Faculty Research Interests

For a more detailed description of each faculty members work, please click on their name or photo.

Dr. Reza Abedi

Our research interests are in general areas of applied mathematics, computational mechanics, and fracture modeling. The development of advanced numerical schemes, such as spacetime discontinuous Galerkin finite element methods, and the investigation of their convergence, efficiency, scalability, and robustness are some themes of our research. These methods are capable of obtaining extraordinarily efficient and accurate solutions for a wide array of multiphysics applications in solid, fluid, and thermal mechanics, electromagnetics, and acoustics, particularly for highly multiscale and parallel simulations and problems with nonsmooth features such as shocks and singular features.

 

 


Dr. Ying-Ling Chen

Current research activities include Laser spectroscopy applications: Laser-induced initiation, CFDRC rocket health diagnostics and Visual science applications: Computational evaluation of ocular screening algorithm, Cornea (dry eye, cornea scars, keratoconus) and lens (cataract) screening instrumentation, Pediatric vision screening instrumentation, Ophthalmic measurement simulation for medical training, and Race-, age-, and gender-specified eye modeling.

 

 

 


Dr. Horace Crater

Dr. Crater’s work is in the area of theoretical physics, mainly relativistic quantum and classical mechanics, classical and quantum field theory; Two-Body Dirac equations with applications to the quark models for mesons, the electron-positron system, nucleon-nucleon scattering, meson decay, meson-meson scattering, the quark-gluon plasma; Dirac’s Hamiltonian Constraint Dynamics with applications to the N-body problem in electrodynamics; the problem of the relativistic center of mass and its applications to orbits.

 

 

 


Dr. Lloyd Davis

Interest lie in three areas of physics – Experimental : non-linear optics, quantum optics, ultrafast laser phenomena, femtosecond spectroscopy, applied optics, optical design, single-photon detectors and electronics, laser-material and laser-plasma interactions; Interdisciplinary : single-molecule detection and spectroscopy, biophotonics, biophysics, chemical physics, biotechnology, nanotechnology, genomic technology, advanced microscopy; and Numerical : Monte Carlo simulations, cluster computing; Theoretical physics: fundamental quantum theory.

 

 


Dr. William Hofmeister

Professor Hofmeister is Director of the Center for Laser Applications and is involved in research using lasers for fabrication and modification of materials particularly on the nanoscale. He has contributed to the science of nucleation and solidification kinetics and is engaged in research on diamond films for microelectronics, nanomaterials, surface modification, and high-temperature, erosion resistant materials.

 

 

 


Dr. Jacqueline Johnson

Jacqueline Johnson studies the structure and properties of glasses, glass-ceramics, and diamond-like carbon films. She is currently working on an NIH project to develop a new mammography system (incorporating a glass-ceramic plate) in collaboration with scientists from Germany and SUNY, Stony Brook. A small company, Materials Research Development Inc., is responsible for scale-up of the plate.

 

 

 

 


Dr. Trevor Moeller

Dr. Moeller has broad interests in plasma physics and electromagnetics. Areas of interest include: modeling and testing of electric propulsion devices, electromagnetic acceleration, plasma diagnostics, generation of nonthermal plasmas for chemical processing and surface treatment, utilization of plasmas for hydrogen production and materials processing.

 

 

 

 


Dr. Christian Parigger

Dr. Parigger has research interests in experimental and theoretical physics, particularly in electromagnetic interactions, quantum optics, atomic and molecular physics. He has experience in argon-ion and narrow-line dye lasers, high vacuum physics, digital electronics, sub-picosecond laser systems, optical pico-second amplifiers, nano-second pulsed eximer and dye lasers. His research includes time-resolved spectroscopy; high power phenomena; laser induced plasma physics; and spectroscopic temperature measurements using atomic lines and molecular spectra.

 

 


Dr. L. Montgomery (Monty) Smith

Dr. Smith works in a variety of fields involving the use of electrical engineering in multidisciplinary research. Research interests include electro-optics, image processing, digital signal processing, and statistical data analysis. His recent research has involved interferometric investigation of plasma sources, analysis of signals from strain gauges, and the application of communication theory principles to engine test telemetry.

 

 

 


Dr. Peter Solies

Advancement of Aero-Space vehicle technology, design optimization, applied aerodynamics, powered lift, stability and control, composite structures, and human factors engineering.

 

 

 

 


Dr. Ahmad Vakili

Dr. Zhongren Yue’s research interests include: Preparation, surface modification, and characterization of high-performance carbon fibers; Fabrication and characterization of fiber reinforced composites; Design and synthesis of high surface area, porous materials; and Advanced materials (adsorbents, ion exchangers, and membranes) for water and air purification.

 

 

 

 


Dr. Zhongren Yue

Interest lie in three areas of physics – Experimental : non-linear optics, quantum optics, ultrafast laser phenomena, femtosecond spectroscopy, applied optics, optical design, single-photon detectors and electronics, laser-material and laser-plasma interactions; Interdisciplinary : single-molecule detection and spectroscopy, biophotonics, biophysics, chemical physics, biotechnology, nanotechnology, genomic technology, advanced microscopy; and Numerical : Monte Carlo simulations, cluster computing; Theoretical physics: fundamental quantum theory

 

 


Dr. Feng-Yuan Zhang

Dr. Zhang’s research interests lie in thermal-fluid sciences, nanotechnology, and advanced spectroscopies and diagnostics. The goal is to develop high-efficiency, low-cost and sustainable power and propulsion devices, such as fuel cells, electrolyzers, batteries, direct combustion engines, and electric thrusters. The research includes: Micro-/nano-scale fluidics, transport, heat transfer and combustion; Novel multifunctional materials; MEMS/NEMS; Electrochemical energy storage and conversions; Alternative fuel; Laser, optical, x-ray and electron spectroscopies.