Cyrus Aidun

Cyrus Aidun

Cyrus Aidun

Professor

Dr. Aidun joined the Woodruff School as a Professor in 2003 after completion of a two-year period as program director at the National Science Foundation. He began at Tech in 1988 as an Assistant Professor at the Institute of Paper Science and Technology. Prior, he was a research Scientist at Battelle Research Laboratories, Postdoctoral Associate at Cornell University and Senior Research Consultant at the National Science Foundation's Supercomputer Center at Cornell. 

Dr. Aidun's research is at the intersection between fundamentals of the physics of complex fluids/thermal transport and applications to engineering and biotransport. He has a diverse research portfolio in fluid mechanics, bioengineering, renewable bioproducts and decarbonization of industrial processes. 

A major focus has been to understand the physics of blood cell transport and interaction with glycoproteins (e.g., vWF) with applications to cardiovascular diseases.

cyrus.aidun@me.gatech.edu

404-894-6645

Office Location:
Love Building, Room 320

Website

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    Research Focus Areas:
  • Biobased Materials
  • Biochemicals
  • Biorefining
  • Biotechnology
  • Conventional Energy
  • Molecular, Cellular and Tissue Biomechanics
  • Pulp Paper Packaging & Tissue
  • Sustainable Manufacturing
  • Additional Research:
    Computational analysis of cellular blood flow in the cardiovascular system with applications to platelet margination, thrombus formation, and platelet activation in artificial heart valves. Thermal Systems. Chemical Recovery; Papermaking.

    IRI Connections:

    Victor Breedveld

    Victor Breedveld

    Victor Breedveld

    Associate Chair for Undergraduate Studies
    Professor and Frank Dennis Faculty Fellow

    victor.breedveld@chbe.gatech.edu

    404.894.5134

    Office Location:
    Ford Environmental Science & Technology Building, Room 1222

    ChBE Profile

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    Research Focus Areas:
  • Biobased Materials
  • Bioengineering
  • Biomaterials
  • Biorefining
  • Biotechnology
  • Energy
  • Additional Research:
    Biofuels; Papermaking, Coatings & Barriers; Films & Coatings; Biomaterials; Structure and Reheology of Complex fluids; Rheology of Bioengineering Materials

    IRI Connections:

    Blair Brettmann

    Blair Brettmann

    Blair Brettmann

    Assistant Professor, School of Chemical and Biomolecular Engineering and Material Science and Engineering
    RBI Co-Lead: Interface of polymer science and wood-based materials

    Blair Brettmann received her B.S. in chemical engineering at the University of Texas at Austin in 2007. She received her Master’s in chemical engineering practice from MIT in 2009 following internships at GlaxoSmithKline (Upper Merion, PA) and Mawana Sugar Works (Mawana, India). Blair received her Ph.D. in chemical engineering at MIT in 2012 working with the Novartis-MIT Center for Continuous Manufacturing under Professor Bernhardt Trout. Her research focused on solid-state characterization and application of pharmaceutical formulations prepared by electrospinning. Following her Ph.D., Brettmann worked as a research engineer for Saint-Gobain Ceramics and Plastics for two years. While at Saint-Gobain she worked on polymer-based wet coatings and dispersions for various applications, including window films, glass fiber mats and architectural fabrics. Later, Brettmann served as a postdoctoral researcher in the Institute for Molecular Engineering at the University of Chicago with Professor Matthew Tirrell. Currently, Brettmann is an assistant professor with joint appointments in chemical and biomolecular engineering and Materials Science and Engineering at Georgia Tech.

    blair.brettmann@mse.gatech.edu

    404.894.2535

    Office Location:
    MoSE 31100P

    Website

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    Research Focus Areas:
  • Biobased Materials
  • Biochemicals
  • Biomaterials
  • Biorefining
  • Biotechnology
  • Drug Design, Development and Delivery
  • Pulp Paper Packaging & Tissue
  • Sustainable Manufacturing
  • Additional Research:
    Pharmaceuticals, polymer and fiber, printing technologies, polymers, nanocellulose applications, new materials, wet-end chemistry, manufacturing, biotechnology, cellulosic nanomaterials, chemistry, biomaterials, aerogels and hydrogels, coating, coatings and barriers, films and coatings

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    Fani Boukouvala

    Fani Boukouvala

    Fani Boukouvala

    Assistant Professor

    Dr. Boukouvala is originally from Piraeus, which is the port of Athens in Greece. As the daughter of an airforce pilot, she travelled a lot with her family. Her first international move was actually to the USA, where she spent one year in Montgomery, Alabama. She later on lived in Riyadh, Saudi Arabia and Crete, Greece, before returning to Athens to get her B.S Degree in Chemical Engineering from the National Technical University in Athens. In 2008, she moved back to the US to obtain a PhD in Chemical Engineering at Rutgers University in NJ. She then worked as a Postdoctoral Associate in both Princeton University and Texas A&M University. In August 2016, Dr. Boukouvala returned to the South East US, as an Assistant Professor in the School of Chemical & Biomolecular Engineering at Georgia Tech. 

    Her research interest in Process Systems Engineering (PSE) started during her PhD years, where she worked under the supervision of Dr. Marianthi Ierapetritou, on modeling and optimization of continuous pharmaceutical manufacturing. Her background on optimization and data-driven modeling was enhanced during her years as a postdoc with the late Christodoulos A. Floudas. Dr. Boukouvala is a proud 4th generation member of the academic family tree of the father of PSE, Roger Sargent.

    fani.boukouvala@chbe.gatech.edu

    (404) 385-5371

    Website

    University, College, and School/Department
    Research Focus Areas:
  • Biobased Materials
  • Biochemicals
  • Biorefining
  • Biotechnology
  • Pulp Paper Packaging & Tissue
  • Sustainable Manufacturing
  • Use & Conservation
  • Additional Research:
    System Design & Optimization; Energy; Sustainability

    IRI Connections:

    Andreas Bommarius

    Andreas Bommarius

    Andreas Bommarius

    Professor
    RBI Initiative Lead: A Renewables-based Economy from WOOD (ReWOOD)

    Andreas (Andy) S. Bommarius is a professor of Chemical and Biomolecular Engineering as well of Chemistry and Biochemistry at the Georgia Institute of Technology in Atlanta, GA.  He received his diploma in Chemistry in 1984 at the Technical University of Munich, Germany and his Chemical Engineering B.S. and Ph.D. degrees in 1982 and 1989 at MIT, Cambridge, MA.

    From 1990-2000, he led the Laboratory of Enzyme Catalysis at Degussa (now Evonik) in Wolfgang, Germany, where his work ranged from immobilizing homogenous catalysts in membrane reactors to large-scale cofactor-regenerated redox reactions to pharma intermediates.

    At Georgia Tech since 2000, his research interests cover green chemistry and biomolecular engineering, specifically biocatalyst development and protein stability studies.  His lab applies data-driven protein engineering to improve protein properties on catalysts ranging from ene and nitro reductases to cellobiohydrolases.  Bommarius has guided the repositioning of the curriculum towards Chemical and Biomolecular Engineering by developing new courses in Process Design, Biocatalysis and Metabolic Engineering, as well as Drug Design, Development, and Delivery (D4), an interdisciplinary course with Mark Prausnitz.

    Andy Bommarius in 2008 became a Fellow of the American Institute of Medical and Biological Engineering.  Since 2010, he is Director of the NSF-I/UCR Center for Pharmaceutical Development (CPD), a Center focusing on process development, drug substance and product stability, and novel analytical methods for the characterization of drug substances and excipients.

    andreas.bommarius@chbe.gatech.edu

    404-385-1334

    Office Location:
    EBB 5018

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    Research Focus Areas:
  • Biobased Materials
  • Biochemicals
  • Biorefining
  • Biotechnology
  • Drug Design, Development and Delivery
  • Molecular Evolution
  • Pulp Paper Packaging & Tissue
  • Renewable Energy
  • Sustainable Manufacturing
  • Additional Research:
    Biomolecular engineering, especially biocatalysis, biotransformations, and biocatalyst stability. Biofuels. Enzymatic Processing; Biochemicals; Chip Activation.

    IRI Connections:

    Faisal Alamgir

    Faisal Alamgir

    Faisal Alamgir

    Professor, School of Materials Science and Engineering
    Initiative Lead, Advanced Real-time Materials Characterization

    faisal.alamgir@mse.gatech.edu

    404.385.3263

    Office Location:
    Love 373

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    Research Focus Areas:
  • Delivery & Storage
  • Fuels & Chemical Processing
  • Hydrogen Production
  • Hydrogen Utilization
  • Materials for Energy
  • Additional Research:
    Energy Conversion, energy storage, nanomaterials, optical materials, photovoltaics, catalysis, electrical grid, energy storage

    IRI Connections:

    Saad Bhamla

    Saad Bhamla

    Saad Bhamla

    Assistant Professor

    Saad Bhamla studies biomechanics across species to engineer knowledge and tools that inspire curiosity.

    Saad Bhamla is an assistant professor of biomolecular engineering at Georgia Tech. A self-proclaimed "tinkerer," his lab is a trove of discoveries and inventions that span biology, physics and engineering. His current projects include studying the hydrodynamics of insect urine, worm blob locomotion and ultra-low-cost devices for global health. His work has appeared in the New York Times, the Economist, CNN, Wired, NPR, the Wall Street Journal and more.

    Saad is a prolific inventor and his most notable inventions includes a 20-cent paper centrifuge, a 23-cent electroporator, and the 96-cent hearing aid. Saad's work is recognised by numerous awards including a NIH R35 Outstanding Investigator Award, NSF CAREER Award, CTL/BP Junior Faculty Teaching Excellence Award, and INDEX: Design to Improve Life Award. Saad is also a National Geographic Explorer and a TED speaker. Newsweek recognized Saad as 1 of 10 Innovators disrupting healthcare.

    Saad is a co-founder of Piezo Therapeutics.

    Outside of the lab, Saad loves to go hiking with his partner and two dogs (Ollie and Bella).

    saadb@chbe.gatech.edu

    404-894-2856

    Office Location:
    ES&T L1224

    Website

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    Research Focus Areas:
  • Biobased Materials
  • Biochemicals
  • Biomaterials
  • Biorefining
  • Biotechnology
  • Molecular, Cellular and Tissue Biomechanics
  • Pulp Paper Packaging & Tissue
  • Sustainable Manufacturing
  • Additional Research:
    Biotechnology; Complex Systems; Materials and Nanotechnology. The Bhamla Lab explores fundamental and applied research questions through the development of new experimental tools and techniques at the intersection of soft matter, organismic physics and global health. Ultra-fast Organismic Physics Biologists are just starting to systematically examine ultrafast motion across species (jellyfish, mantis shrimp, trap-jaw ants), some of which achieve accelerations exceeding a million g-forces in nanoseconds. At the single-cell level, the physical biology of ultra-fast motility remains poorly understood. What is the fastest motion a single cell can achieve? How do single-cell organisms amplify power and survive repeated high accelerations? These fundamental questions guide our exploration of several non-model unicellular and multicellular organisms to uncover the principles of extreme motility at cellular scales. Biological Soft Matter Our bodies are composed almost entirely of soft, wet, squishy materials. How do the fundamental principles of soft matter and complex fluids enable us to grasp dynamic processes, from the self-assembly of proteins to the stretching of a spider web? We study a spectrum of biological soft matter, from the tears on our eyes to biological foams from insects, with the goal of connecting the microscale structures (lipids, proteins) to their consequences for macroscale biological function (contact lens-eye interaction, microbiome health). As engineers, we leverage this understanding for human-health applications, ranging from diagnostics and monitoring to artificial therapeutic replacements and biomedical devices. Frugal Science and GlobalHealth Today, although information is free to anyone with internet, access to scientific tools and healthcare devices still has many barriers. How do we design and build tools that are scientifically rigorous, but cost a few cents on the dollar? Driven by the spirit of doing “frugal science”, we box ourselves in to find out of the box solutions for global challenges in science education, agriculture, and healthcare. Projects in this area include field-work, science outreach, and citizen-science initiatives. Disciplines: Biotechnology Complex Systems Materials and Nanotechnology

    IRI Connections:

    Vinayak Agarwal

    Vinayak Agarwal

    Vinayak Agarwal

    Assistant Professor

    Vinny is an Assistant Professor at Georgia Tech with joint appointments at the School of Chemistry and Biochemistry and School of Biological Sciences.

    A majority of antibiotics and drugs that we use in the clinic are derived or inspired from small organic molecules called Natural Products that are produced by living organisms such as bacteria and plants. Natural Products are at the forefront of fighting the global epidemic of antibiotic resistant pathogens, and keeping the inventory of clinically applicable pharmaceuticals stocked up. Some Natural Products are also potent human toxins and pollutants, and we need to understand how these toxins are produced to minimize our and the environmental exposure to them.

    We as biochemists ask some simple questions- how and why are Natural Products produced in Nature, what we can learn from Natural Product biosynthetic processes, and how we can exploit Nature's synthetic capabilities for interesting applications?

    Broadly, we are interested in questions involving (meta)genomics, biochemistry, structural and mechanistic enzymology, mass spectrometry, analytical chemistry, and how natural product chemistry dictates biology.

    vagarwal@gatech.edu

    404-385-3798

    Office Location:
    Petit Biotechnology Building, Office 3315

    Website

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  • Research Focus Areas:
  • Molecular, Cellular and Tissue Biomechanics
  • Additional Research:
    A majority of antibiotics and drugs that we use in the clinic are derived or inspired from small organic molecules called Natural Products that are produced by living organisms such as bacteria and plants. Natural Products are at the forefront of fighting the global epidemic of antibiotic resistant pathogens, and keeping the inventory of clinically applicable pharmaceuticals stocked up. Some Natural Products are also potent human toxins and pollutants, and we need to understand how these toxins are produced to minimize our and the environmental exposure to them. We as biochemists ask some simple questions- how and why are Natural Products produced in Nature, what we can learn from Natural Product biosynthetic processes, and how we can exploit Nature's synthetic capabilities for interesting applications? Broadly, we are interested in questions involving (meta)genomics, biochemistry, structural and mechanistic enzymology, mass spectrometry, analytical chemistry, and how natural product chemistry dictates biology.

    IRI Connections:

    Lily Cheung

    Lily Cheung

    Lily Cheung

    Assistant Professor

    Lily Cheung got her research start as a sophomore at Rutgers University, where she graduated Summa Cum Laude with a B.S. in Chemical Engineering in 2008. She then earned her Ph.D. in Chemical Engineering from Princeton University in 2013. Under the supervision of Stanislav Shvartsman, she characterized gene regulatory networks controlling the development of the model organism Drosophila melanogaster, using a combination of molecular biology, genetics, and reaction-diffusion modeling.

    During her postdoctoral training with Wolf Frommer at the Carnegie Institution for Science, she designed biomolecular sensors to quantify sugar transport in plants. Her current interests include the use of high-throughput quantitative techniques and mathematical modeling to advance our understanding of how metabolic and gene regulatory networks interact to control plant growth.

    Lily is the recipient of a NSF NPGI Postdoctoral Fellowship in Biology, a NSF CAREER Award, and a Human Frontier Science Program Early Career Award.

    lily.cheung@gatech.edu

    404-894-2826

    Office Location:
    ES&T L1230

    Website

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  • Research Focus Areas:
  • Systems Biology
  • Additional Research:
    Engineering of genetically encoded biosensors Quantitative fluorescence microscopy and image analysis Computational models of gene regulatory networks Transcriptional regulation and developmental biology of plants The past fifteen years has seen dramatic advancements in genome sequencing and editing. The cost of sequencing a genome has decreased by two orders of magnitude, giving rise to new systems-level approaches to biology research that aim to understand life as an emerging property of all the molecular interactions in an organism. At the same time, technologies that allow site-specific modifications of the genome are enabling researchers to manipulate multicellular organisms in unprecedented ways. From reductionist approaches to systems biology, and from conventional plant breeding to synthetic biology, the future of plant biology research relies on the adoption of computational methods to analyze experimental data and develop predictive models. In biomedicine, mathematical models are already revolutionizing drug discovery; in agriculture, they have the potential to generate more efficient, faster growing crop varieties. The goal of the Cheung lab is to bring quantitative techniques and mathematical modeling to plants in order to gain systems-level insight into their physiology and development - particularly to understanding how metabolic and gene regulatory networks interact to control homeostasis and growth.

    IRI Connections:

    Karl Jacob

    Karl Jacob

    Karl Jacob

    Professor, School of Materials Science and Engineering and School of Mechanical Engineering

    Karl I. Jacob, a professor of Materials Science and Engineering with a joint appointment in the G. W. Woodruff School of Mechanical Engineering, teaches graduate and undergraduate courses on polymer physics and engineering, rheology, and mechanics of polymeric materials. His graduate work was in the area of numerical analysis of vibrating three-dimensional structures. He came to Georgia Tech from DuPont Corporation in 1995. His initial work at the DuPont Dacron Research Laboratory was in the area of fiber-reinforced composite materials and in the development and modeling of fiber spinning processes. He then moved to the DuPont Central Research and Development Department, where he was involved in molecular modeling, computational chemistry, and diffusion.

    Jacob is a member of the American Academy of Mechanics, the American Society of Mechanical Engineers, the Sigma Xi Research Society, and the Phi Kappa Phi Honor Society.

    karl.jacob@mse.gatech.edu

    404.894.2541

    Office Location:
    MRDC-1 4509

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  • University, College, and School/Department
    Research Focus Areas:
  • Biobased Materials
  • Biochemicals
  • Biorefining
  • Biotechnology
  • Computational Materials Science
  • Drug Design, Development and Delivery
  • Fuels & Chemical Processing
  • Molecular, Cellular and Tissue Biomechanics
  • Pulp Paper Packaging & Tissue
  • Sustainable Manufacturing
  • Additional Research:
    "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

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