Jamshad Mahmood has over 23 years of experience in corrosion testing and manufacturing of recovery boilers and pressure vessels. He is a Mechanical/Research Engineer with expertise in the design, manufacturing of industrial equipments and conducting lab corrosion testing e.g., slow strain rate corrosion testing, electrochemical corrosion testing, high-temperature aqueous corrosion testing and molten salts corrosion testing. In addition to laboratory experimentation, Jamshad conducted several field studies evaluating in-situ corrosion of pulp mill equipments e.g., digesters, paper machines, storage tanks and recovery boiler tubes. He manages the corrosion laboratories and chemical inventories for the corrosion group. Prior to joining the Institute of Paper Science and Technology in 1997, he worked as Manager Production for 8 years with Descon Engineering Works – one of the large boiler manufactures.

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Professor of the Practice                       
School of Chemical and Biomolecular Engineering
College of Engineering, Georgia Institute of Technology

Associate Director, Pulp, Paper, Packaging and Tissue, Renewable Bioproducts Institute, an Interdisciplinary Research Institute at GT

Director, GT Pulp and Paper Engineering Undergraduate Certificate Program and Foundation
 

Brief Biography:  
Luettgen has 25 plus years of industry experience, with Scott Paper and Kimberly-Clark Corp., where he most recently served as head of North American Innovation the Kimberly-Clark Professional business sector. He has held positions in product development and innovation as well as in capital project management and manufacturing facility leadership.

For several years, Luettgen has served on the Georgia Tech Renewable Bioproducts Institute Industry Board of Advisors, and as the Chairman of the Board of the Technical Association of the Pulp & Paper Industry (TAPPI).  He earned his bachelor's degree in Paper Engineering at Western Michigan University (’85), his master’s degree at the Institute of Paper Chemistry, Appleton, WI (’87), and his Ph.D. in Surface Chemistry at the Institute of Paper Science and Technology - now the Renewable Bioproducts Institute at Georgia Tech (’91).

He rejoined Georgia Tech in November 2014 as a Professor of the Practice in the School of Chemical and Biomolecular Engineering, and Associate Director of Pulp, Paper, Tissue and Packaging at RBI. He also serves as the Director of the undergraduate Pulp and Paper Certificate Program and its Foundation.

Areas of research interest include:  Recycling; renewable cellulosic feedstocks; replacing fossil-based products with bio-based materials; commercialization of nanocellulosic materials in consumer and packaging products; Smart Manufacturing and Industry 4.0; tissue/towel manufacturing and converting; and manufacturing leadership / operational excellence.

Jianxin (Roger) Jiao (M’01) received the Bachelor's degree in mechanical engineering from Tianjin University of Science and Technology, Tianjin, China, the Master's degree in manufacturing engineering from Tianjin University, Tianjin, China, and the Ph.D. degree in industrial engineering from Hong Kong University of Science and Technology, Kowloon, Hong Kong, in 1998.,He is currently an Associate Professor of enterprise systems engineering in the G. W. Woodruff School of Mechanical Engineering, Georgia Institute of Technology, Atlanta. He was an Assistant Professor and Associate Professor in the School of Mechanical and Aerospace Engineering, Nanyang Technological University, Singapore. His research interests include engineering design, manufacturing systems and logistics, affective computing, and engineering management.

Donggang Yao is a professor in the School of Materials Science and Engineering at Georgia Institute of Technology. He received his Ph.D. and Master’s degrees both from University of Massachusetts Amherst, and his B.S. degree from Shanghai Jiao Tong University, China. He teaches and directs research in the broad area of polymer engineering. His current research focuses on polymer micromolding, fiber spinning, single-polymer composites, constitutive modeling, and process modeling and simulation. He has published over 60 journal papers and 80 conference papers on polymer processing. He was a recipient of NSF Career Award in 2003 for his research on polymer micromolding. He chaired the ASME Composites and Textile Engineering Technical Committee from 2009 to 2011. He currently serves as an associate editor for ASME Journal of Manufacturing Science and Engineering and an editorial board member for Polymer Engineering and Science.

When Dr. Rosen arrived at Georgia Tech, he helped form the Systems Realization Laboratory, along with Drs. Janet Allen, Bert Bras, and Farrokh Mistree. In August 1995, Dr. Rosen was appointed the Academic Director of the Georgia Tech Rapid Prototyping and Manufacturing Institute (RPMI), where he has responsibility for developing educational and research programs in rapid prototyping. In 1998, he was appointed the Director of the RPMI. He began at Tech in Fall 1992 as an Assistant Professor.

Paul S. Russo is a Professor of Materials Science and Engineering with a joint appointment in the School of Chemistry and Biochemistry at the Georgia Institute of Technology with expertise in polymer, biopolymer and particle chemistry.

His research interests are rooted in rodlike polymers, such as plant viruses, cellulose derivatives and aromatic backbone materials. Particular emphasis has been paid to molecular transport in complex fluids containing rods and to related measurement methods. Static and dynamic laser light scattering have been joined by fluorescence photobleaching recovery and pulsed field gradient NMR spectroscopy to measure diffusion in dilute and concentrated solutions, gels, and liquid crystals. Dialysis implementations of these techniques have permitted stability studies of the amyloid protein responsible for Alzheimer’s disease. Other materials of interest include organophilic polypeptides, which have been coupled to silica cores to yield hybrid particles that can carry hydrophobic payloads, such as enzymes. The same particles can also form colloidal crystals and linear arrays. Small-angle x-ray scattering plays a role in the characterization of these materials. Hydrophobic proteins are being used to template the synthesis of polymers in new and unusual shapes and to disperse oil following marine spills.

H. Jerry Qi is a professor and the Woodruff Faculty Fellow in the George W. Woodruff School of Mechanical Engineering at Georgia Institute of Technology. He received his bachelor degrees (dual degree), master and Ph.D. degree from Tsinghua University (Beijing, China) and a ScD degree from Massachusetts Institute of Technology (Boston, MA, USA). After one year postdoc at MIT, he joined University of Colorado Boulder as an assistant professor in 2004, and was promoted to associate professor with tenure in 2010. He joined Georgia Tech in 2014 as an associate professor with tenure and was promoted to a full professor in 2016. Qi is a recipient of NSF CAREER award (2007). He is a member of Board of Directors for the Society of Engineering Science. In 2015, he was elected to an ASME Fellow. The research in Qi's group is in the general area of soft active materials, with a focus on 1) 3D printing of soft active materials to enable 4D printing methods; and 2) recycling of thermosetting polymers. The material systems include: shape memory polymers, light activated polymers, vitrimers. On 3D printing, they developed a wide spectrum of 3D printing capability, including: multIMaTerial inkjet 3D printing, digit light process (DLP) 3D printing, direct ink write (DIW) 3D printing, and fused deposition modeling (FDM) 3D printing. These printers allow his group to develop new 3D printing materials to meet the different challenging requirements. For thermosetting polymer recycling, his group developed methods that allow 100% recycling carbon fiber reinforced composites and electronic packaging materials. Although his group develops different novel applications, his work also relies on the understanding and modeling of material structure and properties under environmental stimuli, such as temperature, light, etc, and during material processing, such as 3D printing. Constitutive model developments are typically based on the observations from experiments and are then integrated with finite element through user material subroutines so that these models can be used to solve complicated 3D multiphysics problems involving nonlinear mechanics. A notable example is their recent pioneer work on 4D printing, where soft active materials is integrated with 3D printing to enable shape change (or time in shape forming process). Recently, his developed a state-of-the-art hybrid 3D printing station, which allows his group to integrate different polymers and conduct inks into one system. Currently, his group is working on using this printing station for a variety of applications, including printed 3D electronics, printed soft robots, etc.