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DTEND;TZID=America/New_York:20210407T130000
DTSTAMP:20260417T055209
CREATED:20210405T174754Z
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UID:3543-1617796800-1617800400@che.northeastern.edu
SUMMARY:ChE Seminar Series: Engineered Autonomous Control of Metabolic Pathways
DESCRIPTION:ChE Seminar Series Presents: \nKristala L. J. Prather\, Ph.D.\nArthur D. Little Professor\, Department Executive Officer\, Department of Chemical Engineering\, MIT \nEngineered Autonomous Control of Metabolic Pathways \nAbstract\nMicrobial systems offer the opportunity to produce a wide variety of chemical compounds in a sustainable fashion. Economical production\, however\, requires processes that operate with high titer\, productivity\, and yield. One challenge towards maximizing yields is the need to use substrate for biomass\, resulting in a competing pathway that cannot merely be eliminated. Productivities may also be significantly influenced by the timing of expression of genes in the production pathway. Dynamic metabolic engineering has emerged as a means to address these and other impediments in strain performance. Ideally\, the triggers for dynamic control would be autonomous\, that is\, independent of any external intervention by the operator. We have developed such autonomous devices based on pathway-independent quorum-sensing circuits and have demonstrated their utility across several distinct metabolic pathways and with varying levels of complexity. In this talk\, I will describe our approach for development of these Metabolite Valves and results to date from their implementation. \nBiography\nKristala L.J. Prather is the Arthur D. Little Professor in and Executive Officer of the Department of Chemical\nEngineering at MIT. She received an S.B. degree from MIT in 1994 and Ph.D. from the University of California\, Berkeley (1999)\, and worked 4 years in BioProcess Research and Development at the Merck Research Labs prior to joining MIT. Her research interests are centered on the design and assembly of recombinant microorganisms for the production of small molecules\, with additional efforts in novel bioprocess design approaches. A particular focus is the elucidation of design principles for the production of unnatural organic compounds with engineered control of metabolic flux within the framework of the burgeoning field of synthetic biology. Prather is the recipient of an Office of Naval Research Young Investigator Award (2005)\, a Technology Review “TR35” Young Innovator Award (2007)\, a National Science Foundation CAREER Award (2010)\, the Biochemical Engineering Journal Young Investigator Award (2011)\, and the Charles Thom Award of the Society for Industrial Microbiology and Biotechnology (2017). Additional honors include selection as the Van Ness Lecturer at Rensselaer Polytechnic Institute (2012)\, as a Fellow of the Radcliffe Institute for Advanced Study (2014-2015)\, the American Association for the Advancement of Science (AAAS; 2018)\, and the American Institute for Medical and Biological Engineering (AIMBE; 2020). \nPlease email Alyssa Ramsey at a.ramsey@northeastern.edu for the link to the seminar.
URL:https://che.northeastern.edu/event/che-seminar-series-engineered-autonomous-control-of-metabolic-pathways/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20210409T120000
DTEND;TZID=America/New_York:20210409T130000
DTSTAMP:20260417T055209
CREATED:20210405T174852Z
LAST-MODIFIED:20210405T174852Z
UID:3544-1617969600-1617973200@che.northeastern.edu
SUMMARY:ChE Seminar Series: Tools for Analyzing and Repairing Biological Systems
DESCRIPTION:ChE Seminar Series Presents: \nDr. Edward S. Boyden\, Ph. D.\nY. Eva Tan Professor in Neurotechnology at MIT\nHoward Hughes Medical Institute\, McGovern Institute\nProfessor\, Departments of Brain and Cognitive Sciences\, Media Arts and Sciences\, and Biological Engineering\, MIT \nTools for Analyzing and Repairing Biological Systems \nAbstract \nUnderstanding and repairing complex biological systems\, such as the brain\, requires technologies for systematically observing and controlling these systems.  We are discovering new molecular principles that enable such technologies.  For example\, we discovered that one can physically magnify biological specimens by synthesizing dense networks of swellable polymer throughout them\, and then chemically processing the specimens to isotropically swell them.  This method\, which we call expansion microscopy\, enables ordinary microscopes to do nanoimaging – important for mapping the brain across scales.  Expansion of biomolecules away from each other also decrowds them\, enabling previously invisible nanostructures to be labeled and seen.  As a second example\, we discovered that microbial opsins\, genetically expressed in neurons\, could enable their electrical activities to be precisely controlled in response to light.  These molecules\, now called optogenetic tools\, enable causal assessment of how neurons contribute to behaviors and pathological states\, and are yielding insights into new treatment strategies for brain diseases.  Finally\, we are developing\, using new strategies such as robotic directed evolution\, fluorescent reporters that enable the precision measurement of signals such as voltage and calcium.  By fusing such reporters to self-assembling peptides\, they can be stably clustered within cells at random points\, distant enough to be resolved by a microscope\, but close enough to spatially sample the relevant biology. Such clusters\, which we call signaling reporter islands (SiRIs)\, permit many fluorescent reporters to be used within a single cell\, to simultaneously reveal relationships between different signals.  We share all these tools freely\, and aim to integrate the use of these tools so as to enable comprehensive understandings of neural circuits. \nBiography: \nEd Boyden is Y. Eva Tan Professor in Neurotechnology at MIT\, an investigator of the Howard Hughes Medical Institute and the MIT McGovern Institute\, and professor of Brain and Cognitive Sciences\, Media Arts and Sciences\, and Biological Engineering at MIT. He leads the Synthetic Neurobiology Group\, which develops tools for analyzing and repairing complex biological systems such as the brain\, and applies them systematically to reveal ground truth principles of biological function as well as to repair these systems. He co-directs the MIT Center for Neurobiological Engineering\, which aims to develop new tools to accelerate neuroscience progress\, and is a faculty member of the MIT Center for Environmental Health Sciences\, Computational & Systems Biology Initiative\, and Koch Institute. \nAmongst other recognitions\, he has received the Wilhelm Exner Medal (2020)\, the Croonian Medal (2019)\, the Lennart Nilsson Award (2019)\, the Warren Alpert Foundation Prize (2019)\, the Rumford Prize (2019)\, the Canada Gairdner International Award (2018)\, the Breakthrough Prize in Life Sciences (2016)\, the BBVA Foundation Frontiers of Knowledge Award (2015)\, the Carnegie Prize in Mind and Brain Sciences (2015)\, the Jacob Heskel Gabbay Award (2013)\, the Grete Lundbeck Brain Prize (2013)\, the NIH Director’s Pioneer Award (2013)\, the NIH Director’s Transformative Research Award (three times\, 2012\, 2013\, and 2017)\, and the Perl/UNC Neuroscience Prize (2011). He was also named to the World Economic Forum Young Scientist list (2013) and the Technology Review World’s “Top 35 Innovators under Age 35” list (2006)\, and is an elected member of the National Academy of Sciences (2019)\, the American Academy of Arts and Sciences (2017)\, the National Academy of Inventors (2017)\, and the American Institute for Medical and Biological Engineering (2018). His group has hosted hundreds of visitors to learn how to use new biotechnologies\, and he also regularly teaches at summer courses and workshops in neuroscience\, and delivers lectures to the broader public (e.g.\, TED (2011)\, TED Summit (2016)\, World Economic Forum (2012\, 2013\, 2016)). \nEd received his Ph.D. in neurosciences from Stanford University as a Hertz Fellow\, working in the labs of Jennifer Raymond and Richard Tsien\, where he discovered that the molecular mechanisms used to store a memory are determined by the content to be learned. In parallel to his PhD\, as an independent side project\, he co-invented optogenetic control of neurons\, which is now used throughout neuroscience. Previously\, he studied chemistry at the Texas Academy of Math and Science at the University of North Texas\, starting college at age 14\, where he worked in Paul Braterman’s group on origins of life chemistry. He went on to earn three degrees in electrical engineering and computer science\, and physics\, from MIT\, graduating at age 19\, while working on quantum computing in Neil Gershenfeld’s group. Long-term\, he hopes that understanding how the brain generates the mind will help provide a deeper understanding of the human condition\, and perhaps help humanity achieve a more enlightened state. \nPlease email Alyssa Ramsey at a.ramsey@northeastern.edu for the link to the seminar.
URL:https://che.northeastern.edu/event/che-seminar-series-tools-for-analyzing-and-repairing-biological-systems/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20210416T120000
DTEND;TZID=America/New_York:20210416T130000
DTSTAMP:20260417T055209
CREATED:20210415T192227Z
LAST-MODIFIED:20210415T192227Z
UID:3546-1618574400-1618578000@che.northeastern.edu
SUMMARY:Che Seminar Series: Creating Inclusive Spaces in the Curriculum to Improve the Classroom Climate
DESCRIPTION:ChE Seminar Series Presents: Dr. Matthew Lee \nMatthew Lee\, PhD \nTeaching Professor of Human Services \nNortheastern University \nCreating Inclusive Spaces in the Curriculum to Improve the Classroom Climate \nAbstract: In this Distinguished Lecture\, Professor Matthew Lee\, PhD\, from the Human Services Program at Northeastern\, will discuss his life\, career\, and lifelong commitment to equity and diversity for college students. Drawing on his years of experience engaged in intergroup dialogue\, research\, teaching study abroad\, and anti-racist training\, Dr. Lee will describe some lessons for attendees to consider in developing a more inclusive curriculum and climate. Question & answer period to take place during the session. \nBio: Dr. Matthew Lee received his PhD in Clinical and Community Psychology from the University of Illinois at Urbana-Champaign. He has taught courses in counseling theory and practice\, cross-cultural psychology\, ethnic identity and conflict (in Romania\, Germany\, Poland\, and Croatia)\, intro to psychology\, lifespan development\, developmental psychology\, race and empowerment\, Asian American identity\, psychology and literature\, and senior capstone. \nHis research examines campus climate and advocacy for diversity/inclusion in the classroom\, and Asian American mental health as it relates to experiences of microaggressions that may be associated with phenotype or socialization.
URL:https://che.northeastern.edu/event/che-seminar-series-creating-inclusive-spaces-in-the-curriculum-to-improve-the-classroom-climate/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20210421T120000
DTEND;TZID=America/New_York:20210421T130000
DTSTAMP:20260417T055209
CREATED:20210420T180408Z
LAST-MODIFIED:20210420T180408Z
UID:3547-1619006400-1619010000@che.northeastern.edu
SUMMARY:ChE Seminar Series: Biomaterials to unlock the regenerative capacity of tissues
DESCRIPTION:ChE Seminar Series Presets: Dr. Tatiana Segura \nTatiana Segura\, PhD \nProfessor of Biomedical Engineering\, Duke University \nBiomaterials to unlock the regenerative capacity of tissues \nAbstract: Injectable materials that can conform to the shape of a desired space are used in a variety of fields including medicine. The ability to fill a tissue defect with an injectable material can be used for example to deliver drugs\, augment tissue volume\, or promote repair of an injury. This talk will explore the development of injectable materials that are based on assembled particle building blocks\, for tissue repair. We find that using microparticle building blocks to build the scaffold generates a porous network by the space left behind between adjacent building blocks. Due to the injectability of this microporous material we have explored its wide applicability to tissue repair applications ranging from skin to brain wounds. In this talk\, I will describe how MAP scaffolds can modulate the wound healing immune response and lead to regenerative wound healing. \nBiography: Professor Tatiana Segura received her BS degree in Bioengineering from the University of California Berkeley and her doctorate in Chemical Engineering from Northwestern University. Her graduate work in designing and understanding non-viral gene delivery from hydrogel scaffolds was supervised by Prof. Lonnie Shea. She pursued post-doctoral training at the Swiss Federal Institute of Technology\, Lausanne under the guidance of Prof. Jeffrey Hubbell\, where her focus was self-assembled polymer systems for gene and drug delivery. Professor Segura’s Laboratory studies the use of materials for minimally invasive in situ tissue repair. On this topic\, she has published 113 peered reviewed publications to date. She has been recognized with the Outstanding Young Investigator Award from the American Society of Gene and Cell Therapy\, the American Heart Association National Scientist Development Grant\, and the CAREER award from National Science Foundation. She was Elected to the College of Fellows at the American Institute for Medical and Biological Engineers (AIMBE) in 2017. She spent the first 11 years of her career at UCLA department of Chemical and Biomolecular Engineering and has recently relocated to Duke University\, where she holds appointments in Biomedical Engineering\, Neurology and Dermatology.
URL:https://che.northeastern.edu/event/che-seminar-series-biomaterials-to-unlock-the-regenerative-capacity-of-tissues/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20210720T080000
DTEND;TZID=America/New_York:20210722T130000
DTSTAMP:20260417T055209
CREATED:20210622T000006Z
LAST-MODIFIED:20210622T000006Z
UID:3661-1626768000-1626958800@che.northeastern.edu
SUMMARY:COE CommLab/Khoury College Writing Retreat
DESCRIPTION:College of Engineering PhD students are invited to join us for a writing retreat July 20 – 22.  The aim of this retreat is to create sustained writing time for researchers to work in a calm\, supportive environment on a longer project.  Studies have shown that an academic writing retreat supports productivity and progress while also encouraging helpful guidance from peers. \nOur virtual retreat is organized around alternating periods of quiet work on individual projects with collective sessions on topics related to research writing. Each of the three days begins with a welcome message and group gathering. On the last day\, we’ll wrap up the retreat with a virtual lunch to share concluding thoughts. \nRegister here for this event by June 24.
URL:https://che.northeastern.edu/event/coe-commlab-khoury-college-writing-retreat/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20210922T120000
DTEND;TZID=America/New_York:20210922T130000
DTSTAMP:20260417T055209
CREATED:20210921T173948Z
LAST-MODIFIED:20210921T173948Z
UID:3727-1632312000-1632315600@che.northeastern.edu
SUMMARY:ChE Seminar Series: Materials Innovation in Nanotechnologies
DESCRIPTION:ChE Seminar Series Presents: \nDr. Paulette Clancy\, Ph.D\nHead of the Department of Chemical and Biomolecular Engineering at Johns Hopkins University \nMaterials Innovation in Nanotechnologies \nAbstract\nThere are many problems at the forefront of materials chemistry whose solution is stymied by its inherent complexity. Such problems are characterized by a rich landscape of parameters and processing variables that is combinatorially too large for either an experimental or a computational approach to solve through an exhaustive search. In such cases\, the usual approach is an Edisonian trial-and-error approach\, which inevitably leaves areas of parameter space unexplored. The problems that we have explored are also characterized by a scarcity of data\, since the data are expensive to acquire\, both experimentally and computationally. This makes it an ideal candidate to solve using a Bayesian optimization (BayesOpt) approach.\nWe have used a Bayesian approach to study several problems in self-assembly processes involving materials chemistry. This talk will discuss two mature test cases in which we used BayesOpt extensively to study (1) how to optimize the choice of solvent and halides to produce high quality thin films of lead-based hybrid organic-inorganic perovskites and (2) identify stable and metastable polymorphs of an organic semiconducting material. I will end with some ideas of where the BayesOpt field can expand its use in the chemical sciences and share some “lessons learned” in implementing BayesOpt and machine learning\, which may be helpful to others who decide to start adding machine learning to their research repertoire. \nBiography\nPaulette Clancy is a Professor and the inaugural Head of the Department of Chemical and Biomolecular Engineering at Johns Hopkins University. She is also the Samuel and Diane Bodman Professor Emerita of Chemical Engineering at Cornell. She is the Associate Director of the Hopkins Center for Integrated Structure-Materials Modeling and Simulation. She was the inaugural Director of the Cornell Institute for Computational Science and Engineering for almost 10 years and is reprising a similar role at Hopkins\, chairing our petascale research computing resources\, ARCH.\nHer research group is recognized as one of the country’s leading computational groups in atomic- scale modeling of materials and algorithm development. Her current thrust is to develop machine learning algorithms to accelerate the search for optimal materials processing protocols. Her group has always been focused on electronic materials\, but it also includes more esoteric projects include xenobiology (Life on Titan) and a screening of therapeutic oligomers to maximize antibacterial ability. She has won numerous awards for mentoring\, service learning and civic engagement\, and promoting those from under- represented groups.
URL:https://che.northeastern.edu/event/che-seminar-series-materials-innovation-in-nanotechnologies/
LOCATION:108 SN
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20210929T120000
DTEND;TZID=America/New_York:20210929T130000
DTSTAMP:20260417T055209
CREATED:20210924T175623Z
LAST-MODIFIED:20210924T175647Z
UID:3795-1632916800-1632920400@che.northeastern.edu
SUMMARY:ChE Seminar Series: Learning about Biological Interactions\, Recognition\, and Targeted Delivery Through Surface Forces
DESCRIPTION:ChE Seminar Series Presents: \nDr. Tonya Kuhl \nProfessor and Chair\, Department of Chemical Engineering\, UC Davis \nLearning about biological interactions\, recognition\, and targeted delivery through surface forces \nAbstract: \nThe promoters of cell adhesion are ligands\, which are often attached to semi-flexible tethers that bind to surface receptors on adjacent cells. Drug delivery systems\, such as Stealth Liposomes\, have also attempted to use biological specificity to target therapeutic payloads. Using a combination of Monte Carlo simulations\, diffusion reaction theory\, and direct experiments (surface force measurements)\, we have quantified how polymer tethers alter the interaction and binding/capture based on biospecificity (ligand-receptor binding). Experimental and theoretical results as a function of molecular weight and bi-modal distributions will be discussed to enable rational design. \nBiography: \nTonya Kuhl\, is Professor and Chair of Chemical Engineering\, the co-Director of the UC Davis Coffee Center (and co-instructor and developer of ECH 1 “The Design of Coffee”)\, and a faculty member of the Biophysics and Biomedical Engineering Graduate Groups. Her Bachelors was from the University of Arizona and Ph.D. from UCSB\, both in chemical engineering. Her research interests are in the general area of colloidal science\, self-assembly\, and complex fluids.  In particular\, the Kuhl group studies a wide range of systems from surfactants\, lipids and proteins to polymer coatings\, nanoparticles and confined fluids. The common theme is that “interfaces are where stuff happens”.  Her group studies interfaces by directly measuring the normal interactions (attractive and repulsive) between surfaces and their lateral friction using specialized high resolution force spectroscopy. Complementary x-ray and neutron scattering measurements are used to measure the exact film structure on a molecular level\, enabling a fundamental understanding of how surface film structure and experimental conditions yield the measured properties.  Rather than more empirical\, “guess and test”\, approaches for improvement in properties or functionality – the Kuhl group uses direct measurements and theory to enable predictive modeling and rational design.
URL:https://che.northeastern.edu/event/che-seminar-series-learning-about-biological-interactions-recognition-and-targeted-delivery-through-surface-forces/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20211006T170000
DTEND;TZID=America/New_York:20211006T200000
DTSTAMP:20260417T055209
CREATED:20210929T180818Z
LAST-MODIFIED:20210929T181335Z
UID:3803-1633539600-1633550400@che.northeastern.edu
SUMMARY:Showcase of Opportunities for Undergraduate Research and Creative Endeavor (SOURCE)
DESCRIPTION:Calling all Huskies! Learn more about what cutting-edge research and creative endeavor look like at Northeastern. This is your chance to talk one-on-one with faculty from across the colleges about their research – and how you can get involved in projects during your time at Northeastern. Not everyone will have open positions right now but you’ll get a chance to see the range of work that’s happening and begin to make connections that you can build for the rest of your time at Northeastern. \nBefore you attend\, here’s some advice to consider. \n\nTake a look and see who’ll be there. We have an online database of attendees. Go through it and learn more about the project areas and visit the researcher/creative practitioner web pages. This will help prepare you for a conversation and help you ask any questions you might have.\nGet ready for a conversation from your end. Think about goals you have \, as well as your current interests and skills and those that you want to develop. How does what you have read about the various projects align with what you know about yourself and your interests? Take a minute to practice a simple declarative sentence\, “My name is ____________. I study ____________. I think that this part of your work ____________ is interesting because of this intellectual reason/moral imperative/grand impact ____________.  I’d love to learn more about it because of this previous experience ____________ and these skills ____________ and my long-term interest in ____________.  How I can get involved?” You might not know how to fill in all of the blanks right now (that’s why you’re in school) but see how close you can get.  When you know who you are\, what you value\, and how you can contribute — and get some practice saying it out loud– being confident becomes easier.\nRemember\, not every faculty member will have open positions now — but a good impression lasts a long time. You can’t go wrong with being polite and courteous.   Address faculty members as Professor until told otherwise (better to err on the side of formality).\nKeep in mind your time! If you want to be involved in research or creative practice\, a good thing to keep in mind is that faculty members will commit a lot of time to training and mentoring their undergraduates. They’re investing time\, energy\, and expertise in their mentees and want to know that you will make time for the projects\, show up consistently\, and ideally be with them for longer than a semester if possible. The learning curve of most projects is steep and it takes some time to get to the meatiest parts of the work. Be honest with yourself about the commitment you can make\, be frank with your faculty mentors\, and stick to your word. Communication and honesty in relationships\, including the mentoring relationship\, is key.\n\nSOURCE is a collaboration between Bouvé College of Health Sciences; College of Arts\, Media and Design; College of Engineering; College of Science; College of Social Sciences and Humanities; D’Amore-McKim School of Business; and Khoury College of Computer Science. It is coordinated by Undergraduate Research and Fellowships on behalf of the Office of the Chancellor.
URL:https://che.northeastern.edu/event/showcase-of-opportunities-for-undergraduate-research-and-creative-endeavor/
LOCATION:Curry Student Center\, 360 Huntington Ave.\, Boston\, MA\, 02115\, United States
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END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20211013T120000
DTEND;TZID=America/New_York:20211013T130000
DTSTAMP:20260417T055209
CREATED:20211007T175033Z
LAST-MODIFIED:20211007T175033Z
UID:3822-1634126400-1634130000@che.northeastern.edu
SUMMARY:ChE Seminar Series: Chemo-mechanics and solid-state batteries
DESCRIPTION:ChE Seminar Series Presents: \nDr. Kelsey Hatzell\, Ph.D \nAssistant Professor in the Andlinger Center for Energy and Environment \nAssistant Professor of Mechanical and Aerospace Engineering \nPrinceton University \nChemo-mechanic and solid-state batteries \nAbstract: Transportation accounts for 23% of energy-related carbon dioxide emissions and electrification is a pathway toward ameliorating these growing challenges.  All solid-state batteries could potentially address the safety and driving range requirements necessary for widespread adoption of electric vehicles. However\, the power densities of all-solid-state batteries are limited because of ineffective ion transport at solid|solid interfaces. New insight into the governing physics that occur at intrinsic and extrinsic interfaces are critical for developing engineering strategies for the next generation of energy-dense batteries. However\, buried solid|solid interfaces are notoriously difficult to observe with traditional bench-top and lab-scale experiments. In this talk\, I discuss opportunities for tracking phenomena and mechanisms in all solid-state batteries in-situ using advanced synchrotron techniques. Synchrotron techniques that combine reciprocal and real space techniques are capable of tracking multi-scale structural phenomena from the nano- to meso-scale. This talk will discuss the role microstructure plays on transport and interfacial properties that govern adhesion. Quantification of salient descriptors of structure in solid-state batteries is critical for understanding the mechanochemical nature of all solid-state batteries. \nBiography: Dr. Hatzell is an assistant professor at Princeton university in the Andlinger Center for Energy and Environment and department of Mechanical and aerospace engineering. Hatzell’s group primarily work on energy storage and is particularly interested at using non-equilibrium x-ray techniques to probe batteries during operando experimentation. \nDr. Hatzell earned her Ph.D. in Material Science and Engineering at Drexel University\, her M.S. in Mechanical Engineering from Pennsylvania State University\, and her B.S./B.A. in Engineering/Economics from Swarthmore College. Hatzell’s research group works on understanding phenomena at solid|liquid and solid|solid interfaces and works broadly i9n energy storage and conversion. Hatzell is the recipient of several awards including the ORAU Powe Junior Faculty Award (2017)\, NSF CAREER Award (2019)\, ECS Toyota Young Investigator Award (2019)\, finalist for the BASF/Volkswagen Science in Electrochemistry Award (2019)\, the Ralph “Buck” Robinson award from MRS (2019)\, Sloan Fellowship in Chemistry (2020)\, and POLiS Award of Excellence for Female Researchers (2021). \nPlease contact a.ramsey@northeastern.edu for the seminar link. \n  \n 
URL:https://che.northeastern.edu/event/che-seminar-series-chemo-mechanics-and-solid-state-batteries/
LOCATION:108 SN
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20211020T120000
DTEND;TZID=America/New_York:20211020T130000
DTSTAMP:20260417T055209
CREATED:20211019T184128Z
LAST-MODIFIED:20211019T184128Z
UID:3833-1634731200-1634734800@che.northeastern.edu
SUMMARY:ChE Seminar Series: Towards Sustainable Energy and Materials: Carbon Capture\, Utilization and Storage
DESCRIPTION:ChE Seminar Series Presents: \nDr. A.-H. Alissa Park\, Ph.D \nLenfest Earth Institute Professor of Climate Change\nDepartment of Earth and Environmental Engineering & Department of Chemical Engineering\nDirector of the Lenfest Center for Sustainable Energy\,\nColumbia University \nTowards Sustainable Energy and Materials: Carbon Capture\, Utilization and Storage  \nAbstract: \nIn order to meet the ever-increasing global energy demands while stabilizing the atmospheric CO2 level\, the development of carbon capture\, utilization and storage (CCUS) technologies is one of the critical needs. In particular\, there has been significant efforts to develop CO2 capture solvents and some (e.g.\, amine-based aqueous solvents) have shown very promising results. Unfortunately\, the energy requirement for the current aqueous solvent systems is still considered to be too high. Thus\, efforts have been focused on the development of second and third-generation CO2 capture solvents which are often water-free. Nanoparticle Organic Hybrid Materials (NOHMs) are a new class of organic-inorganic hybrids that consist of a hard nanoparticle core functionalized with a molecular organic corona that possesses a high degree of chemical and physical tunability. It has recently been discovered that NOHMs have interesting electrolyte properties which may allow the CO2 capture to be pulled by the in-situ CO2 conversion reactions. The development of these unique nanoscale hybrid materials will not only advance CO2 capture materials design but also introduce unique research opportunities in various energy and environmental fields. This seminar will discuss the challenges and opportunities of different CO2 capture and conversion pathways including Negative Emission Technologies (e.g.\, Direct Air Capture) that can allow the development of circular carbon and hydrogen economy using renewable energy. \nBio: \nAh-Hyung (Alissa) Park is the Lenfest Earth Institute Professor of Climate Change in the Departments of Earth and Environmental Engineering & Chemical Engineering at Columbia University. She is also the Director of the Lenfest Center for Sustainable Energy. Her research focuses on sustainable energy and materials conversion pathways with emphasis on integrated Carbon Capture\, Utilization and Storage (CCUS) technologies addressing climate change. Park group is also working on Direct Air Capture of CO2 and Negative Emission Technologies including BioEnergy with Carbon Capture and Storage (BECCS) and sustainable construction materials with low carbon intensity. Park received a number of professional awards and honors including the U.S. C3E Research Award (2018)\, PSRI Lectureship Award in Fluidization at AIChE (2018)\, ACS Energy and Fuels Division – Emerging Researcher Award (2018)\, ACS WCC Rising Star Award (2017)\, and the National Science Foundation CAREER Award (2009). Park also led a number of global and national discussions on CCUS including the Mission Innovation Workshop on Carbon Capture\, Utilization and Storage in 2017 and the National Petroleum Council CCUS Report in 2019. She is an elected Fellow of AIChE\, AAAS\, ACS\, and RSC. \n  \nPlease contact a.ramsey@northeastern.edu for the remote seminar link.
URL:https://che.northeastern.edu/event/che-seminar-series-towards-sustainable-energy-and-materials-carbon-capture-utilization-and-storage/
LOCATION:108 SN
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20211027T120000
DTEND;TZID=America/New_York:20211027T130000
DTSTAMP:20260417T055209
CREATED:20211020T175119Z
LAST-MODIFIED:20211020T175119Z
UID:3841-1635336000-1635339600@che.northeastern.edu
SUMMARY:ChE Seminar Series: Engineering directed Transport and Collective Dynamics of Charged Colloids under Electric Fields
DESCRIPTION:ChE Seminar Series Presents: \nDr. Carlos A. Silvera Batista \nDepartment of Chemical & Biomolecular Engineering \nVanderbilt University \nEngineering directed Transport and Collective Dynamics of Charged Colloids under Electric Fields \nAbstract: \nGradients in electrical potential (electric fields)\, along with gradients in concentration of ionic species\, are a principal way to control the motion of colloids. The surface and body forces that electric fields exert on anisotropic colloids have opened new applications in self-propulsion\, transport of cargo\, dynamic assembly\, and directed assembly. This talk focuses on the long-range transport of charged colloids\, as well as on the dynamic assembly of anisotropic and active colloids. In the first part\, we present a study of the dynamics of charged colloids under direct currents and gradients of chemical species (electrodiffusiophoresis). In our approach\, we developed a method to simultaneously visualize the progression of concentration polarization and the ensuing dynamics of charged colloids near electrodes. With the aid of confocal microscopy\, we show that the passage of current through water induce the focusing and aggregation of charged colloids away from both electrodes. Preliminary experiments show that this phenomenon can potentially be useful to perform focusing\, trapping and separation operations in lab-on-a-chip devices. In the second part\, we discuss strategies to tailor the propulsion and collective dynamics of Janus particles (JPs) under electric fields. We engineer the relaxation time of JPs by controlling the properties of the medium and the particles. The insights from this study provide helpful quantitative information for the design of colloidal machines with targeted propulsion\, interparticle interactions and collective dynamics. In addition\, our results provide the experimental basis for the design of non-equilibrium strategies for materials fabrication. \nBio: \nDr. Carlos A. Silvera Batista initiated undergraduate studies in chemical engineering at the Universidad de San Buenaventura (Cartagena\, Colombia) and subsequently obtained a bachelor’s degree from the City College of New York (CCNY). Dr. Silvera began his research trajectory as an LSAMP scholar under the guidance of Prof. Ilona Kretzschmar (CCNY). After earning a PhD in chemical engineering from the University of Florida\, Dr. Silvera held postdoctoral positions at the National Institute of Standards and Technology and at the University of Michigan\, where he received the President’s Postdoctoral Fellowship. Currently\, as an assistant professor at Vanderbilt University\, his research interest is on the electrokinetics and directed assembly of colloidal systems.  His research work has resulted in over 20 peer-reviewed publications in high-impact scientific journals\, such as JACS\, ACS Nano\, Langmuir and Science. \n 
URL:https://che.northeastern.edu/event/che-seminar-series-engineering-directed-transport-and-collective-dynamics-of-charged-colloids-under-electric-fields/
LOCATION:108 SN
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20211027T140000
DTEND;TZID=America/New_York:20211027T150000
DTSTAMP:20260417T055209
CREATED:20211021T174450Z
LAST-MODIFIED:20211021T174450Z
UID:3843-1635343200-1635346800@che.northeastern.edu
SUMMARY:LEADERs Event: AI Challenges in the Deployment of Advanced Driver-Assistance Systems
DESCRIPTION:This presentation will help attendees learn about integrating AI in auto industry. While AI has been able to achieve remarkable success over the last 10 years\, can it really be trusted?  What does trustworthy AI look like in the context of connected vehicles and advanced driver-assistance systems (ADAS)?  To create an ADAS for all\, it’s paramount that the AI systems in the vehicle be trusted and work for everyone.  This is especially important given the nature of ADAS as a safety-critical\, cyber-physical\, and people-centric system of systems.  In this talk\, the presenter will outline a number of challenges in building AI systems which could potentially be deployed in future ADAS. \nSpeaker Dr. Jacob Bond leads trustworthy AI research at General Motors R&D.  In addition to his work on ensuring AI systems in the vehicle can be trusted\, his research looks at how to keep AI systems private and how to ensure cloud and vehicle systems can establish secure communications.  After receiving a Ph.D. in computational mathematics and cryptography from Purdue University\, he joined General Motors’ Product Cybersecurity organization\, focusing on applications of public-key cryptography.  Jacob then began investigating the security of AI systems\, moving to GM R&D and expanding his work to encompass the trustworthiness of AI systems.
URL:https://che.northeastern.edu/event/leaders-event-ai-challenges-in-the-deployment-of-advanced-driver-assistance-systems/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20211102T100000
DTEND;TZID=America/New_York:20211102T110000
DTSTAMP:20260417T055209
CREATED:20211019T180302Z
LAST-MODIFIED:20211021T235946Z
UID:3830-1635847200-1635850800@che.northeastern.edu
SUMMARY:Chemical Engineering Programs Webinar
DESCRIPTION:Please join faculty and graduate admissions staff at a webinar discussing the Chemical Engineering departmental program offerings and experiential learning opportunities in the Graduate School of Engineering.
URL:https://che.northeastern.edu/event/chemical-engineering-programs-webinar/
ORGANIZER;CN="Graduate School of Engineering":MAILTO:coe-gradadmissions@northeastern.edu
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20211103T120000
DTEND;TZID=America/New_York:20211103T130000
DTSTAMP:20260417T055209
CREATED:20211101T174011Z
LAST-MODIFIED:20211101T174011Z
UID:3852-1635940800-1635944400@che.northeastern.edu
SUMMARY:ChE Seminar Series: Detection\, Prediction\, and Visualization of Monolayer Phase Separation on Metallic Nanoparticles
DESCRIPTION:ChE Seminar Series Presents: \nDr. David L. Green \nMaterials Science\, Chemical Engineering\, and Mechanical Engineering Departments \nUniversity of Virginia \nAbstract: The goal is to gain fundamental insights into the factors that dictate the synthesis of monolayer-protected nanoparticles and translate them into rational design strategies for novel functional soft materials. He is interested in monolayer self-assembly\, polymer grafting\, and nanoparticle dispersion. He studies how to exert control over the interface of nanoparticles\, which dictates their degree of compatibility with and assembly in soft materials\, provides reactive sites for attachment of molecules\, such as drug payloads\, and tunes detectable properties\, such as the surface plasmon to a wavelength of interest. David Green is particularly interested in the development of nanoparticles coated with monolayers from mixtures of organic molecules that may also self-assemble into advantageous patterns. As pattern formation in self-assembled monolayers is inextricably linked to their intermolecular interactions\, a key research challenge is the integration of experimental and theoretical techniques to enable de novo design of patterned nanoparticles. \nBio: David Green is an Associate Professor in the Departments of Materials Science and Chemical Engineering at the University of Virginia. He and his team collaborate with chemists\, physicists\, pharmacists\, and oncologists to develop design principles for monolayer-protected nanoparticles.
URL:https://che.northeastern.edu/event/che-seminar-series-detection-prediction-and-visualization-of-monolayer-phase-separation-on-metallic-nanoparticles/
LOCATION:108 SN
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20211112T120000
DTEND;TZID=America/New_York:20211112T130000
DTSTAMP:20260417T055209
CREATED:20211108T194127Z
LAST-MODIFIED:20211108T194127Z
UID:3855-1636718400-1636722000@che.northeastern.edu
SUMMARY:ChE Seminar Series: Designing Optically Active Semiconductor Nanoparticles for Biomedical Applications
DESCRIPTION:ChE Seminar Series Presents: \nDr. Allison Dennis \nAssistant Professor\, Biomedical Engineering and Materials Science and Engineering \nBoston University \nAbstract: \nAlthough the unique optoelectronic properties of semiconductor nanoparticle quantum dots (QDs) enable a variety of commercial products including display technology\, solid state lighting\, and photovoltaics\, different design criteria need to be considered to use these nanoparticles in biomedical devices. Here\, I will discuss how we tailor the composition and optical properties of QDs for a variety of biosensing and bioimaging applications. For example\, I’ll describe how we use bright red and green emitting QDs in a rapid\, instrument-free assay to detect small molecules such as antibiotics in complex water samples and use near infrared and shortwave infrared emitters to improve the clarity and resolution of in vivo imaging in mice. Finally\, I’ll describe how biodegradable and biocompatible plasmonic semiconductor nanoparticles could be used to overcome barriers to clinical translation for photoaccoustic imaging and photothermal therapy applications. Notably\, the efforts to remove heavy metals from the nanoparticles compositions also reduces the environmental impact of QDs developed for energy applications. By carefully considering material properties and engineering design choices\, we develop semiconductor nanoparticles for a wide variety of applications. \nBio: \nAllison Dennis is an assistant professor in Biomedical Engineering and Materials Science and Engineering at Boston University. After graduating with a B.S. in Bioengineering and B.A. in German from Rice University\, Prof. Dennis pursued nanobiotechnology research with Prof. Achim Göpferich in the Department of Pharmaceutical Technology at the University of Regensburg in Germany as a Fulbright Scholar. This research direction was continued during her Ph.D. work with Prof. Gang Bao at the Georgia Institute of Technology and post-doctoral research with Dr. Jennifer Hollingsworth at the Center for Integrated Nanotechnologies at Los Alamos National Laboratory. At Boston University\, the Dennis Lab engages the fundamental material properties of heterostructured semiconductor nanoparticles to optimize them for sensing\, imaging\, fundamental photophysical investigations\, and energy applications. The Dennis Lab appreciates past and current support from intramural and extramural sources including the NIH\, NSF\, and the BU Clinical and Translational Science Institute.
URL:https://che.northeastern.edu/event/che-seminar-series-designing-optically-active-semiconductor-nanoparticles-for-biomedical-applications/
LOCATION:108 SN
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20211116T100000
DTEND;TZID=America/New_York:20211116T110000
DTSTAMP:20260417T055209
CREATED:20211025T211715Z
LAST-MODIFIED:20211025T211715Z
UID:3845-1637056800-1637060400@che.northeastern.edu
SUMMARY:Chemical Engineering Research Webinar
DESCRIPTION:Join Dr. Rebecca Willits on November 16th at 10:00am EST as she conducts a deep dive of her research. This event is open to all prospective students and applicants to the Chemical Engineering department.
URL:https://che.northeastern.edu/event/chemical-engineering-research-webinar/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20211117T120000
DTEND;TZID=America/New_York:20211117T130000
DTSTAMP:20260417T055209
CREATED:20211115T194819Z
LAST-MODIFIED:20211115T194819Z
UID:3865-1637150400-1637154000@che.northeastern.edu
SUMMARY:ChE Seminar Series: Game-Inspired Approaches to Engineering Education Across the Curriculum
DESCRIPTION:ChE Seminar Series Presents: \nDr. Daniel Burkey \nAssociate Dean of Undergraduate Education and Diversity\, Professor-in-Residence in Chemical and Biomolecular Engineering\, and a University Teaching Fellow at University of Connecticut \nAbstract: \nGame-based educational techniques can be an interesting and novel approach to active learning in engineering courses. Because games often exist within their own rule sets\, they can allow students to explore scenarios and make choices that they wouldn’t otherwise make because they are appropriate within the context and the rules of the game. In this talk\, we discuss two different projects involving game-based learning. In the first\, we explore multiple game-based approaches to teaching engineering ethics to freshmen engineering students in a multidisciplinary setting. At the beginning of the semester\, students are given a baseline survey to quantify the sophistication of their ethical reasoning. Over the course of the semester\, different game-based interventions are given to the students\, and the survey instrument again is used to determine any changes in their ethical reasoning. The game-based interventions by their nature allow students to explore ethical reasoning in the context of behavioral ethics. In the second project\, we discuss the development and use of a digital video game to teach process safety to senior chemical engineering students. Our research team developed a survey instrument to gauge the sophistication of student thinking about process safety. Students completing the survey instrument and then completing similar scenarios in the game show statistically significant differences in the types of responses they make\, indicating that different reasoning modes may be activated by the game due to its more authentic and realistic portrayal of the material. \nBio: \nDaniel D. Burkey is the Associate Dean of Undergraduate Education and Diversity\, Professor-in-Residence in Chemical and Biomolecular Engineering\, and a University Teaching Fellow at the University of Connecticut. Dr. Burkey holds his B.S. in Chemical Engineering from Lehigh University in Bethlehem\, PA\, and his M.S.C.E.P. and Ph.D. in Chemical Engineering from the Massachusetts Institute of Technology. Prior to UConn\, he held positions at Northeastern University and at GVD Corporation in Cambridge\, MA. Since joining UConn in 2010\, Dr. Burkey’s area of research has focused broadly on engineering education\, and specifically on moral and ethical development of engineering students\, process safety education\, and game-inspired educational techniques. Dr. Burkey currently serves as a Director of the Education Division of AIChE\, where he runs the Future Faculty Mentoring Program. He is a past program chair of the ASEE Chemical Engineering Division and serves on the publications board of Chemical Engineering Education. In 2020\, he was inducted into the Connecticut Academy of Science and Engineering (CASE) for his contributions to engineering education in the state. In addition to his many teaching awards\, Dr. Burkey is also the recipient of the 2020 AICHE Education Division Innovation Award for his contributions to new pedagogies in chemical engineering education\, as was recently awarded the 2021 ASEE Corcoran Award for the best paper in Chemical Engineering Education in the previous year.
URL:https://che.northeastern.edu/event/che-seminar-series-game-inspired-approaches-to-engineering-education-across-the-curriculum/
LOCATION:108 SN
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20211119T120000
DTEND;TZID=America/New_York:20211119T130000
DTSTAMP:20260417T055209
CREATED:20211118T195449Z
LAST-MODIFIED:20211118T195449Z
UID:3868-1637323200-1637326800@che.northeastern.edu
SUMMARY:ChE Seminar Series: Unwinding Anxiety: An App Based Mindfulness Program
DESCRIPTION:ChE Seminar Series Presents: \nDr. Nancy Lasson\, DO\, FACP\, DipACLM \nPrimary care provider and medical director of the primary care group at the Women’s Medicine Collaborative of LifeSpan Physician Group in Providence\, Rhode Island \nAbstract:  \nAnxiety can be managed by understanding reward-based learning and using mindfulness to interrupt unwanted behavior. Habits form to promote survival. The underlying mechanism is based on reward-based learning. There are areas of the brain where habits run on autopilot. The neo-cortex\, or new brain\, is where mindfulness can help break the cycle of unwanted habits of anxiety. Anxiety as an emotion has associated behaviors\, including worry\, rumination\, stress eating\, and smoking. The goal of unwinding anxiety is to offer an alternative to autopilot habits by employing mindfulness techniques. Multiple studies have demonstrated significant efficacy in this tool. Mindfulness is the awareness that occurs when paying attention in the present moment intentionally\, without judgment. The felt experience of mindfulness replaces autopilot habits like worry and stress. \nBio: \nDr Nancy Lasson is a primary care provider and medical director of the primary care group at the Women’s Medicine Collaborative of LifeSpan Physician Group in Providence\, Rhode Island. She is also a clinical assistant professor of medicine\, Warren Alpert Medical School at Brown University. Dr. Lasson received her B.A. at the University of Pennsylvania in religious studies and cultural anthropology. She studied medicine at the Philadelphia College of Osteopathic Medicine. She is board certified in both internal medicine and lifestyle medicine. She was a primary care physician in Limestone Medicine and Pediatrics of Christiana Care in Wilmington\, Delaware where she achieved a “Top Doctor in Delaware” award in internal medicine. She is a Fellow of the American College of Physicians and Diplomat of the American College of Lifestyle Medicine. Recently she became certified as a behavior change facilitator.  Dr. Lasson’s clinical interests include women’s medical issues and care; preventive medicine\, especially cholesterol management; coronary artery disease and cancer screening; end-of-life care for patients and their families; and mindfulness practices. She is passionate about struggles of the human soul.
URL:https://che.northeastern.edu/event/che-seminar-series-unwinding-anxiety-an-app-based-mindfulness-program/
LOCATION:108 SN
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20211201T080000
DTEND;TZID=America/New_York:20211201T090000
DTSTAMP:20260417T055209
CREATED:20211118T211129Z
LAST-MODIFIED:20211118T211129Z
UID:3870-1638345600-1638349200@che.northeastern.edu
SUMMARY:Learn about the Co-op Program (Disciplinary) Webinar
DESCRIPTION:Please join our Assistant Dean of Co-op at a webinar discussing the Co-op experiential learning opportunities available for graduate students in the departments of Bioengineering\, Chemical Engineering\, Civil & Environmental Engineering\, Electrical & Computer Engineering\, and Mechanical & Industrial Engineering. \nRegister
URL:https://che.northeastern.edu/event/learn-about-the-co-op-program-disciplinary-webinar/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20211201T120000
DTEND;TZID=America/New_York:20211201T130000
DTSTAMP:20260417T055209
CREATED:20211124T023858Z
LAST-MODIFIED:20211124T023858Z
UID:3872-1638360000-1638363600@che.northeastern.edu
SUMMARY:ChE Seminar Series: Orchestrating Cellular Regeneration at Organ Scale
DESCRIPTION:ChE Seminar Series Presents: \nYvon Woappi\, Ph.D. \nK99/R00 MOSAIC Fellow at Harvard Medical School\, Brigham and Women’s Hospital \nAbstract \nLarge scale tissue damage\, such as organ failure and burn injury\, is a leading cause of morbidity and death. However\, the mechanisms underlying full regeneration of organs remain poorly understood. As the largest organ system in the body\, the integumentary system is a composite tissue evolutionarily adapted for healing. Consequently\, its complex physiology requires multifaceted cooperation between several distinct cell populations and cell lineages of embryologically distinct origins. Equally integrated within this dynamic process is local immune response that produces mitogenic and inhibitory signals throughout the restoration procedure. There remains a significant gap in understanding how these processes are orchestrated\, and how various skin cell populations from distinct developmental lineages functionally cooperate to regenerate tissue at organ scale. My research seeks to characterize the molecular language of tissue healing and to harness this malleable dialect for the regeneration of mammalian tissues. Through the development of organoid models of wound regeneration\, and the coupling of these systems with novel gene-editing approaches\, my work is enabling the functional understanding of the multifaceted cellular events executed throughout restorative healing. This seminar will describe these high throughput technologies and will illustrate their utility in identifying novel regulators of tissue healing. \nBio \nDr. Yvon Woappi’s passion for life sciences ignited during his childhood in Douala\, Cameroon and was magnified after his family immigrated to Hanover\, Pennsylvania during his middle school years. He went on to receive his B.S in Biology at the University of Pittsburgh\, and his Ph.D. in Biomedical Sciences as a Grace Jordan McFadden Fellow under Lucia Pirisi at the University of South Carolina. There\, he developed a 3D skin organoid system to study the relationship between epithelial regeneration and virus-induced neoplasia. He subsequently completed postdoctoral training in the Harvard Dermatology Research Training Program at Brigham and Women’s Hospital where he established novel in vivo gene editing systems to understand the contribution of distinct cell lineages in tissue regeneration and cancer. He was recipient of the 2019 Engineering the Genome Award\, and was later selected as a Rising Star in biomedical sciences and engineering by MIT\, Cornell\, BU and Columbia University. Most recently\, Dr. Woappi was awarded the NIH K99/R00 MOSAIC award to launch his independent research career. Away from the bench\, he is an ardent proponent of inclusive excellence and currently sits on the advisory committee for the NIH Continued Umbrella Research Experiences Program at Harvard Medical School.
URL:https://che.northeastern.edu/event/che-seminar-series-orchestrating-cellular-regeneration-at-organ-scale/
LOCATION:108 SN
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20211208T120000
DTEND;TZID=America/New_York:20211208T130000
DTSTAMP:20260417T055209
CREATED:20211202T021738Z
LAST-MODIFIED:20211202T021738Z
UID:3880-1638964800-1638968400@che.northeastern.edu
SUMMARY:ChE Seminar Series: Catalytic Oxidation of Methane\, the “Other” Greenhouse Gas
DESCRIPTION:ChE Seminar Series Presents: \nDr. Michael Harold \nDepartment of Chemical & Biomolecular Engineering\, University of Houston \nAbstract: \nThe abundant domestic natural gas resources has motivated the accelerated development of natural gas powered vehicles and stationary engines.  With the primary constituent of abundant NG being methane (CH4)\, NG has a higher H:C ratio than gasoline or diesel and therefore its combustion produces less CO2.   However\, CH4 is itself a more potent greenhouse gas (GHG) than CO2 with a GHG potential about 85 times that of CO2. Uncombusted CH4 must be eliminated in order to clear the way for the growth in the NG engine market. Current state-of-the-art Platinum Group Metal (PGM) catalysts are ineffective in eliminating methane. Our research is focused on the study and development of a new class of cost effective structured catalysts with reduced PGM loadings for both stoichiometric and lean methane oxidation. For stoichiometric oxidation we show that the combination of spinel mixed metal oxide (AB2O4) addition and lean-rich feed modulation results in significant enhancement in the catalyst performance. Detailed study of feed modulation parameters (frequency\, amplitude)\, catalyst design (composition\, architecture) and spatiotemporal reactor features provide insight into and optimization of the underlying mechanism. The enhancement is attributed to the transient oxidation of methane conversion inhibitors CO and H2 by the spinel. Up to a 30% reduction in PGM loading is possible with negligible loss in performance. For lean oxidation we study and develop an in situ method to regenerate methane oxidation catalysts. Periodic reductant (H2\, CO) pulsing mitigates the detrimental water poisoning of Pd-Pt catalyst. The pulsing is able to regenerate the catalyst deactivated by water by removal of OH-groups from the catalysts surface\, but also promoted its activity after repeated application of pulsing for several hours. This state of high activity is stable for several hours under the tested lean conditions. \nBio: \nMike Harold is the Cullen Engineering Professor in the Department of Chemical and Biomolecular Engineering at the University of Houston.  With expertise in catalysis and reaction engineering\, Harold is the author of more than 180 peer-reviewed papers and book chapters and has given over 350 presentations and invited lectures.  Harold received his BS at Penn State and PhD from the University of Houston (UH).  He joined the faculty at University of Massachusetts at Amherst in 1985 where he became Associate Professor.  In 1993 Harold joined DuPont Company\, where he held technical and managerial positions.  In 2000 Harold became the Dow Chair Professor and Department Chair at UH\, a position he held for 16 years. Mike was appointed Editor-in-Chief of the AIChE Journal in 2012 and will soon end his 10 year term. His honors include the Excellence in Applied Catalysis from the Southwest Catalysis Society in 2019\, the Ester Farfel Award at UH in 2013\, and AIChE Fellow in 2014. \nPlease contact a.ramsey@northeastern.edu for the seminar link.
URL:https://che.northeastern.edu/event/che-seminar-series-catalytic-oxidation-of-methane-the-other-greenhouse-gas/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20211214T120000
DTEND;TZID=America/New_York:20211214T130000
DTSTAMP:20260417T055209
CREATED:20211207T203629Z
LAST-MODIFIED:20211207T203629Z
UID:3882-1639483200-1639486800@che.northeastern.edu
SUMMARY:CILS Seminar: arivis™\, Imaging Software
DESCRIPTION:Join this seminar to learn how to make microscopy image analysis more straightforward. An arivis™ representative will be presenting on topics such as image segmentation\, multiview registration\, storyboard\, colocalization\, and image processing (denoise\, decon\, etc).
URL:https://che.northeastern.edu/event/cils-seminar-arivis-imaging-software/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20220126T120000
DTEND;TZID=America/New_York:20220126T130000
DTSTAMP:20260417T055209
CREATED:20220121T000850Z
LAST-MODIFIED:20220121T012413Z
UID:3913-1643198400-1643202000@che.northeastern.edu
SUMMARY:Materials Exhibiting Biomimetic Carbon Fixation: Kinetic Analysis\, Mechanistic Insights\, and Material Design
DESCRIPTION:ChE Seminar Series Presents: \nDorsa Parviz\, Ph.D. \nDepartment of Chemical Engineering\, Massachusetts Institute of Technology \n Abstract: \nPopulation growth and climate change necessitate a paradigm shift from current chemical and materials production methods to more sustainable approaches with a negative carbon footprint. In view of this\, I will introduce carbon fixing materials (CFM) as a new synthetic platform that\, like plants\, utilize sunlight to photocatalytically reduce ambient CO2 and add to an ever-extending carbon backbone. First\, I will describe a mathematical framework enveloping the main functions of carbon fixing materials to answer basic questions about the kinetics regimes of operation\, photocatalytic requirements\, and limits of functional materials in CFMs. I will also present mechanistic insights on the photocatalytic reduction of CO2 to C1 intermediates as desired intermediates for producing value-added products from CO2. In the second part of my talk\, I will focus on state-of-the-art 2D nanomaterials and strategies for surface engineering these materials in the colloidal state\, addressing challenges in their characterization for applications in photocatalysis. \nBio: \nDorsa Parviz is a postdoctoral researcher at the Massachusetts Institute of Technology\, working with Prof. Michael Strano in the Department of Chemical Engineering. She earned her Ph.D. in 2016 from Texas A&M University under the guidance of Prof. Micah Green\, where she pioneered techniques for high-yield production of 2D nanomaterials\, investigated their colloidal interactions and assembly\, and designed tailored nanosheet-based polymer composites and 3D networks for structural and electrode applications. During her postdoc\, she developed carbon fixing materials at MIT\, establishing a high-throughput photocatalytic reaction screening system to accomplish this vision. In addition\, she has led the research on the preparation and characterization of biocompatible engineered 2D nanomaterials with tailored structure and properties for nanotoxicity studies at NIEHS Nanosafety Center. \nIf unable to attend in person\, please contact a.ramsey@northeastern.edu for the seminar link.
URL:https://che.northeastern.edu/event/materials-exhibiting-biomimetic-carbon-fixation-kinetic-analysis-mechanistic-insights-and-material-design/
LOCATION:024 East Village\, 360 Huntington Ave\, Boston\, MA\, 02115\, United States
GEO:42.3396156;-71.0886534
X-APPLE-STRUCTURED-LOCATION;VALUE=URI;X-ADDRESS=024 East Village 360 Huntington Ave Boston MA 02115 United States;X-APPLE-RADIUS=500;X-TITLE=360 Huntington Ave:geo:-71.0886534,42.3396156
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20220202T120000
DTEND;TZID=America/New_York:20220202T130000
DTSTAMP:20260417T055209
CREATED:20220121T000612Z
LAST-MODIFIED:20220121T012456Z
UID:3911-1643803200-1643806800@che.northeastern.edu
SUMMARY:Platinum: Not as Noble as We Thought
DESCRIPTION:ChE Seminar Series Presents: \nArthur Shih\, Ph.D. \nLeiden Institute of Chemistry\, Leiden University\, The Netherlands \nAbstract \nUnderstanding of catalysis at a fundamental level has historically lagged behind its commercial counterpart with the Haber-Bosch ammonia synthesis process and catalytic converters as pertinent examples [1]. This historical paradigm\, however\, is shifting with the advancement of computing prowess and collaboration. We will discuss how experiments and density functional theory (DFT) computations led us to discover that platinum\, a noble metal that is frequently utilized as a catalyst in the cathode of fuel cells\, restructures when the voltage is held constant between fuel-cell relevant voltages of 0.6 and 1.0 V on a reversible hydrogen electrode scale (VRHE) [2]. \nAn anomalous reduction feature at ~0.53 VRHE was observed on a Pt(111) single crystal in Ar-saturated HClO4 after holding at the fuel-cell relevant voltage of 0.8 VRHE (Figure 1). Decades of research has established that Pt(111) in HClO4 oxidizes H2O to adsorbed *OH between 0.6 and 1.0 VRHE [3-5] and this current model is unable to explain the anomalous feature. Using a combination of computational\, electrochemical\, spectroscopic\, and imaging probes\, we find that holding the voltage between 0.6 and 1.0 VRHE results in a mildly-roughened Pt(111) surface [6]\, presumably due to an *OH-induced release of surface stress. The catalytic performance of this mildly roughened Pt(111) was tested for the oxygen reduction reaction (ORR) and carbon monoxide oxidation (CO Oxidation) where it was found that the ORR rate is seemingly structure insensitive and CO Oxidation rate is surprisingly structure sensitive [7]. Overall\, this discovery demonstrates the importance of understanding how dynamic and steady operating conditions influence the electrode-electrolyte interface – critical for predicting\, designing\, and improving current commercial technologies and opening doors for the development of future technologies. \nBio \nArthur Shih’s research interests are in catalysis for the sustainable production of chemicals and energy\, with emphasis on utilizing reaction kinetics and spectroscopy to understand catalytic mechanisms. He obtained his bachelor’s in Chemical Engineering from the University of Michigan during which he developed computer-based resources with H. Scott Fogler for his textbook “Elements of Chemical Reaction Engineering” and explored several research areas ranging from cancer detection to polymers to CO2 capture. He then earned his Ph.D.\, also in Chemical Engineering\, from Purdue University with Fabio H. Ribeiro where he investigated the thermal-catalytic reduction of toxic nitrogen oxides in catalytic converters. Inspired by the growth and prowess of computational chemistry coupled with a desire to capitalize on cheap renewable electricity for the environment\, he then moved to Leiden University and completed a postdoc in Chemistry with Marc Koper on the electrocatalysis of water splitting to H2 and O2 over well-defined single crystal electrodes. During that time he collaborated with several computational chemists around the world. He is currently a postdoctoral scholar in Materials Science and Engineering at Northwestern University with Sossina Haile working on nitride catalysts for high temperature electrochemical ammonia synthesis. \nIf unable to attend in person\, please contact a.ramsey@northeastern.edu for the link.
URL:https://che.northeastern.edu/event/platinum-not-as-noble-as-we-thought/
LOCATION:024 East Village\, 360 Huntington Ave\, Boston\, MA\, 02115\, United States
GEO:42.3396156;-71.0886534
X-APPLE-STRUCTURED-LOCATION;VALUE=URI;X-ADDRESS=024 East Village 360 Huntington Ave Boston MA 02115 United States;X-APPLE-RADIUS=500;X-TITLE=360 Huntington Ave:geo:-71.0886534,42.3396156
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20220209T120000
DTEND;TZID=America/New_York:20220209T130000
DTSTAMP:20260417T055209
CREATED:20220207T195452Z
LAST-MODIFIED:20220207T195452Z
UID:3924-1644408000-1644411600@che.northeastern.edu
SUMMARY:Capture and Conversion of CO2 – Towards CO2 Recycling
DESCRIPTION:ChE Seminar Series Presents: \nJuliana Carnerio\, Ph.D \nPostdoctoral Research Fellow \nSchool of Chemical Engineering & Biomolecular Engineering\, Georgia Institute of Technology \nAbstract: \nOur current global fossil-based economy produces significant environmental\, economic\, and social challenges. Such complex challenges are the defining issues of our time\, pushing society toward stepwise decarbonization of our energy and consumption economy. Ideally\, the aim is a more just and reliable economy\, with minimal social and environmental burdens and the redistribution of economic and environmental benefits. To this end\, a circular carbon economy – which integrates energy\, chemical\, and waste management sectors – offers an opportunity to rethink our linear model. With the CO2 recycling system playing a central role in this proposed model\, the scientific community responds with efforts in R&D to create a suite of CO2 mining and utilization technologies. \nIn the first part of my talk\, I will tackle the electrochemical conversion of CO2 at an elevated temperature regime\, using Reversible Solid Oxide Electrochemical Cells (RSOECs). The optimization of the performance of the oxygen and fuel electrodes in these cells has been hindered by the limited understanding of the factors that govern the O2 and CO2 chemistries. As such\, I will discuss our efforts toward developing design principles for the identification of optimal electrocatalysts for these electrode reactions. We used a combination of theoretical calculations\, controlled synthesis\, advanced characterization\, and testing to show that the binding energy of atomic oxygen can be used as an activity descriptor for these processes. It was found that a compromise in the oxophilicity of the electrocatalyst was required to achieve optimal activity and stability. Our theory-guided design principles successfully identified: (i) Cobalt-doped La2NiO4 as a highly active material for O2 electrocatalysis\, and (ii) Fe\, the most oxophilic metal tested\, as a highly active metal for CO2 electrochemical reduction. However\, Fe exhibited unstable electrochemical behaviors induced by the oxidation of the metal under electrochemical CO2 reduction conditions in SOECs. This phenomenon ratifies the importance of the strength of oxygen binding on the electrocatalyst surface as a descriptor of activity and stability for CO2 electrolysis in SOECs. \nIn the second part of my talk\, I will highlight our work on adsorptive materials for the direct air capture (DAC) of atmospheric CO2. We explore the role of atmospheric humidity as an essential stability parameter for DAC processes employing solid amine adsorbents. We demonstrate this by using prototypical class 1 aminopolymer-type solid sorbents that allow for flexibility in the support use. Sorbent deactivation was investigated by means of several complementary factors\, including (i) the relative loss in amine efficiency determined via time-course CO2 sorption\, (ii) elemental analysis\, and (iii) in situ IR spectroscopy to obtain an understanding of the role of water on the sorbent degradation process. Our findings provide important insights into the relevant parameters that impact the effective design of DAC sorbents and processes for different climatic environments\, allowing tailoring of sorbent formulations to overcome the challenges associated with highly varied conditions in which a DAC process must operate. \nBio: \nDr. Juliana Carneiro is a postdoctoral research fellow in the School of Chemical Engineering & Biomolecular Engineering at the Georgia Institute of Technology with Professor Christopher W Jones. She received her Ph.D. in Chemical Engineering from Wayne State University in 2019 under the supervision of Prof. Eranda Nikolla. Her research interests lie in developing active\, selective\, and stable electrocatalysis for electrochemical conversion and separation processes\, including the electrochemical recycling/upcycling of post-consumer plastics\, the capture and storage of CO2 from oceans\, and the capture and conversion of atmospheric CO2. She is the recipient of several awards\, including\, but not limited to the 2017-2018 Ralph H. Kummler Award for Distinguished Achievement in Graduate Student Research\, 2018 Women’s Initiatives Committee’s (WIC) AIChE Travel Award\, and the prestigious Student Presentation Awards at the (i) Gordon Research Conference on Catalysis\, (ii) the Michigan Catalysis Society.
URL:https://che.northeastern.edu/event/capture-and-conversion-of-co2-towards-co2-recycling/
LOCATION:024 East Village\, 360 Huntington Ave\, Boston\, MA\, 02115\, United States
GEO:42.3396156;-71.0886534
X-APPLE-STRUCTURED-LOCATION;VALUE=URI;X-ADDRESS=024 East Village 360 Huntington Ave Boston MA 02115 United States;X-APPLE-RADIUS=500;X-TITLE=360 Huntington Ave:geo:-71.0886534,42.3396156
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BEGIN:VEVENT
DTSTART;TZID=America/New_York:20220216T090000
DTEND;TZID=America/New_York:20220216T100000
DTSTAMP:20260417T055209
CREATED:20220210T013003Z
LAST-MODIFIED:20220210T013003Z
UID:3936-1645002000-1645005600@che.northeastern.edu
SUMMARY:Accelerating the Transition to Carbon Neutrality
DESCRIPTION:ChE Seminar Series Presents: \nMadga Barecka\, Ph.D. \nPost-Doc at University of Cambridge\, Research Centre in Singapore \nAbstract \nTransition to Net Zero 2050 requires immediate and drastic changes in the current manufacturing methods. This transformation is difficult to realize without disrupting the existing industries and putting at risk the delivery of the products that our society relies on. To address this challenge\, I proposed an alternative approach: use of novel\, carbon-neutral technologies such as CO2 electrolysis as a retrofit\, which operates in parallel to an existing chemical plant\, can be installed with a minimum disruption to the ongoing manufacturing activities and leads to a meaningful reduction of the carbon footprint. This technology\, Carbon Capture On-site Recycling\, will be illustrated with examples of several chemical manufacturing processes\, where\, if fully deployed\, it could allow to save annually up to 10 Gt of CO2 emissions by 2050. \nThis work is a part of my broader vision on disrupting the global carbon cycle through both discovery and scaling of circular production methods for chemical\, pharmaceutical and environmental sectors. How to encourage the industry to change and adopt innovative technologies? How to functionally reproduce photosynthesis to deliver carbon neutral chemicals? How to improve the access to medicines for those most exposed to distribution injustice? In my talk\, I will discuss my current and future research that will significantly contribute to answering these questions. \nBio \nDr. Magda H. Barecka is a Post-Doc at University of Cambridge\, Research Centre in Singapore. She is interested in accelerating the adoption of CO2 conversion\, powered by renewable energy\, and the development of economically viable and scalable carbon neutral production methods. Dr. Barecka holds a PhD degree from TU Dortmund University (Germany) and was the first PhD candidate to be awarded the title as a Double Diploma certificated together with Lodz University Technology (Poland). She is a chemical engineer with expertise in process intensification\, retrofitting and design\, developed in academia and private sector. As a part of her PhD thesis\, she developed a methodology supporting implementation of intensified technologies in the chemical manufacturing\, which was transferred to Industry (Processium company\, France/Brazil). After the completion of her PhD\, she joined pharmaceutical/fine chemicals sector in Switzerland and worked on the design of manufacturing lines\, as well as established collaborations with Academia towards the development of algorithms accelerating process development. After this\, she came back to the research sector to deploy her process design experience in the field of carbon capture and utilization. Dr. Barecka is currently working in the intersection of CO2 electrolysis process design\, reaction optimization\, integration with renewable energy sources\, and techno-economic analysis for CO2-based manufacturing methods that can disrupt the carbon cycle. \nPlease contact a.ramsey@northeastern.edu for the remote seminar link.
URL:https://che.northeastern.edu/event/accelerating-the-transition-to-carbon-neutrality/
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DTSTART;TZID=America/New_York:20220223T120000
DTEND;TZID=America/New_York:20220223T130000
DTSTAMP:20260417T055209
CREATED:20220218T231713Z
LAST-MODIFIED:20220218T231713Z
UID:3967-1645617600-1645621200@che.northeastern.edu
SUMMARY:Accelerating Research Along the Path to Commercialization
DESCRIPTION:There are a variety of steps required to transition technologies from the research lab to the marketplace. Each step comes with its own set of questions and challenges. How do you protect your innovation and when is the right time? What is the right path to market? What are the obstacles to get there? What resources are available for researchers and entrepreneurs? \nRepresentatives from Northeastern’s Center for Research Innovation (CRI) will help to answer these questions. The CRI is focused on accelerating the advancement of Northeastern research from lab to market\, maximizing its impact\, for the benefit of society. \nTheir talk will be followed by a Q&A session\, providing ample opportunity for researchers to raise any questions and discuss issues related to intellectual property\, technology commercialization\, and entrepreneurship. \nSpeakers:  \nMark Saulich \nAs Associate Director of Commercialization\, Mark and his team are focused on the commercialization of Northeastern research. Industry engagement is at the core of their efforts\, identifying opportunities to solve real world challenges by leveraging Northeastern innovations. Prior to joining the CRI team\, Mark spent several years working at yet2\, a global open innovation consulting company\, leading technology scouting projects for several Fortune 1000 companies. \nKatie Hemphill \nAs Director of Technology Ventures and Talent Network\, Katie leads the development of a pipeline that encourages the discovery\, formation\, launch and growth of new ventures. In addition to managing the various venture programs at CRI\, she continues to cultivate a team of executive talent who mentor and support spinouts as they launch and scale. Prior to joining CRI\, Katie served as Associate Director of the McCarthy(s) Venture Mentoring Network (VMN) at Northeastern’s Center for Entrepreneurship Education at D’Amore-McKim School of Business. The VMN is a global network of volunteer mentors who give time and talent to early-stage startups based on timely business challenges.
URL:https://che.northeastern.edu/event/accelerating-research-along-the-path-to-commercialization/
LOCATION:024 East Village\, 360 Huntington Ave\, Boston\, MA\, 02115\, United States
GEO:42.3396156;-71.0886534
X-APPLE-STRUCTURED-LOCATION;VALUE=URI;X-ADDRESS=024 East Village 360 Huntington Ave Boston MA 02115 United States;X-APPLE-RADIUS=500;X-TITLE=360 Huntington Ave:geo:-71.0886534,42.3396156
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BEGIN:VEVENT
DTSTART;TZID=America/New_York:20220224T120000
DTEND;TZID=America/New_York:20220224T133000
DTSTAMP:20260417T055209
CREATED:20220211T021747Z
LAST-MODIFIED:20220211T021747Z
UID:3938-1645704000-1645709400@che.northeastern.edu
SUMMARY:CILS Seminar: Photoacoustics from VisualSonics
DESCRIPTION:Join this seminar to learn about the capabilities of photoacoustics in research ranging from oncology and molecular biology to cardiology and neurobiology. \nThe presentation from VisualSonics will be followed by a student presentation from Kevin Bardon in the Clark Lab\, focusing on where his research will go with this technology. Visit Vevo LAZR-X for more details about the instrument.
URL:https://che.northeastern.edu/event/cils-seminar-photoacoustics-from-visualsonics/
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BEGIN:VEVENT
DTSTART;TZID=America/New_York:20220301T103000
DTEND;TZID=America/New_York:20220301T113000
DTSTAMP:20260417T055209
CREATED:20220216T200737Z
LAST-MODIFIED:20220222T235523Z
UID:3943-1646130600-1646134200@che.northeastern.edu
SUMMARY:MathWorks Week: Climate\, Energy and the Built Environment
DESCRIPTION:Join MathWorks engineers and Northeastern faculty for these insightful seminars in Climate Change\, Quantum Computing\, and AI. \n\nClimate\, Energy and the Built Environment\nTuesday\, March 1\, 10:30 am – 11:30 am\nRegister: MathWorksNUSymposiumClimate.eventbrite.com \nInsights of climate changes from the Common Era: an Artificial Intelligence view\nJianghao Wang\, MathWorks \nThe rapid global warming seen in observations over the past 150 years shows nearly global coherence\, the spatiotemporal coherence of climate epochs earlier in the Common Era (the past 2\,000 years)\, however\, has yet to be robustly tested. Understanding how the climate system works and how historical temperature changes shed light on the study of anthropogenic climate change. \nModeling the Stochastic Dynamics of Rotating Wind Turbine Blades\nLuca Caracoglia\, Professor\, Dept. of Civil and Environmental Engineering \nThis presentation describes the results of recent research activities\, examining the dynamic modeling of wind turbine blades under the influence of various sources of input error and noise. The presentation will focus on the flutter phenomenon. Flutter is a flow-induced dynamic instability that results from the coupling between flap-wise bending mode and torsional mode of the rotating blade. \nLocating Damage in Structural Systems\nDennis Bernal\, Professor\, Dept. of Civil and Environmental Engineering \nThis presentation outlines the basic ideas behind some techniques used to localize damage applicable in cases where the structure is large\, and the number of sensors is small. Visual inspection has been the traditional procedure used to check the condition of structural systems but there is significant interest in devising ways to replace or enhance this approach by incorporating information from sensors.
URL:https://che.northeastern.edu/event/mathworks-week-at-northeastern-university/
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BEGIN:VEVENT
DTSTART;TZID=America/New_York:20220302T120000
DTEND;TZID=America/New_York:20220302T130000
DTSTAMP:20260417T055209
CREATED:20220228T194506Z
LAST-MODIFIED:20220228T194506Z
UID:3976-1646222400-1646226000@che.northeastern.edu
SUMMARY:Development of micro-magnets for bio-medical applications
DESCRIPTION:ChE Seminar Series Presents: \nNora M. Dempsey \nUniv. Grenoble Alpes\, CNRS\, Grenoble INP\, Institut NEEL\, 38000 Grenoble\, France \nAbstract: \nMagnetic flux sources are used to manipulate biological entities (cells\, embryos\, DNA\, proteins…). The magnetic field gradients produced by a flux source scales up as its size is decreased\, resulting in increased force per unit volume. Hard magnetic flux sources are particularly interesting for compact and / or portable applications while the force produced by soft magnetic flux sources on a target object are easily varied.  There is thus great potential for using both hard and soft micro-magnets as flux sources in biology and medicine. \nIn this talk I will briefly review our work on the development and micro-patterning of magnetic films\, in particular Rare Earth – Transition Metal hard magnetic films\, and the low-cost fabrication of micro-magnet arrays based on powder-polymer composites. I will then give examples of bio-medical applications of the micro-magnets we have developed. To wrap up I will discuss potential uses of high intensity pulsed magnetic field sources in bio-medical applications. \nBiography: \nNora Dempsey received her PhD from Trinity College Dublin\, Ireland\, in 1998. Since then she has been based at Institut Néel\, CNRS Grenoble in France. She works on functional magnetic materials\, with an emphasis on hard magnetic materials in film form. These films are used as model systems to guide the development of bulk magnets\, and also to develop micro-magnets for applications in biology\, medicine\, telecommunications and energy management. \nPlease contact a.ramsey@northeastern.edu for the remote seminar link.
URL:https://che.northeastern.edu/event/development-of-micro-magnets-for-bio-medical-applications/
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