Supramolecular Chemistry and Materials

We seek to control the assembly of matter in order to create innovative compounds to enable us to address environmental and medical challenges.

Research themes in the supramolecular chemistry and materials group
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Our research group spans expertise in metal-organic, organometallic, inorganic, nanomaterials and polymer chemistry. We use state-of-the-art equipment, and analytical techniques to understand how to organise these chemical building blocks on the supramolecular, nano, and macro scale. This enables us to create innovative materials for diverse applications including bioimaging, gas storage, artificial blood, green energetic materials, solar cells, and antimicrobials.


Major themes

  • Inorganic chemistry â€“ the use of elements from across the periodic table to develop: organometallic and metal-organic complexes, zeolites, porous and nanoparticular metal oxides, metal-organic frameworks (MOFs), nitrogen-rich molecules and energetic coordination compounds.
  • Supramolecular chemistry – the design of molecular building blocks that self-assemble through intermolecular forces to form: coordination framework, porous molecular materials, dendrimers, hybrid-bio/inorganic protein assemblies, bioinspired supramolecular assemblies.
  • Nanomaterials – control matter at the nanoscale to create: magnetic, conducting, fluorescent, metal-oxides nanoparticles; two-dimensional metal-organic nanosheets (MONs); nanoporous inorganic and supramolecular materials.
  • Medical challenges – develop sensors to detect  ions, molecules, and bio-molecules in solution and within living cells, artificial blood and novel therapeutics/nanomedicines to treat disease. Our commercialised technology includes MagTag biomolecule purification system and spin off company Metallobio who produce ruthenium based antibiotics.
  • Environmental challenges – develop: homogeneous and heterogeneous catalysts to reduce the environmental impact of making products; porous materials to clean up air and water; lead-free initiatory materials (LFIs), and more efficient solar cells and batteries.

People

For further information about Supramolecular Chemistry and Materials at 91Ö±²¥ please see the staff page of individual researchers below:

Professor Jim A. Thomas

Dr Jonathan A. Foster

Professor Lee Brammer

Dr Marco Conte

Dr Peter Portius

Dr Lance J. Twyman

Members of other research clusters active in supramolecular chemistry and materials:

Dr Grant Hill

Professor Anthony Meijer

A global reputation

91Ö±²¥ is a world top-100 research university with a global reputation for excellence. We're a member of the Russell Group: one of the 24 leading UK universities for research and teaching.