Energy Conversion, energy storage, nanomaterials, optical materials, photovoltaics, catalysis, electrical grid, energy storage

Biofuels; Separations Technology; Water

Heat Transfer; power generation; CO2 Capture; Catalysis; fuel cells; "Fedorov's research is at the interface of basic sciences and engineering. His research portfolio is diverse, covering the areas of portable/ distributed power generation with synergetic carbon dioxide management, including hydrogen/CO2 separation/capture and energy storage, novel approaches to nanomanufacturing (see Figure), microdevices (MEMS) and instrumentation for biomedical research, and thermal management of high performance electronics. Fedorov's research includes experimental and theoretical components, as he seeks to develop innovative design solutions for the engineering systems whose optimal operation and enhanced functionality require fundamental understanding of thermal/fluid sciences. Applications of Fedorov's research range from fuel reformation and hydrogen generation for fuel cells to cooling of computer chips, from lab-on-a-chip microarrays for high throughput biomedical analysis to mechanosensing and biochemical imaging of biological membranes on nanoscale. The graduate and undergraduate students working with Fedorov's lab have a unique opportunity to develop skills in a number of disciplines in addition to traditional thermal/fluid sciences because of the highly interdisciplinary nature of their thesis research. Most students take courses and perform experimental and theoretical research in chemical engineering and applied physics. Acquired knowledge and skills are essential to starting and developing a successful career in academia as well as in many industries ranging from automotive, petrochemical and manufacturing to electronics to bioanalytical instrumentation and MEMS."

Catalysis, Biochemicals, Biorefining, Chemistry, Sugars, Molecular Simulations, Computational Biology

"Dr. Jacob's research is directed at stress induced phase changes, nanoscale characterization of materials, synthesis of polymeric nanofibers, mechanical behavior of fiber assemblies (particularly related to biological systems and biomimitic systems), nanoparticle reinforced composites, transdermal drug delivery systems, large scale deformation of rubbery (networked) polymers, and nanoscale fracture of materials. The objectives in this work, using theoretical, computational and experimental techniques, is to understand the effect of micro- and nano- structures in the behavior of materials in order to try to design the micro/nano structures for specific materials response. Dr. Jacob plans are to continue current research interests with a multidisciplinary thrust with more emphasis in bio related areas and to start some work on the dynamic behavior of materials and structures. Graduate students could benefit from the interdisciplinary nature of the work combining classical continuum mechanics with nanoscale analysis for various applications, particularly in the nano and bio areas. Dr. Jacob has extensive experience in vibrations and stability of structures, mechanics of polymeric materials, behavior of fiber assemblies, stress-induced phase transformation, diffusion, and molecular modeling. His research involves the application of mechanics principles, both theoretical and experimental, in the analysis and design of materials for various applications.";Fibers; smart textiles; fuel cells; Polymeric composites

Separations Technology; Water

Catalysis; Biofuels

Separations Technology; Biofuels; Energy & Water; Separation Technologies