The Nanoscale Electronics and Sensor Laboratory (NESL) is currently focused on five major research areas: Epitaxial Graphene based Sensors; MEMS sensors; Nanowire based MEMS sensors and electronics; Implantable sensors for biomedical application; Scanning probe characterization.
A non-for-profit corporation with a broad-based Board of Directors that will lead, coordinate and enable partner organizations to complete the action steps necessary to improve Colorado's competitive position in five target areas: leadership, business growth, research and technology transfer, workforce development and public education and societal change.
MRSEC is an interdisciplinary team of university, industrial, and national laboratory scientists and engineers working together to develop and examine new types of nanocrystals and ways of assembling them into thin films.
The Columbia University Nanocenter's goal is to establish new paradigms for information processing using the characteristics of electron transport unique to nanoscale molecular structures. Founded in 2001, the Nanocenter draws upon years of experience in chemical synthesis to design molecular structures with carefully crafted properties.
The Converging Technologies Bar Association is the first professional association in the world dedicated to addressing the multi-faceted impact of converging technologies. With its collective focus on nanotechnology, biotechnology, information technology, cognitive science, neuroscience, and other related sciences and technologies, the CTBA provides a rich forum for bringing clarity and focus to the legal, ethical, and societal issues generated by the convergence of these provinces.
Established as one of 6 interdisciplinary Nanoscale Science and Engineering Centers to address the existing challenges and opportunities that are to be found in nanotechnology research and development.
The group investigates the physics and applications of nanoscale photonic structures. In particular, they are interested in light confining structures that can slow down, trap, enhance and manipulate light. Photonic structures can enhance light-matter interactions by orders of magnitude.The applications of the devices that the group designs, fabricates and demonstrates are numerous: on-chip light modulation (optically and electro-optically) and detection, networks on-chip, nonlinear phenomena, multi-material devices and platforms, microfluidics, basic physics, etc.
The group of Prof. Carl A. Batt is engaged in basic and applied research in a wide range of topics. One area of focus in on the use of protein engineering / expression techniques for developing recombinant anti-cancer therapeutics. Another active area of research involves the design and engineering of portable sensor devices using leading-edge micro- and nanofabrication methods. The third major area of investigation in our lab explores how biomaterials may be used to develop novel methodologies for creating advanced microfluidic systems and nanostructured arrays for bioanalytical applications.