge to energy utilization. Electrochemical water splitting, as a technology for producing hydrogen which can be stored and utilized to maintain balance between energy supply and demand, is extensively studied. − Among the various electrolytic water technologies, polymer electrolyte membrane water electrolyzes (PEMWEs) have received considerable attention due to the fast response to fluctuating electricity, higher current densities, and compact stack designs. − However, the anodic oxygen evolution reaction (OER), as the key rate-limiting step of PEMWE, involves a complex four-electron transfer process and thus displays slow reaction kinetics and high overpotential. − Moreover, various intermediates like the formation of *O and *OOH have presented significant long-term challenges in devising efficient water splitting catalysts . Consequently, there is an urgent need to design anode catalysts with exceptional OER performance.…”

mentioning

confidence: 99%

Defect Engineering of RuO₂ Aerogel for Efficient Acidic Water Oxidation

Han,

Jin,

Chen

et al. 2024

ACS Materials Lett.

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The development of renewable energy conversion devices heavily relies on the design of high-performance electrocatalysts for water electrolysis systems. In this study, a Se-doped RuO 2 aerogel (Se-RuO 2 aerogel) with abundant defects is prepared as an excellent oxygen evolution reaction (OER) electrocatalyst in acidic media. The Se-RuO 2 aerogel exhibits a remarkably low overpotential of 166 mV at a current density of 10 mA cm −2 and long-term stability of up to 48 h. Concurrently, detailed in situ experiments demonstrate that the Se-RuO 2 aerogel can maintain excellent stability during the OER process, for their reaction path follows a more stable adsorption evolution mechanism. Therefore, it can operate for 100 h at a current density of 100 mA cm −2 when assembled as an anode catalyst in a polymer electrolyte membrane (PEM) electrolyzer. This work provides a new vision for the design of high-performance electrocatalysts based on aerogel with defect engineering.

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Spin Polarization of Chiral Amorphous Fe‐Ni Electrocatalysts Enabling Efficient Electrochemical Oxygen Evolution

Cited by 14 publications

References 66 publications

Spin-Modulated Oxygen Electrocatalysis

Spin-Modulated Oxygen Electrocatalysis

Chirality Engineering of Colloidal Copper Oxide Nanostructures for Tailored Spin-Polarized Catalysis

Defect Engineering of RuO₂ Aerogel for Efficient Acidic Water Oxidation

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Spin Polarization of Chiral Amorphous Fe‐Ni Electrocatalysts Enabling Efficient Electrochemical Oxygen Evolution

Cited by 14 publications

References 66 publications

Spin-Modulated Oxygen Electrocatalysis

Spin-Modulated Oxygen Electrocatalysis

Chirality Engineering of Colloidal Copper Oxide Nanostructures for Tailored Spin-Polarized Catalysis

Defect Engineering of RuO2 Aerogel for Efficient Acidic Water Oxidation

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Defect Engineering of RuO₂ Aerogel for Efficient Acidic Water Oxidation