Swarit Dwivedi scite author profile

To understand the mechanisms responsible for thermal decomposition of a Zr-MOF (MIL-140C), we perform atomistic-scale molecular dynamics (MD) simulations and discuss the simulation data in comparison with the TEM images obtained for the decomposed Zr-MOF. First, we introduce the ReaxFF parameters suitable for the Zr/C/H/O chemistry and then apply them to investigate the thermal stability and morphological changes in the MIL-140C during heating. Based on the performed simulations we propose an atomic mechanism for the collapse of the MIL-140C and the molecular pathways for carbon monoxide formation, the main product of the MIL-140C thermal degradation. We also determine that the oxidation state of the ZrO x clusters, evolved due to the thermal degradation, approximates the tetragonal phase of ZrO 2 . Both simulations and experiments show a distribution of very small ZrO x clusters embedded in the disrupted organic sheet that could contribute to the unusual high catalytic activity of the decomposed MIL-140C.

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Aqueous phase conversion of CO2 into acetic acid over thermally transformed MIL-88B catalyst

Ahmad

Koley

Dwivedi

et al. 2023

Nat Commun

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Sustainable production of acetic acid is a high priority due to its high global manufacturing capacity and numerous applications. Currently, it is predominantly synthesized via carbonylation of methanol, in which both the reactants are fossil-derived. Carbon dioxide transformation into acetic acid is highly desirable to achieve net zero carbon emissions, but significant challenges remain to achieve this efficiently. Herein, we report a heterogeneous catalyst, thermally transformed MIL-88B with Fe0 and Fe3O4 dual active sites, for highly selective acetic acid formation via methanol hydrocarboxylation. ReaxFF molecular simulation, and X-ray characterisation results show a thermally transformed MIL-88B catalyst consisting of highly dispersed Fe0/Fe(II)-oxide nanoparticles in a carbonaceous matrix. This efficient catalyst showed a high acetic acid yield (590.1 mmol/gcat.L) with 81.7% selectivity at 150 °C in the aqueous phase using LiI as a co-catalyst. Here we present a plausible reaction pathway for acetic acid formation reaction via a formic acid intermediate. No significant difference in acetic acid yield and selectivity were noticed during the catalyst recycling study up to five cycles. This work is scalable and industrially relevant for carbon dioxide utilisation to reduce carbon emissions, especially when green methanol and green hydrogen are readily available in future.

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Solvation behaviour and micro-phase structure of formaldehyde-methanol-water mixtures

Dwivedi

Mushrif

Chaffee

et al. 2020

Journal of Molecular Liquids

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Swarit Dwivedi

Formation and control of secondary nanostructures in electro-hydrodynamic patterning of ultra-thin films

Atomistic Mechanisms of Thermal Transformation in a Zr-Metal Organic Framework, MIL-140C

Aqueous phase conversion of CO2 into acetic acid over thermally transformed MIL-88B catalyst

Solvation behaviour and micro-phase structure of formaldehyde-methanol-water mixtures

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