Mark Berg
"Ultrafast lasers producing pulses as short as 10−13 sec are combined with new multidimensional spectroscopies to study the dynamics of complex materials, including nanoparticles, ionic liquids, glasses, polymers and biomolecules."
Donna Chen
"We are studying chemical reactions on metal nanoparticles and metal surfaces on the atomic scale in order to obtain information about reaction products, kinetics, mechanisms and active surface sites."
Sophya Garashchuk
"We are interested in understanding the nuclear quantum effects, such as the zero-point energy and tunneling, on reactivity at low temperature during the proton transfer and other processes occurring within the molecular environment. To simulate these effects we are developing the quantum trajectory-based molecular dynamics with approximate quantum corrections, which is practical to describe hundreds of atoms thanks to high-performance computing implementation."
Ting Ge
"We study the conformations and dynamics of macromolecules and the material properties such as mechanical and rheological properties of polymeric materials. We combine computer simulations and microscopic theories to understand the relations between microscopic parameters and macroscopic response. "
Andrew Greytak
"We use microscopy, spectroscopy and electronic transport measurements to explore the role of the surface in dictating the properties of semiconductor nanowires and colloidal nanocrystals. We are also interested in applications of nanomaterials in energy production and biological fluorescence imaging."
Michael Myrick
"We're working to understand how nutrient conditions affect fluorescence properties of phytoplankton. This knowledge is being used to test phytoplankton as sensors for ocean composition. It is also being used to help identify phytoplankton by their pigmentation regardless of ocean composition."
Vitaly Rassolov
"Our lab develops and applies new electronic structure models based on electron pairs, especially useful for transition metal complexes and bond breaking. We also work on the nuclear dynamics of protons in complex systems."
Chris Sutton
"Machine learning to predict quantum mechanical properties of atomistic systems (e.g., energy, bandgap, density, etc), high-throughput methods and statistical learning methods for the computational screening of new materials, & calculating ground and excited state properties of materials and molecules to gain a quantitative understanding of atomic-scale phenomena."
Tom Vogt
"We make novel metal oxides and nanoparticles and determine their atomic structures using electron, X-ray, and neutron scattering and explore their unique electrical, magnetic, dielectric, optical and photocatalytic properties."
Hui Wang
"The central theme of our research is to use novel physical chemistry approaches, specifically spectroscopies and microscopies, to develop quantitative understanding of novel nanophotonic materials systems and conformationally dynamic biomolecules."