Dr. Rick E. Russo has studied fundamental properties of laser material interactions and related applications for over 25 years. Dr. Russo earned a B.S. degree in Chemistry at the University of Florida (1976), and received his Ph.D. in Chemistry from Indiana University (1981), where he also completed his postdoctoral studies. Since 1982, he has held various positions at the Lawrence Berkeley National Laboratory in Berkeley, California, where he is currently a Senior Scientist. His background includes experience with state-of-the-art lasers, spectroscopic instrumentation, imaging systems, computers, and electronics. His research has included: fundamental studies of laser heating and laser ablation processes; improved chemical analysis using laser ablation inductively coupled plasma mass spectrometry; study and fabrication of high-temperature superconductor (HTSC) thin-films; fiber sensors for monitoring organic and radioactive species in groundwater; Raman, fluorescence, and photothermal spectroscopy of rare-earth and actinide ions; acoustic monitoring with optical fibers (laser ultrasonics, non-destructive evaluation); and the fabrication of porous optical materials (aerogels). He is co-inventor of the ion-assisted pulsed laser deposition (IBAD) and ion-texturing (ITEX) processes, and holds the world record for the highest critical current density (Jc) HTSC film on polycrystalline substrate (1992). Dr. Russo is co-discoverer of the nanowire laser, highlighted by a Science article and patent application in 2002. His credits include 200 scientific publications; 48 proceedings; 176 presentations (91 invited and plenary); 10 book chapters, 9 patents, and R&D100 award in 2006.
Direct Real-Time Determination of Compositional Profiles in Structured Materials Using Laser Ablation Instruments: LIBS and LA-ICP-MS
Femtosecond laser ablation particle introduction to a liquid sampling-atmospheric pressure glow discharge ionization source
Guiding and focusing of a nanosecond infrared laser within transient hollow plasma femtosecond filament channels
Laser ablation plasmas for diagnostics of structured electronic and optical materials during or after laser processing
Liquid sampling-atmospheric pressure glow discharge optical emission spectroscopy detection of laser ablation produced particles: A feasibility study
Rapid bulk analysis using femtosecond laser ablation inductively coupled plasma time-of-flight mass spectrometry