First name,Last name,Preferred title,Overview,Position,Department,Individual
Peter,Rentzepis,Professor,My research interest include lasers and their application to science and technology.,Faculty Affiliate||Professor,Energy Institute||Electrical and Computer Engineering,https://scholars.library.tamu.edu/vivo/display/n08418952
Stratos,Pistikopoulos,Professor,"The objective of my research programme is to develop fundamental theory and optimization based methodologies and computational tools that enable process engineers to analyze, design and evaluate process manufacturing systems which are economically attractive, energy efficient and environmentally benign, while at the same time exhibit good performance characteristics like flexibility, controllability, robustness, reliability and safety.",Director||Professor,Energy Institute||Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/n1aaac28f
Virender,Sharma,Professor,"My research focuses on (1) chemistry and application of ferrates, (2) formation, fate, and toxicity of silver and gold engineered and natural nanoparticles in aquatic environment, (3) applications of ferrites to destroy toxins and pollutants under solar light, and apply carbon-based materials to remediate contaminated water",Faculty Affiliate||Professor,Energy Institute||Environmental and Occupational Health,https://scholars.library.tamu.edu/vivo/display/n28508dfb
Tahir,Cagin,Professor,"My research interests include: computational materials science and nanotechnology with emphasis on design; characterization and development of multifunctional nano-structured materials for device and sensor applications; fundamental studies on transport phenomena (heat, mass and momentum) at nanoscale and in confined media; thermal, mechanical, electronic and magnetic properties and phase behavior of materials; materials for thermal management, power generation and energy harvesting; and development and application of multiscale simulation methods.",Faculty Affiliate||Professor,Energy Institute||Materials Science and Engineering,https://scholars.library.tamu.edu/vivo/display/n299235a8
James,Batteas,Professor,"The research in our group is organized around three main projects: nanoscale materials and devices, biological surfaces and interfaces and nanotribology,
with the overarching goal of developing custom engineered surfaces and interfaces. This requires obtaining a fundamental (molecular level) understanding of the underlying chemistry and physics of the systems in question to afford rational approaches to test and develop new technologies. In much of our research we employ a range of scanned probe microscopies such as scanning tunneling microscopy (STM) and atomic force microscopy (AFM) to probe structure and to manipulate materials at the nanoscale.",Faculty Affiliate||Professor||Faculty Fellow||D. Wayne Goodman Professor of Chemistry,Center for Health Systems and Design||Energy Institute||Chemistry||Chemistry,https://scholars.library.tamu.edu/vivo/display/n413d1dff
Laszlo,Kish,Professor,Unsolved problems of random noise; Unconditionally secure communications over the wire; KLJN key exchanger; Noise-based logic and computation; Fluctuation-enhanced sensing; SEPTIC bacterium detection method; 1/f noise; Noise in high-Tc superconductors; Conductance noise at percolation; Noise spectrum in self-organized criticality; Stochastic resonance; Nanomaterials and structures; Lognormal distribution; Neuronal firing dynamics; Originality in scientific research; Physical informatics; Energy dissipation in computing and communications; Non-validity of the Landauer theorem; Information versus thermal entropy; etc.,Faculty Affiliate||Professor,Energy Institute||Electrical and Computer Engineering,https://scholars.library.tamu.edu/vivo/display/n4e482d22
Jorge,Seminario,Professor,"Dr. Seminario's research covers several aspects of nanotechnology such as the analysis, design, and simulation of systems and materials of nanometer dimensions--especially those needed for development and systems for energy, nanosensors and nanoelectronics. Among his recent goals is the design of smaller, cleaner, more efficient and faster devices for energy production and storage as well as for detection of chemical, biological and nuclear agents. He has developed new scenarios for nanodevice architectures using a multiscale and multidisciplinary approach that progresses from the atomistic level to the final product, guided by first principles calculations.",Faculty Affiliate||Professor,Energy Institute||Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/n563c3880
Sergio,Capareda,Professor,"Fluidized bed pyrolysis and gasification of biomass; biofuels and biopower production including biomass characterization; waste management, environmental air quality research, PM, GHG and RVOC emissions measurements; engine dynamometer testing; process design and development.",Professor||Faculty Affiliate,Biological and Agricultural Engineering||Energy Institute,https://scholars.library.tamu.edu/vivo/display/n5974e0e3
Mahmoud,El-Halwagi,Professor,"Dr. El-Halwagi's research is in the area of process design, integration, and optimization. The focus is on the development of systematic and generally applicable methodologies and tools that can guide engineers in the design and operation of gas and fuels processing facilities.",Faculty Affiliate||Professor,Energy Institute||Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/n5c26539a
Prasad,Enjeti,TI Jack Kilby Chair Professor,"My research focuses on advance power electronic converters for utility interface of solar-pv/wind/fuel-cell/battery-energy storage power systems, design of high temperature power conversion systems with wide band-gap semiconductor devices, new converter topologies for single/three phase solid state transformers (SSTs) with medium frequency isolation, medium voltage power converters for mega-watt scale solar-pv/wind/fuel-cell energy systems, adjustable speed drives with medium frequency transformer isolation, development of smart solar pv-systems for curved surfaces / BIPVs, power quality enhancement for interconnected renewables, Power Quality Issues: Design & development of Active Power Filters; Dynamic voltage restorer's (DVRs) and new & improved ride-through technologies employing Flywheel and Supercapacitors, and advancing switching power supply designs for portable power systems and modular fuel-cell systems.",Professor||TI Jack Kilby Chair Professor||Faculty Affiliate,Energy Institute||Electrical and Computer Engineering||Electrical and Computer Engineering,https://scholars.library.tamu.edu/vivo/display/n66ebcf36
Raymundo,Arroyave,Professor,"Dr. Arroyave obtained his BS degrees in Mechanical and Electrical Engineering from the Instituto Tecnol?gico y de Estudios Superiores de Monterrey (M?xico) in 1996. He got his MS in Materials Science and Engineering in 2000 and his PhD in Materials Science in 2004 from MIT. After a postdoc at Penn State, he joined the Department of Mechanical Engineering at Texas A&M University in 2006. He is currently a Professor in the Department of Materials Science and Engineering and holds courtesy appointments in the Departments of Mechanical Engineering and Industrial and Systems Engineering
Dr. Arroyave's area of expertise is in the field of computational materials science, with emphasis in computational thermodynamics and kinetics of materials. He and his group use different techniques across multiple scales to predict and understand the behavior of inorganic materials (metallic alloys and ceramics). The techniques range from ab initio methods, classical molecular dynamics, computational thermodynamics as well as phase-field simulations. Dr. Arroyave's group recent focus has been on simulation and data-enabled materials discovery and design in a wide range of contexts, including Additive Manufacturing.
Dr. Arroyave has been co-author of more than 250 publications in peer-reviewed journals, 20 conference proceedings as well as close to 120 conference papers and >130 invited talks in the US and abroad. He is the recipient of several awards, including NSF CAREER Award (2010), TMS Early Career Faculty Fellow (2012, Honorable Mention), TMS Brimacombe Medal (2019), ASM Fellow (2020), Acta Materialia Silver Medal (2023). He has been named Texas A&M Presidential Impact Fellow (2017) and Texas A&M University System Chancellor EDGES Fellow (2019). He currently holds the Segers Family Dean's Excellence Professorship.
He is an Associate Editor of Materials Letters, Integrating Materials and Manufacturing Innovation (IMMI) and the Journal of Phase Equilibria and Diffusion. He is involved in ASM and TMS, having served as Chair of the ASM Alloy Phase Diagram Committee, Chair of the TMS Functional Materials Division as well as member of the Board of Directors of TMS. He has chaired or co-chaired more than 20 symposia and has been the lead organizer and co-organizer of several international conferences.",Faculty Affiliate||Professor||Professor||Professor||Faculty Affiliate,Mechanical Engineering||Energy Institute||Materials Science and Engineering||Industrial and Systems Engineering||Institute for Engineering Education and Innovation,https://scholars.library.tamu.edu/vivo/display/n763870af
Kung-Hui (Bella),Chu,Professor,"Our research interests are in enhancing our understanding of microbial-mediated processes in natural and engineered systems, and in application and development of biotechnology to address various environmental challenges in water, soils, and energy. The Chu lab applies molecular biology, isotopic techniques, chemical analysis, and phage biology to study environmental and biological systems, with focuses on (i) microbial ecology, fate and transport, biodegradation of environmental pollutants such as emerging contaminants and persistent organic pollutants, (ii) production of biofuels and bioproducts from renewable resources, and (iii) detection, tracking, and quantification of microorganisms that play roles in water quality, bioremediation, carbon sequestration and nitrogen cycle in the environment. Other research areas include development and application of novel sorbents and catalysts (bio and non-bio) for removing and/or monitoring emerging environmental pollutants.",Faculty Affiliate||Professor,Civil Engineering||Energy Institute,https://scholars.library.tamu.edu/vivo/display/n7a373eec
Perla,Balbuena,Professor,,University Distinguished Professor||Faculty Affiliate||Professor,Energy Institute||Chemical Engineering||Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/nb82a0bc7
Marcelo Javier,Sanchez Castilla,Professor,"My research group effort focuses on advanced geomechanics, considering engineering problems involving mechanical, hydraulic, thermal, geochemical, and biological couplings. Problems in geotechnical engineering and geomechanics are generally strongly coupled with mutual interactions between different physics. Specific challenges include: the design of nuclear waste disposal, modeling the THMC behavior of gas hydrate sediments, the design of energy piles (and other forms of energy exchange with the ground), understanding the degradation of geomaterials due to climate change (including desiccation cracks), advancing the design of geological CO2 sequestration, improving our scientific understanding of hydraulic fracturing, and assisting energy production from existing and new sources.",Professor||Faculty Affiliate,Civil Engineering||Energy Institute,https://scholars.library.tamu.edu/vivo/display/nc712e4a2
Mark,Holtzapple,Professor,"Our group is dedicated to the research and development of the sustainable and renewable technologies which, when implemented on a commercial scale, will impact future fuel, chemical, food, and water production.",Faculty Affiliate||Professor,Energy Institute||Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/nd303ef41
David,Bergbreiter,Professor,"Our group explores new chemistry related to catalysis and polymer functionalization using the tools and precepts of synthetic organic chemistry to prepare functional oligomers or polymers that in turn are used to either effect catalysis in a greener, more environmentally benign way or to more efficiently functionalize polymers. Often this involves creatively combining the physiochemical properties of a polymer with the reactivity of a low molecular weight compound to form new materials with new functions. These green chemistry projects involve undamental research both in synthesis and catalysis but has practical aspects because of its relevance to practical problems.
A common theme in our catalysis studies is exploring how soluble polymers can facilitate homogeneous catalysis. Homogeneous catalysts are ubiquitously used to prepare polymers, chemical intermediates, basic chemicals and pharmaceuticals. Such catalysts often use expensive or precious metals or expensive ligands or are used at relatively high catalyst loadings. The products often contain traces of these catalysts or ligands - traces that are undesirable for esthetic reasons or because of the potential toxicity of these impurities. Both the cost of these catalysts of these issues require catalyst/product separation - separations that often are inefficient and lead to chemical waste. These processes also use volatile organic solvents - solvents that have to be recovered and separated. Projects underway in our lab explore how soluble polymers can address each of these problems. Examples of past schemes that achieve this goal in a general way as highlighted in the Figure below.
We also use functional polymers to modify existing polymers. Ongoing projects involve molecular design of additives that can more efficiently modify polymers' physical properties. We also use functional polymers in covalent layer-by-layer assembly to surface polymers' surface chemistry.",Faculty Affiliate||Professor,Energy Institute||Chemistry,https://scholars.library.tamu.edu/vivo/display/nf01e95dd
David,Powers,Professor,"Catalysis lies at the heart of many unmet chemical challenges. Research efforts in our group focus on development of new catalytic chemistry to impact both chemical synthesis as well as chemical storage of solar energy. Projects span organic, organometallic, and inorganic chemistries and rely on the tools of modern synthetic chemistry and spectroscopy, as well as advanced characterization techniques supported at synchrotron X-ray sources. Representative research interests include: shape-selective catalysis, solar energy storage in organic solar-thermal flow batteries, and aerobic oxidation chemistry for C-H functionalization reactions. We are seeking students who wish to gain expertise in synthetic chemistry and reaction mechanism elucidation.",Professor||Faculty Affiliate,Energy Institute||Chemistry,https://scholars.library.tamu.edu/vivo/display/nfa6c8878