BILLACURA, Maria Distressa Genita (2022). Group-13 catalysed protocols for utilisation of CO2 as a sustainable C1 source. Doctoral, Sheffield Hallam University. [Thesis]
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32074:618995
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Billacura_2023_PhD_Group-13CatalysedProtocols.pdf - Accepted Version
Restricted to Repository staff only until 13 March 2025.
Available under License Creative Commons Attribution Non-commercial No Derivatives.
Billacura_2023_PhD_Group-13CatalysedProtocols.pdf - Accepted Version
Restricted to Repository staff only until 13 March 2025.
Available under License Creative Commons Attribution Non-commercial No Derivatives.
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Abstract
The research described in this thesis focuses on the preparation of group 13-
containing compounds and their application as Lewis acid catalysts. This
research is in the context of utilizing CO2 as a renewable C1 feedstock, through
the atom-efficient conversion with epoxides/aziridines to form useful cyclic
carbonates and cyclic oxazolidinones. Significant progress in the search for
efficient catalysts for these conversions has been made over the years, with some
highly active aluminium compounds being developed. However, potential gaps in
this exploration exist, including the study of other metals from group 13 beyond
aluminium that have been investigated in many other fields of chemistry. Notably,
there are few reports of boron, indium and gallium-based compounds used as a
catalyst for the cycloaddition of CO2 to epoxides. With aluminium being
thoroughly explored this presents motivation for exploring the potential for use of
these other group 13 elements.
In this work, a series of trimethyl borate compounds with different parasubstitutions
on the phenoxy moieties have been prepared. Further to this, boron,
gallium and indium complexes containing aminotrisphenolate ligands have been
prepared. All these complexes have been tested as potential catalysts for the
synthesis of cyclic carbonates, and their reactivity investigated. Boron
aminotrisphenolate complexes operate by hydrogen-bonding catalysis rather
than the expected Lewis acid catalysis due to the incomplete coordination of the
aminotrisphenol ligand to the boron. The resulting free phenol acts as a catalyst
for the production of cyclic carbonates at relatively elevated catalyst loading.
Meanwhile, the trimethyl borate compounds, with a trigonal planar geometry,
provide Lewis acid-driven catalysis rather than via a hydrogen bonding
interaction.
The gallium aminotrisphenolate complex was used as a catalyst for
oxazolidinone synthesis, demonstrating the gallium complex's versatile efficiency
as a more powerful catalyst than the aluminium congener. The results show that
the Ga complex converts aziridines into the corresponding oxazolidinones in high
yields at relatively low catalyst loading. Indium complexes bearing
aminotrisphenolate and halide ligands are competent catalyst for the
cycloaddition of CO2 and epoxides to form cyclic carbonates, with evidence that a coordinated halide can also act as the nucleophile required for the ring-opening
step of the mechanism, thus adding more future possibilities to this family of
compounds.
Finally, modified cellulose fibres, prepared through anchoring of an
epoxide to the surface by the Fenton reaction, followed by cycloaddition of CO2
using gallium catalyst have been prepared. These fibres have shown a positive
outcome in the search for materials with antibacterial properties. As a final note,
the potential cycloaddition of CO2 to episulfide has been briefly studied. This
reaction produces an intractable solid product for which it has been unable to fully
confirm its structure.
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