Spectroscopy

Koen Visscher is an Associate Professor in the Department of Physics with an interest in Biological Physics. He holds joint appointments in Molecular and Cellular Biology as well as in the College of Optical Sciences, and is a member of the Applied Mathematics Graduate Interdisciplinary Program. His research focuses on the role of mechanical force in Biology using single-molecule techniques such as optical tweezers. He pioneered the so called molecular force clamp, a feedback controlled optical tweezers that is able to maintain a constant force on a single individual moving motor protein. Recent interests are RNA structure, nucleic acid-protein interactions interactions, and translational recoding via -1 frameshifting.

Jeanne Pemberton, PhD, is a household name in chemistry departments across the country. Her research on surface vibrational spectroscopy has enabled fundamental advances in the field of analytical chemistry.In her 25 years at The University of Arizona, Pemberton has received more than 40 research grants. Among the many boards and committees she serves, she was the chair of the Math and Physical Sciences Advisory Committee at the National Science Foundation in 2004. In addition to receiving the College of Science Distinguished Teaching Award, she has also received the distinguished American Chemical Society Award for Excellence in Analytical Chemistry, which is among the highest honors in her field.Dr. Pemberton’s group research seeks to develop an understanding of chemistry in several technologically important areas including electrochemistry and electrochemically-related devices, chromatography, self-assembled monolayers, surfactant systems, and environmental and atmospheric systems. Methodologies employed for these efforts include surface vibrational spectroscopies, near-field optical methods, electrochemistry, x-ray photoelectron spectroscopy, Auger electron spectroscopy, LEED, work function measurements, ellipsometry, electron microscopy, and the scanning probe microscopies AFM and STM. Molecular nanoscale imaging exists prominently in the ability to elucidate structural and mechanistic details of surface and interfacial chemistry.Two images of transient intermediate states on NaCl in its reaction with the mineral acids, HNO3 and H2SO4, are shown below. These transient structures are formed en route to the final surface products of crystalline NaNO3 and NaHSO4, respectively.Specific interfacial systems of interest include electrochemical battery and electroluminescent and electrochromic devices, models of these devices fabricated and studied in ultrahigh vacuum, organized molecular assemblies at solid surfaces or air-water interfaces formed spontaneously or by self-assembly or Langmuir-Blodgett techniques, chromatography stationary phase systems, soil and mineral systems important in the fate and transport of environmentally important chemicals, and surfaces such as ice, mineral acids, and alkali halides important in atmospheric processes.

Michael F. Brown is Professor of Chemistry & Biochemistry at the University of Arizona. He is co-director of the Biological Physics Program and the Chemical Physics Program, and was a co-founder of the Biological Chemistry Program at the University of Arizona. He is internationally renowned for his work on the molecular basis of activation of G-protein-coupled receptors that are the targets for the majority of pharmaceuticals and medicines used by humans. The focus of his work is on biomembranes, with a particular emphasis on lipid-protein interactions in relation to potential drug targets involving membrane proteins. He is involved with investigation of the molecular basis of visual signaling involving rhodopsin. Moreover, Professor Brown is an expert in nuclear magnetic resonance (NMR) spectroscopy. His activities in the area of biomolecular NMR spectroscopy involve the devolvement and application of methods for studying the structure and dynamics of biomolecules. Michael Brown has authored over 130 original research papers, 10 book chapters, 4 book reviews, and has published more than 275 abstracts. His current H-index is 43. He numbers among his coworkers various prominent scientists worldwide. He presents his work frequently at national and international conferences, and is the recipient of a number of major awards. Professor Brown's many contributions have established him as a major voice in the area of biomembrane research and biomolecular spectroscopy. He is frequently a member of various review panels and exerts an influence on science policy at the national level. Among his accolades, he is an elected Fellow of the American Association for the Advancement of Science; American Physical Society; Japan Society for the Promotion of Science; and the Biophysical Society. He is a Fellow of the Galileo Circle of the University of Arizona. Most recently, he received the Avanti Award of the Biophysical Society. This premier honor recognizes his vast and innovative contributions to the field of membrane biophysics, and groundbreaking work in the development of NMR techniques to characterize lipid structure and dynamics. Most recently he presented the 2014 Avanti lecture of the Biophysical Society.

Jennifer Barton, Ph.D. is known for her development of miniature endoscopes that combine multiple optical imaging techniques, particularly optical coherence tomography and fluorescence spectroscopy. She evaluates the suitability of these endoscopic techniques for detecting early cancer development in patients and pre-clinical models. She has a particular interest in the early detection of ovarian cancer, the most deadly gynecological malignancy. Additionally, her research into light-tissue interaction and dynamic optical properties of blood laid the groundwork for a novel therapeutic laser to treat disorders of the skin’s blood vessels. She has published over 100 peer-reviewed journal papers in these research areas. She is currently Professor of Biomedical Engineering, Electrical and Computer Engineering, Optical Sciences, Agriculture-Biosystems Engineering, and Medical Imaging at the University of Arizona. She has served as department head of Biomedical Engineering, Associate Vice President for Research, and is currently Director of the BIO5 Institute, a collaborative research institute dedicated to solving complex biology-based problems affecting humanity. She is a fellow of SPIE – the International Optics Society, and a fellow of the American Institute for Medical and Biological Engineering. Keywords: bioimaging, biomedical optics, biomedical engineering, bioengineering, cancer, endoscopes