Nicolas Magnard scite author profile

Manganese dioxide is a good candidate for effective energy storage and conversion as it possesses a rich electrochemistry. The compound also shows a wide polymorphism. The γ-variety, an intergrowth of β- and R-MnO2, has been extensively studied in several types of batteries (e.g. Zn/MnO2, Li-ion) and is a common electrode material for commercial batteries. It is well known that the insertion of protons thermodynamically stabilises γ-MnO2 with respect to β-MnO2. Protons can enter the structure either by forming groups of 4 hydroxyls around a Mn4+ vacancy, called a Ruetschi defect, or by forming a hydroxyl group near a Mn3+ ion, called a Coleman defect. These defects differently affect the electrochemistry of manganese oxide, and tailoring their amount in the structure can be used to tune the material properties. Previous studies have addressed the proton insertion process, but the role of the synthesis pathway on the amount of defects created is not well understood. We here investigate how the parameters in a hydrothermal synthesis of γ-MnO2 nanoparticles influence the amount and type of H-related defects. Structural investigations are carried out using Pair Distribution Function analysis, X-ray absorption spectroscopy, thermogravimetric analysis, and inelastic neutron scattering. We demonstrate the possibility to control the amount and type of defects introduced during the synthesis. While the amount of Ruetschi defects increases with synthesis temperature, it decreases with extended synthesis time, along with the amount of Coleman defects. Moreover, we discuss the arrangement of the defects in the γ-MnO2 nanoparticles.

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Local structure analysis and structure mining for design of photocatalytic metal oxychloride intergrowths

Chatterjee

Magnard

Mathiesen

et al. 2022

J. Mater. Chem. A

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Sub-second pair distribution function using a broad bandwidth monochromator

Magnard¹,

Sørensen²,

Kantor³

et al. 2023

J Appl Cryst

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Here the use of a broad energy bandwidth monochromator, i.e. a pair of B4C/W multilayer mirrors (MLMs), is demonstrated for X-ray total scattering (TS) measurements and pair distribution function (PDF) analysis. Data are collected both on powder samples and from metal oxo clusters in aqueous solution at various concentrations. A comparison between the MLM PDFs and those obtained using a standard Si(111) double-crystal monochromator shows that the measurements yield MLM PDFs of high quality which are suitable for structure refinement. Moreover, the effects of time resolution and concentration on the quality of the resulting PDFs of the metal oxo clusters are investigated. PDFs of heptamolybdate clusters and tungsten α-Keggin clusters from X-ray TS data were obtained with a time resolution down to 3 ms and still showed a similar level of Fourier ripples to PDFs obtained from 1 s measurements. This type of measurement could thus open up faster time-resolved TS and PDF studies.

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Control of H-Related Defects in γ-MnO₂ in a Hydrothermal Synthesis

et al. 2023

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Manganese dioxide is a good candidate for effective energy storage and conversion as it possesses rich electrochemistry. The compound also shows a wide polymorphism. The γ-variety, an intergrowth of βand R-MnO 2 , has been extensively studied in several types of batteries (e.g., Zn/MnO 2 , Li-ion) and is a common electrode material for commercial batteries. It is well known that the insertion of protons thermodynamically stabilizes γ-MnO 2 with respect to β-MnO 2 . Protons can enter the structure either by forming groups of 4 hydroxyls around a Mn 4+ vacancy, called a Ruetschi defect, or by forming a hydroxyl group near a Mn 3+ ion, called a Coleman defect. These defects differently affect the electrochemistry of manganese oxide, and tailoring their amount in the structure can be used to tune the material properties. Previous studies have addressed the proton insertion process, but the role of the synthesis pathway on the amount of defects created is not well understood. We here investigate how the parameters in a hydrothermal synthesis of γ-MnO 2 nanoparticles influence the amount and type of H-related defects. Structural investigations are carried out using Pair Distribution Function analysis, X-ray absorption spectroscopy, thermogravimetric analysis, and inelastic neutron scattering. We demonstrate the possibility to control the amount and type of defects introduced during the synthesis. While the amount of Ruetschi defects increases with synthesis temperature, it decreases with extended synthesis time, along with the amount of Coleman defects. Moreover, we discuss the arrangement of the defects in the γ-MnO 2 nanoparticles.

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Nicolas Magnard

Characterisation of intergrowth in metal oxide materials using structure-mining: the case of γ-MnO₂

Control of H-related defects in γ-MnO2 in a hydrothermal synthesis

Local structure analysis and structure mining for design of photocatalytic metal oxychloride intergrowths

Sub-second pair distribution function using a broad bandwidth monochromator

Control of H-Related Defects in γ-MnO₂ in a Hydrothermal Synthesis

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About

Nicolas Magnard

Characterisation of intergrowth in metal oxide materials using structure-mining: the case of γ-MnO2

Control of H-related defects in γ-MnO2 in a hydrothermal synthesis

Local structure analysis and structure mining for design of photocatalytic metal oxychloride intergrowths

Sub-second pair distribution function using a broad bandwidth monochromator

Control of H-Related Defects in γ-MnO2 in a Hydrothermal Synthesis

Contact Info

Product

Resources

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Characterisation of intergrowth in metal oxide materials using structure-mining: the case of γ-MnO₂

Control of H-Related Defects in γ-MnO₂ in a Hydrothermal Synthesis