Biomimetics through nanoelectronics: development of three-dimensional macroporous nanoelectronics for building smart materials, cyborg tissues and injectable biomedical electronics.

Nanoscale materials enable unique opportunities at the interface between physical and life sciences. The interface between nanoelectronic devices and biological systems makes possible communication between these two diverse systems at the length scale relevant to biological functions. The development of a bottom-up paradigm allows the nanoelectronic units to be synthesized and patterned on unconventional substrates. In this thesis, I will focus on the development of three-dimensional (3D) nanoelectronics, which mimics the structure of porous biomaterials to explore new methods for seamless integration of electronics with other materials, with a special focus on biological tissue.Chemistry and Chemical Biolog

Future Computer Requirements for Computational Aerodynamics

Recent advances in computational aerodynamics are discussed as well as motivations for and potential benefits of a National Aerodynamic Simulation Facility having the capability to solve fluid dynamic equations at speeds two to three orders of magnitude faster than presently possible with general computers. Two contracted efforts to define processor architectures for such a facility are summarized