Laura A. Achola scite author profile

The catalytic activity of MnO 2 nanosheets towards oxygen evolution depends highly on their interlayer environment. We present a systematic investigation on fine-tuning of the interlayer environment of MnO 2 nanosheets by intercalation through a facile cation exchange with inexpensive first-row transition metal cations, including Ni 2 + , Co 2 + , Cu 2 + , Zn 2 + , and Fe 3 + ions. Among them, the Ni-intercalated MnO 2 nanosheets show remarkably enhanced OER activity and long-term stability, compared to pristine MnO 2 nanosheets. The overpotential of 330 mV at a current density of 10 mA cm À 2 is observed for the Ni-intercalated MnO 2 nanosheets. The ehancement mechanism of OER is studied by comparing physiochemical properties, such as the oxidation state of Mn, the interlayer distance, the increase in the disorder/twisting of MnO 6 octahedra, and the interlayer cooperative binding of water molecules. The Ni intercalation, different from other metal cations, strengthens the MnÀ O bond perpendicularly to the layer chains to facilitate the interlayer catalysis possibly between two Mn sites, and thus promotes the efficiency of oxygen evolution.

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Ultrasmall Au nanocatalysts supported on nitrided carbon for electrocatalytic CO₂ reduction: the role of the carbon support in high selectivity

Liu

Wang

et al. 2018

Nanoscale

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Au is one of the most promising electrocatalysts to convert CO2 into CO in an aqueous-phase electrochemical reduction. However, ultrasmall Au nanocatalysts (AuNCs, <2 nm) have proven to be favorable for water reduction over CO2, although they possess a large surface-to-volume ratio and potentially are ideal for CO2 reduction. We herein report that ultrasmall AuNCs (1.9 ± 0.3 nm) supported on nitrided carbon are remarkably active and selective for CO2 reduction. The mass activity for CO of AuNCs reaches 967 A g-1 with a faradaic efficiency for CO of ∼83% at -0.73 V (vs. reversible hydrogen electrode) that is an order of magnitude more active than the state-of-the-art results. The high activity is endowed by the large surface area per unit weight and the high selectivity of ultrasmall AuNCs for CO2 reduction originates from the cooperative effect of Au and the nitrided carbon support where the surface N sites act as Lewis bases to increase the surface charge density of AuNCs and enhance the localized concentration of CO2 nearby catalytically active Au sites. We show that our results can be applied to other pre-synthesized Au catalysts to largely improve their selectivity for CO2 reduction by 50%. Our method is expected to illustrate a general guideline to effectively lower the cost of Au catalysts per unit weight of the product while maintaining its high selectivity for CO2 reduction.

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Laura A. Achola

Catalytic manganese oxide nanostructures for the reverse water gas shift reaction

Intercalating MnO₂ Nanosheets With Transition Metal Cations to Enhance Oxygen Evolution

Ultrasmall Au nanocatalysts supported on nitrided carbon for electrocatalytic CO₂ reduction: the role of the carbon support in high selectivity

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Laura A. Achola

Catalytic manganese oxide nanostructures for the reverse water gas shift reaction

Intercalating MnO2 Nanosheets With Transition Metal Cations to Enhance Oxygen Evolution

Ultrasmall Au nanocatalysts supported on nitrided carbon for electrocatalytic CO2 reduction: the role of the carbon support in high selectivity

Contact Info

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Intercalating MnO₂ Nanosheets With Transition Metal Cations to Enhance Oxygen Evolution

Ultrasmall Au nanocatalysts supported on nitrided carbon for electrocatalytic CO₂ reduction: the role of the carbon support in high selectivity