The primary goal of INE is to develop breakthrough technologies in energy storage and generation (solar and wind) by developing organic based nano-photonic, nano-phononic and nanomechanical composites that are manufactured by means of sophisticated material control mechanisms. This is achieved through the use of a variety of techniques including electron and optical microscopy, spectroscopy, nanofabrication and self-assembly. The ability to design, assemble and engineer nanostructures will rely predominately on understanding and controlling the interactions between the nanostructures.
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.
The group of Prof William King designs, fabricates, and uses tools for thermal and thermomechanical processing at micrometer and nanometer length scales. Their research involves the use of atomic force microscopy (AFM) and nanoimprint lithography for thermal and thermomechanical modification of surfaces.
The Nanoscience and Nanotechnology Institute at The University of Iowa focuses on issues related to applications and implications of nanoscience and nanotechnology in environmental processes and human health, as well as the fundamental properties of nanomaterials.
The REN group works on the forefront of Material Nanochemistry and Nanotechnology, including chemical design, synthesis and self-assembly of low-dimensional nanomaterials based on the bottom-up paradigm, with an emphasis on novel photonic, electronic, magnetic and excitonic properties for applications in efficient solar energy harvesting and magnetic energy storage.
More than 40 research scientists and engineers from diverse disciplines have come together in a new 106,000 square foot research facility on the University of Louisville's main campus. Engineers with specialties in MEMS, bioMEMS, nanotechnology, electrooptics, biomechanics, bioengineering, microfabrication, and theoretical and applied physics, work along side scientists from the College of Arts and Sciences with expertise in molecular, cellular and structural biology and medicinal and combinatorial chemistry, and with cancer and genetic researchers from the Schools of Medicine and Dentistry.
The Mission of the Center for Nanomedicine and Cellular Delivery (CNCD) at the University of Maryland is to create a multidisciplinary research environment that will provide expertise and foster collaborations for the design, development and translation into clinic of nanosystems for therapeutic and diagnostic purposes.