Eat pizza, meet writing faculty, chat with other writing students, and learn about writing programs at WPI. We'll also be raffling away some WPI swag. Open to writing students and students who might be interested in pursuing writing at WPI as a major, minor, or HUA depth.Please RSVP through the registration link below if you plan on attending.

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Be well at home while celebrating Wellness Day on September 19th. Drop by the Center for Well-Being or the lobby of Gateway 1 (60 Prescott) starting on Wednesday, September 17th to pick up your Wellness @ Home Kit to help de-stress and relax. Kits will be available September 17-19 or until we run out. Get one before they are gone! Sponsored by the CWB.

Abstract: In recent years, there has been growing recognition that the physical bodies of animals play just as crucial a role in performing complex tasks as the control signals that drive them. In the field of robotics, this has given rise to the concept of “mechanical intelligence,” whereby desired behavior is embedded directly into robotic hardware rather than relying purely on active control. Though much work remains to match the level of performance found in nature, great progress has been made by both soft and rigid roboticists, alike. In this talk, Prof. Connor McCann will present his research at the intersection of these two fields, using a combination of experimental, theoretical, and numerical techniques to embed intelligent behavior into rigid robotic hands, soft wearable rehabilitative robots, and biomimetic soft-rigid structures inspired by stingray skeletons. As the director of the Principled Rigid-Soft Mechanisms (PRiSM) Lab at WPI, Prof. McCann’s ongoing research directions focus on the development of new paradigms to achieve mechanical intelligence through “hybrid-stiffness” mechanisms. By leveraging the benefits of both softness and rigidity, he aims to push the bounds of robotic hardware to enable complex and intelligent robotic behavior beyond what is currently possible.Bio: Connor McCann is an Assistant Professor in the Robotics Engineering department at Worcester Polytechnic Institute. His research focuses on hybrid-stiffness mechanisms at the intersection of rigid and soft robotics. He is interested in the underlying mechanics that govern the non-trivial interactions between rigid and soft materials, and how these interactions can enable advanced, highly functional behavior in robots. His work combines first-principles physical modeling with application-driven design and prototyping, spanning multiple application areas including robotic grasping and manipulation, wearable robotics, and bioinspired robotics. Prior to joining WPI, he received his Ph.D. and M.S. from Harvard University and his B.S. from Yale University, all in mechanical engineering.

TITLE: Investigations of current-use flame retardants and plasticizers in atmospheric particulate matterAbstract: The World Health Organization (WHO) considers air pollution “one of the biggest environmental threats to human health". Since organic chemicals can efficiently sorb to particulate matter (PM), the health effects associated with these chemicals must also be considered a hazard. Organophosphate esters (OPEs), which are a “reemerging” pollutant with a wide-range of uses in consumer products, including as a flame retardant (FR) and plasticizer, are one such ���high production volume” chemical. Despite known and suspected health effects of OPEs, there is no international regulation in place for OPEs and studies of these chemicals in PM in the US are limited. Providence, RI is the third most populated city in New England while also being home to New England’s second largest deep-water port. It has been documented that urban centers are a significant source of OPEs and have been shown to be transported to coastal regions from other nearby cities. Filter-based samples of total suspended particulate (TSP) and PM2.5 have been collected in Providence, RI. Samples were extracted to determine the concentration of 33 OPEs (including 14 novel-OPEs) in an urban area as a function of size fraction, season, precipitation, and solar radiation. Comparison of partitioning between size fractions will allow for a better understanding of health-related exposures, since PM2.5 is the respirable fraction of PM. Preliminary data on OPEs in Pacific Northwest wildfires will also be presented.Biography: Adelaide E. Clark received a Bachelor of Science in Chemistry with a concentration in education from Emory & Henry College before pursuing her PhD in analytical chemistry from Baylor University. Prior to coming to Providence College, she spent 6 years teaching at the Oregon Institute of Technology, the last year as a tenured faculty member. While at Oregon Tech, she worked with undergraduate researchers looking at the effects of wildfire smoke on hospitalization rates and the effects of wood stoves on air quality in the Klamath Basin. Since coming to PC, she's been conducting research looking at flame retardants and plasticizers at three sites in Rhode Island through FriAir Net, the Friar Air Monitoring Network at Providence College (established by her group in 2023), and in wildfire samples from the Pacific Northwest.