Primary goal of the center is to transfer the technology of validated theory and computational tools from the academic-based Center to the practitioners' development environment which is nanotechnology-based industry.
This course teaches numerate graduates knowledge and skills in the field of nanotechnology and microfabrication. The course takes an immersive approach to learning both the principles and practices of nanotechnology and microfabrication with much of the material based around examples and practical exercises. Students completing this course will have a firm grasp of the current practices and directions in this exciting area and will have the knowledge and skills to enable them to design and build microscale devices.
BICAMN includes focus areas in 'Nanodevices' and in 'Nanomaterials' that explore the basic science of nanoscale magnetism and optics and the structural details of novel nanoparticles and nanoscale thin films.
The scientific community grouped under the Ilse Katz Center aims to develop excellent, innovative fundamental research in the field of nano-scaled materials, that will lead to the opening of new technological horizons.
Nanoscale mineral particles -- nanoparticles -- are naturally formed and removed from the environment by numerous chemical and biological processes. The Center's mission is to uncover the numerous roles played by nanoparticles in geochemical and biogeochemical processes.
The Berkeley Nanosciences and Nanoengineering Institute (BNNI) is the umbrella organization for expanding and coordinating Berkeley research and educational activities in nanoscale science and engineering.
The Materials Science and Nanotechnology graduate program has started accepting applications. Students from departments of materials science, physics, electronics, chemistry, mechanical engineering, biotechnology, genetics, pharmacy, mechatronics, agriculture and textile can apply.
The Biologically Inspired Materials Institute (BIMat) was established by NASA under the University Research, Engineering and Technology Institute (URETI) program. The principal goal for BIMat researchers is to develop bio-nanotechnology materials and structures for aerospace vehicles.
The mission of the group is to provide a rewarding and nourishing atmosphere of hands-on cutting edge research for students to develop and grow professionally and technically and use as an opportunity to springboard to a professional career that will benefit them and society.
The department has a strong record of research, with faculty involved in both experimental and theoretical areas. Some areas of current interest are: novel electronic materials; carbon nanotubes and nanotube arrays; theory of marginal Fermi liquids; optical and transport properties of low- dimensional condensed matter systems; novel superconductors.
Research in Optical Characterization and Nanophotonics (OCN) laboratory focuses on developing and applying advanced optical characterization techniques to the study of solid-state and biological phenomena at the nanoscale.
Shiladitya Sengupta's laboratory is focused on developing engineering solutions for complex disease. The team's research lies at the interfaces of fundamental biology, medical applications and nanoscale engineering, where basic understanding of biology inspires the development of novel technology or medical applications.
Highly interdisciplinary and translational, the group's research is focused on multifunctional, nanoparticle-based drug delivery systems. They seek to improve nanoparticle synthesis and formulation and its therapeutic efficacy. Additionally, they develop robust engineering processes to accelerate translation of nanoparticle-based drugs into the drug development pipeline. At the same time, they emphasize a fundamental understanding of the interface between nanomaterials and biological systems.
The lab of Prof. Kenneth Breuer is active in research covering a wide variety of topics, including: Micron and nanometer scale fluid mechanics; Animal motion, in particular, bat flight and bacterial motility; Turbulent shear flows and shear flow control; Diagnostic methods for fluid mechanics.