NCN@Illinois Video Team
This resource belongs to the NCN@Illinois Video Team group.
Dr. Gabriel Popescu is an Assistant Professor in the Department of Electrical and Computer Engineering, University of Illinois at Urbana-Champaign and holds a full faculty appointment with the Beckman Institute for Advance Science and Technology. He is also an affiliate faculty in the Bioengineering Department. Prof. Popescu received the B.S. and M.S. in Physics from University of Bucharest, in 1995 and 1996, respectively. He obtained his M.S. in Optics in 1999 and the Ph.D. in Optics in 2002 from the School of Optics/ CREOL (now the College of Optics and Photonics), University of Central Florida. Dr. Popescu continued his training with the G. R. Harrison Spectroscopy Laboratory at M.I.T., working as a postdoctoral associate. He joined UIUC in August 2007. (Source:http://light.ece.illinois.edu/index.html/qli-team/prof-gabriel-popescu/)
Dr.Arthur Kramer is the Director of the Beckman Institute for Advanced Science & Technology (as of June 2010) and the Swanlund Chair and Professor of Psychology and Neuroscience at the University of Illinois. He received his Ph.D. in Cognitive/Experimental Psychology from the University of Illinois in 1984. He holds appointments in the Department of Psychology, Neuroscience program, and the Beckman Institute. Professor Kramer's research projects include topics in Cognitive Psychology, Cognitive Neuroscience, Aging, and Human Factors. A major focus of his labs recent research is the understanding and enhancement of cognitive and neural plasticity across the lifespan. He is a former Associate Editor of Perception and Psychophysics and is currently a member of six editorial boards. Professor Kramer is also a fellow of the American Psychological Association, American Psychological Society, a former member of the executive committee of the International Society of Attention and Performance, and a recent recipient of a NIH Ten Year MERIT Award. Professor Kramer's research has been featured in a long list of print, radio and electronic media including the New York Times, Wall Street Journal, Washington Post, Chicago Tribune, CBS Evening News, Today Show, NPR and Saturday Night Live. (Source:http://www.psychology.illinois.edu/people/a-kramer)
Dr. Michael F. Insana received his PhD in medical physics from the University of Wisconsin, Madison in 1983. His dissertation topic was acoustic scattering and absorption in biological tissues. He was a research physicist at the FDA from 1984-1987, Professor of Radiology and Physiology at the University of Kansas Medical Center from 1987-1999, and Professor of Biomedical Engineering at the University of California, Davis from 1999-2004. Currently, Mike is a Professor of Bioengineering at UIUC and an affiliate faculty member of the Electrical and Computer Engineering Department and the Beckman Institute for Advanced Science and Technology. His research focuses on the development of novel ultrasonic instrumentation and methods for imaging soft tissue microstructure, elasticity and blood flow. The goal is to understand basic mechanisms of lesion formation, disease progression, and responses to therapy. His research includes the fundamentals of imaging system design and performance evaluation, signal processing, detection and estimation. His lab uses hydrogels to develop models of visco- and poroelastic behavior of soft tissues for cancer imaging. Through collaborations with industry, Insana's lab is investigating spatio-temporal filtering for noise reduction and enhanced spatial resolution with applications in breast elasticity imaging and arterial-wall shear-stress estimation.
Mike is currently a member of the IEEE and Acoustical Society of America, Fellow of the Institute of Physics, and Associate Editor for IEEE Transaction on Medical Imaging. (Source:http://www.brl.uiuc.edu/People/michael_f_insana.php)
Dr. Umberto Ravaioli has research focuses on large scale simulation of charge transport phenomena in solid-state and soft-matter systems. My group investigates the properties of ultra-scaled MOS devices, including size-quantization in nanoscale channels and thermal phenomena, particularly generation and transport of phonons. Transport is studied with particle Monte Carlo models with corrections to account for size quantization. This work has led to the development of the Monte Carlo simulator MOCA 2D and MOCA 3D. In the soft-matter area, transport of ions in nanoscale biological and biomimetic membranes are being investigated using similar engineering approaches based on Monte Carlo simulation where the water background is included implicitly. Simulations work has focused on the study of biological ionic channels, with the development of the transport Monte Carlo code bioMOCA, a full 3-D self-consistent simulator. Large scale studies with bioMOCA are conducted on the national TeraGrid computational infrastructure, in collaboration with the Network for Computational Nanotechnology (NCN) and the NIH Center for Design of Biomimetic Nanoconductors and the National Center for Supercomputing Applications (NCSA). Educational activities are also carried out in co-operation with the National Center for Learning and Teaching of Nanoscale Science and Engineering (NCLT) for which we are developing interactive numerical tools and simulators, suitable for teaching activities and demonstrations at high-school and college level. (Source: http://www.ece.illinois.edu/directory/profile.asp?ravaioli)
Dr. Irfan Ahmad is the executive Director, University of Illinois Center for Nanoscale Science and Technology; and Research Faculty at the Department of Agricultural and Biological Engineering. Dr. Ahmad is working at the confluence of bio- and nano technologies, with research and development of biosensors for agriculture, food, and biomedical applications using nanoscale technology. He also facilitates cross campus multidisciplinary research, industry and government linkages, and research fora. (Source:http://www.csames.illinois.edu/people/faculty/)
Dr. Stephen Boppart graduated from the University of Illinois at Urbana-Champaign (UIUC) in 1990 with a B.S. in Electrical Engineering and an option in Bioengineering. Continuing at UIUC, he completed his M.S. in Electrical Engineering in 1991, where he developed microfabricated multi-electrode arrays for neural recordings. From 1991 to 1993, at the Air Force Laser Laboratory in San Antonio, Texas, he conducted research on laser-tissue interactions in the eye, helping establish national laser safety standards. Prof. Boppart then went on to MIT, receiving his Ph.D. in 1998 in Medical and Electrical Engineering. His doctoral studies included the development of optical coherence tomography in Prof. Jim Fujimoto's laboratory. As part of a joint program between MIT and Harvard, Prof. Boppart completed his M.D. from Harvard Medical School in June 2000. Currently, Prof. Boppart is a full professor with appointments in the Departments of Electrical and Computer Engineering, Bioengineering, and Medicine at UIUC. He is Head of the Biophotonics Imaging Laboratory at the Beckman Institute for Advanced Science and Technology and along with a team of 25 researchers, is investigating novel optical diagnostic imaging technologies for basic science and translational clinical applications. From 2006-2008, he served as Founding Director of the Mills Breast Cancer Institute, and holds a joint position with Carle Foundation Hospital and Carle Clinic Association in Urbana, Illinois. His efforts included constructing a new building and developing new infrastructure to support translational research and technology development in breast cancer research between UIUC and Carle Foundation Hospital. Currently he is initiating efforts to direct a campus-wide Illinois Imaging Initiative intended to leverage the strengths and diversity of over 100 faculty working in all aspects of imaging science, technology, and application. (Source: http://www.ece.illinois.edu/directory/profile.asp?boppart)
Researchers should cite this work as follows:
Gabriel Popescu (2012), "[Illinois] Biophotonics 2012: Welcome," http://nanohub.org/resources/14052.