Intermediate-state-trapped mutants pinpoint G protein-coupled receptor conformational allostery

Wang, Xudong; Neale, Chris; Kim, Soo-Kyung; Goddard, William A.; Ye, Libin

doi:10.1038/s41467-023-36971-6

Cited by 23 publications

(28 citation statements)

References 67 publications

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“…[13] The smaller Tafel slope of the MnÀ Co 3 O 4 @CN signifies a conspicuous enhancement in the water oxidation rate with increasing overpotential and indicates more favorable reaction kinetics. [14] In addition, the Tafel slope for MnÀ Co 3 O 4 @CN is non-potential dependent, whereas that for RuO 2 and pure Co 3 O 4 are strongly potential-dependent. Remarkably, the ratios of Δη/Δlog j (Figure 2c) of MnÀ Co 3 O 4 @CN exhibited a nearly constant behavior at a broad range of current densities, while the corresponding ratio for RuO 2 escalated to an excess of 323.3 mV dec À 1 .…”

Section: Methodsmentioning

confidence: 99%

Reconstructing Hydrogen‐Bond Network for Efficient Acidic Oxygen Evolution

Zhu,

Yang,

et al. 2024

Angew Chem Int Ed

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Developing highly active oxygen evolution reaction (OER) catalysts in acidic conditions is a pressing demand for proton‐exchange membrane water electrolysis. Manipulating proton character at the electrified interface, as the crux of all proton‐coupled electrochemical reactions, is highly desirable but elusive. Herein we present a promising protocol, which reconstruct a connected hydrogen‐bond network beween the catalyst‐electrolyte interface by coupling hydrophilic units to boost acidic OER activity. Modelling on N‐doped‐carbon‐layer clothed Mn‐doped‐Co3O4 (Mn‐Co3O4@CN), we unravel that the hydrogen‐bond interaction between CN units and H2O molecule not only drags the free water to enrich the surface of Mn‐Co3O4 but also serves as a channel to promote the dehydrogenation process. Meanwhile, the modulated local charge of the Co sites from CN units/Mn dopant lowers the OER barrier. Therefore, Mn‐Co3O4@CN surpasses RuO2 at high current density (100 mA cm‐2 @ ~538 mV).

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Section: Methodsmentioning

confidence: 99%

Reconstructing Hydrogen‐Bond Network for Efficient Acidic Oxygen Evolution

Zhu,

Yang,

et al. 2024

Angew Chem Int Ed

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“…This importance of the magnetic moment for Fe, Co, and Ni-containing catalysts complements the understanding of activity descriptors for (hydro)oxides. Recent works by Cao et al 56 and Wang et al 57 have also emphasized the role of magnetism in catalytic activity. Subsequent electronic structure calculations have corroborated the discernible distinctions in magnetic moments among the Fe, Co, and Ni active site atoms within the Fe, Co, and Ni (hydro)oxide (Fig.…”

Section: Active-site Structure Engineeringmentioning

confidence: 99%

Unlocking the performance of ternary metal (hydro)oxide amorphous catalysts via data-driven active-site engineering

Zhang,

Li,

et al. 2023

Energy Environ. Sci.

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“…(a) Anion exchange membrane mechanism schematic, (b) Lattice oxygen oxidation mechanism mechanism schematic. Reproduced with permission: Copyright 2023, Nature Publishing Group., [156] (c) COM mechanism schematic and (d) Dynamic evolution mechanism schematic. its deprotonation.…”

Section: Opportunities Of Nife-based Electrocatalysts For Oermentioning

confidence: 99%

Stability challenges and opportunities of NiFe‐based electrocatalysts for oxygen evolution reaction in alkaline media

Han,

Wang,

Liu

et al. 2024

Carbon Neutralization

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Water splitting is a critical process for the production of green hydrogen, contributing to the advancement of a circular economy. However, the application of water splitting devices on a large scale is primarily impeded by the sluggish oxygen evolution reaction (OER) at the anode. Thus, developing and designing efficient OER catalysts is a significant target. NiFe‐based catalysts are extensively researched as excellent OER electrocatalysts due to their affordability, abundant reserves, and intrinsic activities. However, they still suffer from long‐term stability challenges. To date, few systematic strategies for improving OER durability have been reported. In this review, various advanced NiFe‐based catalysts are introduced. Moreover, the OER stability challenges of NiFe‐based electrocatalysts in alkaline media, including iron segregation, structural degradation, and peeling from the substrate are summarized. More importantly, strategies to enhance OER stability are highlighted and opportunities are discussed to facilitate future stability studies for alkaline water electrolysis. This review presents a design strategy for NiFe‐based electrocatalysts and anion exchange membrane (AEM) electrolyzers to overcome stability challenges in OER, which also emphasizes the importance of long‐term stability in alkaline media and its significance for achieving large‐scale commercialization.

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Intermediate-state-trapped mutants pinpoint G protein-coupled receptor conformational allostery

Cited by 23 publications

References 67 publications

Reconstructing Hydrogen‐Bond Network for Efficient Acidic Oxygen Evolution

Reconstructing Hydrogen‐Bond Network for Efficient Acidic Oxygen Evolution

Unlocking the performance of ternary metal (hydro)oxide amorphous catalysts via data-driven active-site engineering

Stability challenges and opportunities of NiFe‐based electrocatalysts for oxygen evolution reaction in alkaline media

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