Solid-state and materials chemistry with an emphasis on metastable compounds, electronic phase transitions, theory-guided materials design, electronic structure, development of synchrotron methods for imaging and spectroscopy, energy conversion and storage, and functional coatings.
Surface and interfacial phenomena, including charge transport in organic molecules, nanoparticle catalysis, semiconducting and 2D nanomaterials, plasmonics, tribology, "smart" surfaces, and self-organizing nanoscale materials for device applications.
Research in the Bergbreiter group focuses on polymer, organic, catalysis, and surface chemistry and involves modifying polymers, inventing sustainable safe solvents, and making synthetic and catalysis chemistry greener.
The Bluemel research interests span from inorganic, organometallic, and surface chemistry, to catalysis and polymer chemistry. Multinuclear NMR spectroscopy of dia- and paramagnetic liquids and solids is applied and further developed as a powerful method in all fields.
Structure-property relationships in polymer-nanoparticle systems (nanocomposites and thin films) for real world applications such as gas separation, flame retardancy and thermoelectric energy generation (e.g., turning body heat into useful voltage).
Development of mass spectrometry instrumentation and methodology for molecular surface analysis at the nanoscale, applications include the characterization of nano-objects, macromolecular architectures, 2D-materials and the co-localization of molecules at catalytic sites and on biological surfaces.
Synthetic strategies for degradable polymers derived from natural products, unique macromolecular architectures and complex polymer assemblies, designed for practical implementation in the diagnosis and treatment of disease, as non-toxic anti-biofouling or anti-icing coatings, as materials for microelectronics device applications, or as pollutant remediation systems.
Inorganic and materials chemistry, focusing on design and synthesis of metal-organic frameworks (MOFs) and covalent-organic frameworks (COFs) applied to energy-related research (e.g., CO2 capture, H2 storage), catalysis, and biomedical applications.