ChE Seminar Series

Thursday, September 1, 2022; 10:35 a.m.
001 CBEB
Speaker: Bradley D. Olsen from Massachusetts Institute of Technology

Hosted by: Lisa Haines,  luv1@psu.edu

Chemically Controlled Shape-morphing of Elastic Sheets

Wednesday, August 31, 2022; 3:35pm - 4:25pm
360 Willard Building
Speaker: Anna Balazs from University of Pittsburgh

Abstract: Two-dimensional responsive materials that change shape into complex three-dimensional structures are valuable for creating systems ranging from wearable electronics to soft robotics. Typically, the final 3D structure is unique and predetermined through the materials’ processing.  Using theory and simulation, we devise a distinctive approach for driving shape changes of 2D elastic sheets in fluid-filled microchambers. The sheets are coated with catalyst to generate controllable fluid flows, which transform the sheets into complex 3D shapes. A given shape can be achieved by patterning the arrangement of the catalytic domains on the sheet and introducing the appropriate reactant to initiate a specific catalytic reaction. Moreover, a single sheet that encompasses multiple catalytic domains can be transformed into a variety of 3D shapes through the addition of one or more reactants. Materials systems that morph on-demand into a variety of distinct structures can simplify manufacturing processes and broaden the utility of soft materials.

Bio: Anna C. Balazs is a Distinguished Professor of Chemical Engineering and holds the John A. Swanson Endowed Chair in the Swanson School of Engineering at the University of Pittsburgh. She received her B.A. in physics from Bryn Mawr College in 1975 and her Ph.D. in materials science from the Massachusetts Institute of Technology in 1981. Her research involves developing theoretical and computational models to capture the behavior of polymeric materials, nanocomposites and multi-component fluids. Balazs is a Fellow of the American Physical Society, the Royal Society of Chemistry, and the Materials Research Society. She was a Visiting Fellow at Corpus Christi College, Oxford University. She has served on a number of editorial boards, including: Macromolecules, Langmuir, Accounts of Chemical Research, and Soft Matter. She was Chair of the American Physical Society Division of Polymer Physics in 1999-2000. She received a Special Creativity Award from the National Science Foundation. In 2003, she received the Maurice Huggins Memorial Award of the Gordon Research Conference for outstanding contributions to Polymer Science. Recently, she received the American Physical Society Polymer Physics Prize (2016), the Royal Society of Chemistry S F Boys-A Rahman Award (2015), the American Chemical Society Langmuir Lecture Award (2014) and the Mines Medal from the South Dakota School of Mines (2013). She was elected to the National Academy of Engineers (NAE) (2022) and the National Academy of Sciences (NAS) (2021).

Hosted by: Ashley Cecil,  aec5731@psu.edu

UT/ORNL Governor's Chair of Advanced Manufacturing and Professor of Mechanical Engineering

Wednesday, September 7, 2022; 11:00 a.m. - 12:00 p.m. (ET)
Via Zoom
Speaker: Suresh Babu from University of Tennessee, Knoxville

Hosted by: Jaclyn Stimely,  juc52@psu.edu

ChE Seminar Series

Thursday, September 8, 2022; 10:35 a.m.
001 CBEB
Speaker: Brett A. Helms from Lawrence Berkeley National Lab

Hosted by: Lisa Haines,  luv1@psu.edu

Sustainable Propulsion: Fast Forward to a Greener Future

Wednesday, September 7, 2022; 3:35pm - 4:25pm
360 Willard Building
Speaker: Sean Bradshaw from Pratt and Whitney

Abstract: The aviation industry, which accounts for approximately 2.5% of global CO2 emissions, could potentially contribute a greater fraction of global CO2 emissions driven, in part, by the estimated increase in customer demand for air travel by 2050. The International Air Transport Association (IATA) approved a resolution for the global aviation industry to achieve net zero air transport carbon emissions by 2050. Furthermore, Pratt & Whitney has affirmed the Air Transportation Action Group (ATAG) agreement to help our customers achieve net zero air transport carbon emissions by 2050 through smarter technology, compatibility with cleaner fuels, and greener business operations.  Pratt & Whitney’s sustainable technology approach begins with the industry-leading Geared Turbofan (GTF), which delivers up to a 17% fuel efficiency improvement, is capable of operation on 100% sustainable aviation fuels, and is the platform for future growth in sustainable engine performance.  Pratt & Whitney’s technology development builds on the success of the GTF with advanced hybrid-electric propulsion systems that reduce aircraft mission energy and environmental impacts, enabling our customers to meet their commitments to net zero CO2 by 2050.

Biography: Sean Bradshaw is the technical fellow of sustainable propulsion for Pratt & Whitney. His primary focus is on the advanced technologies required for environmentally-sustainable aircraft propulsion systems. This includes developing and maintaining a sustainability strategy across Pratt & Whitney that integrates with Raytheon Technologies. Sean is also engaged in Pratt & Whitney-sponsored university research on advanced technologies related to sustainable propulsion systems, and he supports the recruitment and development of core engineering talent at Pratt & Whitney.

Hosted by: Ashley Cecil,  aec5731@psu.edu