Brief Bio
JAMES K. GIMZEWSKI
PhD, DSc hc, Phd hc, FRS, CPhys, FIoN, FInstP, FWIF, FREng Distinguished Professor, UCLA Chemistry & Biochemistry Department Director, UCLA CNSI Nano & Pico Characterization Core Facility Scientific Director, UCLA Art|Sci Center Principal Investigator & Satellites Co-Director, WPI Center for Materials NanoArchitectonics (MANA), NIMS, Japan
"I am enough of an artist to draw freely upon my imagination. Imagination is more important than knowledge. For knowledge is limited, whereas imagination embraces the entire world, stimulating progress, giving birth to evolution."--Albert Einstein
Jim Gimzewski is a Distinguished Professor of Chemistry at the University of California, Los Angeles; Faculty Director of the Nano & Pico Characterization Core Facility of the California NanoSystems Institute; Scientific Director of the Art|Sci Center and Principal Investigator and Satellites Co-Director of the WPI Center for Materials NanoArchitectonics (MANA) in Japan. He is a Fellow of the Royal Society.
Prior to joining the UCLA faculty, he was a group leader at IBM Zurich Research Laboratory, where he research in nanoscale science and technology from 1983 to 2001. Dr. Gimzewski pioneered research on mechanical and electrical contacts with single atoms and molecules using scanning tunneling microscopy (STM) and was one of the first persons to image molecules with STM. His past accomplishments include the first STM-based fabrication of molecular suprastructures at room temperature using mechanical forces to push molecules across surfaces, the discovery of single molecule rotors. He also developedf new micro-nano sensors based on nanotechnology, which explore ultimate limits of sensitivity and measurement.
This approach has been used to convert biochemical recognition into Nanomechanics. His current interests are in the nanomechanics of cells and bacteria where he collaborates with the UCLA Medical and Dental Schools. He is involved in projects that range from the operation of X-rays, ions and nuclear fusion using pyroelectric crystals, direct deposition of carbon nanotubes using atmospheric plasma techniques and single molecule DNA profiling. Recently his research has focused on self organization and emergent behavior using a device called the atomic switch network (ASN) which aimed at creating a synthetic neocortex using self assembly atomic switches that act as synthetic synapses. Dr. Gimzewski is also involved in numerous art-science collaborative projects that have been exhibited in museums throughout the world.