The Grzybowski Research Group at Northwestern University aims at (i) understanding self-assembly (SA) and self-organization (SO) in both equilibrium and nonequilibrium ensembles at various length-scales and (ii) applying SA/SO in practical applications ranging from micro and nanotechnology through biology to societal/global issues.
The Institute for Nanotechnology was established as an umbrella organization for the multimillion dollar nanotechnology research efforts at Northwestern University. The role of the Institute is to support meaningful efforts in nanotechnology, house state-of-the-art nanomaterials characterization facilities, and nucleate individual and group efforts aimed at addressing and solving key problems in nanotechnology.
The MEMS and Nanomechanics group is focused on characterizing mechanical behavior and properties of materials at small scale, biomaterials and artificial bio-inspired materials, materials at high strain rates, and on developing the expertise and tools to address micro and nanoscale fabrication and testing.
The research of the Mirkin Research Group at Northwestern focuses on developing methods for controlling the architecture of molecules and materials on the 1-100 nm length scale, and utilizing such structures in the development of analytical tools that can be used in the areas of chemical and biological sensing, lithography, catalysis, and optics.
The group's vision is to develop innovative technologies that harness biomolecular activity perfected by nature towards applications in cellular interrogation, bio-energetic/functional materials development, and next-generation medicine.
The Nanoscale Science and Engineering Center (NSEC) for Integrated Nanopatterning and Detection Technologies is driven by a vision to develop innovative biological and chemical detection systems capable of revolutionizing a variety of fields.
The goal of the Seideman groups work at Northwestern is to understand, control and utilize molecular dynamics in different environments. To that end we develop and apply quantum mechanical, semiclassical and classical methods in both time and energy domains.
The Institute's mission is to translate advances in basic physics, chemistry, biology and computation into new tools to address important societal problems and, to create a research and teaching environment to enhance and transmit these capabilities from scientific generation to generation.
Theoretical and Computational Biophysics Group center on the structure and function of supramolecular systems in the living cell, and on the development of new algorithms and efficient computing tools for structural biology.
The group is focused on the study of energy transfer in semiconductor nanocrystals (NCs). They are interested in (1) constructing novel semiconductor nanocrystal material systems to engineer energy transfer processes, (2) developing imaging agents based on their NC constructs and (3) bandgap engineering of multilayered nanocrystalline materials.
The general goal of the Molecular & Electronic Nanostructures (M&ENS) Research Initiative at the Beckman Institute is to develop a fundamental understanding of chemical and physical processes involving structures on the nanometer scale.