Catching an Oxo Vanadate Porous Acetylacetonate Covalent Adaptive Catalytic Network that Renders Mustard-Gas Simulant Harmless.
Nitumani DasRatul PaulShalini TomarChandan BiswasSudip ChakrabortyJohn MondalPublished in: Inorganic chemistry (2024)
In this work, we illustrated the design and development of a metal-coordinated porous organic polymer ( POP ) namely VO@TPA-POP via a post-synthetic metalation strategy to incorporate oxo-vanadium sites in a pristine polymer ( TPA-POP ) having acetylacetonate (acac) as anchoring moiety. The as-synthesized VO@TPA-POP exhibited highly robust and porous framework, which has been utilized for thioanisole (TA) oxidation to its corresponding sulfoxide. The catalyst demonstrated notable stability and recyclability by maintaining its catalytic activity over multiple reaction cycles without any significant loss in activity. The X-ray absorption spectroscopy (XAS) and density functional theory (DFT) analysis establish the existence of V(+4) oxidation state along with the VO(O) 4 active sites into the porous network and the most energetically feasible mechanistic pathway involved in the TA oxidation, respectively, indicating the role of electron density associated with vanadium center during the catalytic transformation. Thus, this work aims at the demonstration of versatility and potential of VO@TPA-POP as a porous heterogeneous catalyst for the TA oxidation followed by decontamination of sulfur mustards (HD's) to their corresponding less toxic sulfoxides in a more efficient and greener way.
Keyphrases
- metal organic framework
- density functional theory
- highly efficient
- hydrogen peroxide
- visible light
- electron transfer
- tissue engineering
- room temperature
- high resolution
- molecular dynamics
- computed tomography
- carbon dioxide
- single molecule
- nitric oxide
- crystal structure
- mass spectrometry
- risk assessment
- network analysis
- water soluble