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X-ORIGINAL-URL:https://www.quantumx.washington.edu
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TZID:America/Los_Angeles
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DTSTART:20250309T100000
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DTSTART:20251102T090000
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BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260501T163000
DTEND;TZID=America/Los_Angeles:20260501T173000
DTSTAMP:20260427T222126Z
CREATED:20260427T220717Z
LAST-MODIFIED:20260427T222126Z
UID:10478-1777653000-1777656600@www.quantumx.washington.edu
SUMMARY:QASMTrans: QASM Compilation Framework with Pulse Generation (Audience: Undergraduates)
DESCRIPTION:
URL:https://quantumclubuw.notion.site/Quantum-Leap-333f77524d31808a84dfc6551c7eaad3?p=336f77524d31818787f6f74b427afdb7&#038;pm=c#new_tab
LOCATION:Washington
CATEGORIES:Physics
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260504T143000
DTEND;TZID=America/Los_Angeles:20260504T152000
DTSTAMP:20260504T083025Z
CREATED:20251212T232748Z
LAST-MODIFIED:20260504T083025Z
UID:7834-1777905000-1777908000@www.quantumx.washington.edu
SUMMARY:MSE Seminar: Chenhao Jin
DESCRIPTION:Event interval: Single day eventAccessibility Contact: Matthew Yankowitz\, myank@uw.eduEvent Types: Lectures/Seminars \nTitle: Probing emergent excitations in semiconducting moiré superlattices \nAbstract: Semiconducting moiré superlattices recently emerged as an attractive platform for engineering new quantum phenomena. While a plethora of intriguing ground states are reported\, their dynamics and excitations remain largely unexplored\, which govern their responses to intrinsic fluctuations and external driving. In this talk\, I will discuss our recent efforts to investigate excitations in semiconducting moiré superlattices. Using an ultrafast wide-field imaging technique\, we record their complete space-time evolution\, such as space-and-time-resolved transport. This allows us to simultaneously capture and separate multiple collective excitations\, identify their nature and distinguish them from single-particle ones\, which have been challenging from steady-state measurements. These emergent excitations govern dynamic responses of the system and play a central role in phase stability and transition. Our results highlight new insights encoded in collective excitations and open avenues for studying and engineering correlated quantum systems through nonequilibrium approaches. \nBio: Dr. Chenhao Jin is an assistant professor of Physics at UC Santa Barbara. He received a B.S. in Physics from Peking university and PhD in Physics from UC Berkeley. He was a Kavli fellow at Cornell University between before moving to UC Santa Barbara in 2021. Dr. Jin’s research focuses on developing new optical spectroscopy and imaging techniques to "watch" quantum phenomena in space and time; and has made seminal contributions to optical studies of van der Waals materials and moiré superlattices. Dr. Jin has received multiple awards\, including AFOSR YIP award\, NSF CAREER award\, Blavatnik Regional Awards for Young Scientists\, and Sloan Research Fellowship.
URL:https://www.quantumx.washington.edu/calendar/mse-seminar-chenhao-jin/
LOCATION:Washington
CATEGORIES:Materials Science & Engineering
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260504T160000
DTEND;TZID=America/Los_Angeles:20260504T160000
DTSTAMP:20260429T214612Z
CREATED:20260319T222151Z
LAST-MODIFIED:20260429T214612Z
UID:9458-1777910400-1777910400@www.quantumx.washington.edu
SUMMARY:: TBA
DESCRIPTION:: TBA\nPAA A102\nColloquia\nhttps://phys.washington.edu/events/2026-05-04/tba-0
URL:https://www.quantumx.washington.edu/calendar/physics-seminar-ken-van-tilburg-stanford-university/
LOCATION:PAA A102
CATEGORIES:Physics
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260504T160000
DTEND;TZID=America/Los_Angeles:20260504T170000
DTSTAMP:20260504T193046Z
CREATED:20251211T214549Z
LAST-MODIFIED:20260504T193046Z
UID:7897-1777910400-1777914000@www.quantumx.washington.edu
SUMMARY:P. C. Cross Endowed Lecture in Physical Chemistry: Maksym Kovalenko
DESCRIPTION:Event interval: Single day eventCampus location: Bagley Hall (BAG)Campus room: BAG 154Accessibility Contact: chem59x@uw.eduEvent Types: Lectures/SeminarsEvent sponsors: This lecture is supported by the Paul C. Cross Endowed Fund\, dedicated to the memory of Professor Paul C. Cross by his family and many friends and colleagues in 2002.\nProf. Cross was a distinguished physical chemist who led the effort to elevate the UW Department of Chemistry to national prominence when he served as professor and chair from 1949 to 1961. Prof. Cross promoted departmental growth through the expansion of the graduate program\, his emphasis on the acquisition and construction of revolutionary new instrumentation\, and his encouragement of faculty to secure external federal funding to expand their research programs.Link: https://kovalenkolab.ethz.ch/research.html \nP. C. Cross Endowed Lecture in Physical Chemistry \n"Quantum light sources using colloidal perovskite quantum dots"Professor Maksym Kovalenko - Department of Chemistry and Applied Biosciences\, ETH ZurichHost: David Ginger \nLead halide perovskite nanocrystals (LHP NCs) – the latest generation of colloidal quantum dots (QDs) – are intrinsically bright emitters without the need for epitaxial wide-bandgap shells. In recent years\, LHP NCs have emerged as the most intensively studied QD material\, challenging the field's foundational paradigms in nearly every respect. They are the first QDs to exhibit excitonic coherence on timescales comparable to their radiative lifetimes (at cryogenic temperatures)\, thus setting the stage for their use as sources of indistinguishable photons. Their giant oscillator strength effect enables extremely fast emission (lifetimes as short as 60 ps) even in relatively large NCs\, while maintaining single-photon emission. Periodic ensembles of LHP NCs have further demonstrated collective\, accelerated radiative decay – superfluorescence – a phenomenon previously unseen in colloidal systems. The excitonic fine structure of LHP NCs can be readily engineered through shape anisotropy. Furthermore\, by simple near-field coupling to highly chiral plasmonic nanostructures\, their otherwise linearly polarized emission becomes fully chiral\, establishing LHP NCs as the first fully chiral colloidal single-photon emitters. LHP NCs are therefore attractive as scalable\, chemically synthesized quantum dot materials for applications in quantum imaging\, sensing\, communication or even computing. The presentation will summarize the contributions of my interdisciplinary team and our international collaborators\, whose names will be acknowledged in the presentation and accompanying notes.
URL:https://www.quantumx.washington.edu/calendar/p-c-cross-endowed-lecture-in-physical-chemistry-maksym-kovalenko/
LOCATION:Bagley Hall (BAG)
CATEGORIES:Chemistry
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260504T160000
DTEND;TZID=America/Los_Angeles:20260504T170000
DTSTAMP:20260310T193040Z
CREATED:20251218T214943Z
LAST-MODIFIED:20260310T193040Z
UID:8019-1777910400-1777914000@www.quantumx.washington.edu
SUMMARY:Ken Van Tilburg\, NYU\, Stanford
DESCRIPTION:PAA A-102Colloquiahttps://phys.washington.edu/events/2026-03-09/tba
URL:https://www.quantumx.washington.edu/calendar/ken-van-tilburg-nyu-stanford/
LOCATION:PAA A-102
CATEGORIES:Physics
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260505T133000
DTEND;TZID=America/Los_Angeles:20260505T143000
DTSTAMP:20260310T175918Z
CREATED:20260310T175800Z
LAST-MODIFIED:20260310T175918Z
UID:9429-1777987800-1777991400@www.quantumx.washington.edu
SUMMARY:IQuS Research Seminar: Michael Cervia (University of Washington)
DESCRIPTION:Hybrid option available\, register on event website
URL:https://www.quantumx.washington.edu/calendar/iqus-research-seminar-michael-cervia-uofwashington/
LOCATION:Physics/Astronomy Building\, C-421\, 3910 15th Ave NE\, Seattle\, Washington\, 98195-1560
CATEGORIES:Physics
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260505T153000
DTEND;TZID=America/Los_Angeles:20260505T163000
DTSTAMP:20260505T193034Z
CREATED:20260319T220355Z
LAST-MODIFIED:20260505T193034Z
UID:9243-1777995000-1777998600@www.quantumx.washington.edu
SUMMARY:Chemistry Seminar: Prof. Maksym Kovalenko
DESCRIPTION:Event interval: Single day eventAccessibility Contact: chem59x@uw.eduEvent Types: Academics\,Lectures/SeminarsLink: https://kovalenkolab.ethz.ch/people/prof_dr_maksym_kovalenko.html"TBD"Professor Maksym Kovalenko – Chemistry\, ETH ZurichHost: David Ginger
URL:https://www.quantumx.washington.edu/calendar/chemistry-seminar-prof-maksym-kovalenko/
LOCATION:Washington
CATEGORIES:Chemistry
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260505T193000
DTEND;TZID=America/Los_Angeles:20260505T203000
DTSTAMP:20260324T225133Z
CREATED:20260324T224909Z
LAST-MODIFIED:20260324T225133Z
UID:9935-1778009400-1778013000@www.quantumx.washington.edu
SUMMARY:Dr. John Martinis (UC Santa Barbara and Qolab): Prehistoric quantum bits: experiments testing the fundamental physics of superconducting quantum devices
DESCRIPTION:Abstract \n\n\n\nQuantum mechanics was developed to describe the physics of the small\, for fundamental particles\, atoms and molecules. But does it still work for macroscopic systems? My PhD thesis experiment in 1985 tested this idea\, showing the macroscopic current and voltages in a 1 cm chip obey the quantum phenomena of tunneling and energy-level quantization\, proving that a superconducting circuit can behave as a single `artificial atom.’ Over the last four decades\, many physicists around the world have continued research on quantum devices. The field has evolved from fundamental tests into a high-stakes effort to build quantum bits and a quantum computer. At Google\, our ‘quantum supremacy’ experiment was the culmination of this system-level optimization\, proving that a processor could outpace classical supercomputers by maintaining high-fidelity control over a huge computational (Hilbert) space. Now\, at my startup Qolab\, we are leveraging 300mm semiconductor fabrication to achieve the extreme uniformity and yield necessary to build a useful general-purpose quantum computer. \n\n\n\nBio \n\n\n\nJohn M. Martinis is an experimental physicist whose work laid much of the foundation for superconducting quantum circuits. Trained at the University of California\, Berkeley\, he carried out landmark experiments demonstrating macroscopic quantum tunneling and energy quantization in Josephson-junction circuits\, showing that electrical circuits can exhibit fully quantum behavior. As a long-time research scientist at NIST and professor at UC Santa Barbara\, he developed high-coherence superconducting qubits and precision measurement techniques that became standards in the field. He later led Google’s quantum hardware program\, where his team built and operated large-scale superconducting processors and demonstrated quantum computational advantage. More recently\, he co-founded Qolab\, focusing on scalable\, high-performance quantum hardware. His contributions to macroscopic quantum phenomena and superconducting quantum technology were recognized with the 2025 Nobel Prize in Physics.
URL:https://www.quantumx.washington.edu/calendar/dr-john-martinis-uc-santa-barbara-and-qolab-prehistoric-quantum-bits-experiments-testing-the-fundamental-physics-of-superconducting-quantum-devices/
LOCATION:Kane Hall 130\, 4069 Spokane Ln NE\, Seattle\, Washington\, 98105
CATEGORIES:Physics
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260511T093000
DTEND;TZID=America/Los_Angeles:20260515T093000
DTSTAMP:20260513T204752Z
CREATED:20260513T204455Z
LAST-MODIFIED:20260513T204752Z
UID:10630-1778491800-1778837400@www.quantumx.washington.edu
SUMMARY:Embedded Workshop: Nuclear Hamiltonians for Advancing Nuclear Physics and Beyond
DESCRIPTION:This one-week workshop that is part of the larger five-week program\, ‘Nuclear Hamiltonians for Advancing Nuclear Physics and Beyond’. The speakers will give these talks in-person in room PAT C-520.For the full list of speakers\, talk times\, and general program information\, please visit the 26-1 webpage. \nPlease contact intmail@uw.edu if you have any questions.
URL:https://www.quantumx.washington.edu/calendar/embedded-workshop-nuclear-hamiltonians-for-advancing-nuclear-physics-and-beyond/
LOCATION:PAT C-520\, 3910 15th Ave NE\, Seattle\, Washington\, 98195
CATEGORIES:Physics,Workshops
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260511T143000
DTEND;TZID=America/Los_Angeles:20260511T152000
DTSTAMP:20260511T090032Z
CREATED:20251212T232759Z
LAST-MODIFIED:20260511T090032Z
UID:7835-1778509800-1778512800@www.quantumx.washington.edu
SUMMARY:MSE Seminar: Mit Naik
DESCRIPTION:Event interval: Single day eventCampus room: SIG 134Accessibility Contact: Matthew Yankowitz\, myank@uw.eduEvent Types: Lectures/Seminars \nTitle: Emergence of Moiré Excitons and Taco-Shaped Flat Bands in Twisted Transition Metal Dichalcogenides. \nAbstract: Moiré patterns of 2D van der Waals materials have proven to be an ideal platform to host unusual correlated electronic phases\, emerging magnetism\, and novel exciton physics. In this talk\, I will present state-of-the-art first-principles calculations revealing how structural reconstruction\, flat electronic bands\, and moiré localization collectively shape excitonic states in twisted transition metal dichalcogenide (TMD) heterostructures. These calculations uncover distinct excitonic states with different spatial and optical characteristics and provide microscopic design principles for tailoring excitonic properties in moiré materials. Our predictions have been validated through close collaborations with experiments including reflection contrast spectroscopy\, electron energy-loss spectroscopy\, and scanning tunneling spectroscopy.  Moiré physics in large twist angles have received relatively less attention since the K valley states are largely decoupled between layers at such angles and the superlattice exhibits minimal structural reconstruction. I will discuss our surprising discovery of a new kind of valley system in bilayer transition metal dichalcogenides twisted to a large magic angle\, where interlayer hybridization between like-spin Λ valleys generates extended\, spin-polarized flat bands with quasi-one-dimensional dispersion. These “taco"-shaped valleys form six anisotropic channels that interconnect across the moiré Brillouin zone\, exhibiting alternating spin polarization under sixfold rotation\, reminiscent of altermagnetic textures. The flat band shows a power-law divergent density of states due to its quasi-one-dimensional character\, enhancing the potential for correlated phases. A direct consequence of this flat band observed recently is the emergence of phonon-assisted intervalley absorption peaks in reflection contrast spectra measurements. \nBio: Mit Naik is an assistant professor in the physics department at the University of Texas at Austin working in the field of computational condensed matter physics and material science. His research particularly targets electronic and optical excitations in nanostructured quantum materials studied using first-principles electronic-structure calculations. He obtained his Ph.D. in physics at the Indian Institute of Science\, Bangalore\, and held a postdoctoral position at the University of California\, Berkeley.
URL:https://www.quantumx.washington.edu/calendar/mse-seminar-tbd-7/
LOCATION:Washington
CATEGORIES:Materials Science & Engineering
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260511T160000
DTEND;TZID=America/Los_Angeles:20260511T160000
DTSTAMP:20260501T214532Z
CREATED:20260319T222401Z
LAST-MODIFIED:20260501T214532Z
UID:9459-1778515200-1778515200@www.quantumx.washington.edu
SUMMARY:Physics Seminar: Viviana Cavaliere (Brookhaven National Laboratory)
DESCRIPTION:PAA A102Colloquiahttps://phys.washington.edu/events/2026-05-11/tba
URL:https://www.quantumx.washington.edu/calendar/physics-seminar-viviana-cavaliere-brookhaven-national-laboratory/
LOCATION:PAA A102
CATEGORIES:Physics
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260512T150000
DTEND;TZID=America/Los_Angeles:20260512T150000
DTSTAMP:20260513T205012Z
CREATED:20260513T205012Z
LAST-MODIFIED:20260513T205012Z
UID:10686-1778598000-1778598000@www.quantumx.washington.edu
SUMMARY:Dimer Effective Field Theory
DESCRIPTION:: Dimer Effective Field Theory\nPAT C421\nSeminars\nhttps://phys.washington.edu/events/2026-05-12/dimer-effective-field-theory
URL:https://www.quantumx.washington.edu/calendar/dimer-effective-field-theory/
LOCATION:PAT C421
CATEGORIES:Physics
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260518T143000
DTEND;TZID=America/Los_Angeles:20260518T152000
DTSTAMP:20260518T091526Z
CREATED:20251212T223217Z
LAST-MODIFIED:20260518T091526Z
UID:7836-1779114600-1779117600@www.quantumx.washington.edu
SUMMARY:MSE Seminar: Kayla Sprenger
DESCRIPTION:Event interval: Single day eventAccessibility Contact: Matthew Yankowitz\, myank@uw.eduEvent Types: Lectures/Seminars \nTitle: Engineering Polymer Interfaces via Multiscale Modeling Across Sustainability and Health. \nAbstract: Plastic waste\, materials sustainability\, and biomaterial performance represent interconnected challenges that require molecular-level understanding across a wide range of polymer systems. In the Rationally Designed Immunotherapeutics and Interfaces (RDI) Lab\, we leverage multiscale computational approaches to interrogate and engineer polymer interfaces spanning applications across sustainability and health. Central to our work is the idea that molecular interactions at polymer interfaces govern macroscopic properties including degradation behavior\, catalytic reactivity\, material performance\, and biological response. This seminar will highlight how advanced in silico approaches\, including reactive molecular dynamics simulations and enhanced sampling methods\, can provide molecular-scale insight into complex polymer systems relevant to the plastics circular economy and next-generation biomaterials. First\, I will discuss our work investigating polymer/metal oxide interfaces relevant to catalytic plastics upcycling and hydrogenolysis\, with the goal of understanding how interfacial chemistry influences degradation pathways and catalytic reactivity for mixed plastic waste streams. I will then describe our efforts to investigate polymer/enzyme interfaces governing PET biodegradation\, including computational identification of mutations that may improve PET-degrading enzyme activity and stability. \nBeyond improving strategies for degrading existing plastics\, our lab is also focused on designing sustainable materials from the ground up. Accordingly\, a major focus of the talk will center on our investigations of biomatter-derived bioplastics composed of biologically derived components including proteins\, carbohydrates\, lipids\, and polymers. By integrating molecular simulations with collaborators’ experimental thermomechanical processing and spectroscopy data\, we seek to uncover how molecular composition and intermolecular interactions influence the emergent structure and properties of these sustainable materials. Finally\, I will briefly discuss how many of the same computational frameworks developed for sustainable polymer systems can be extended to biomedical polymer interfaces\, including polymer-protein bioconjugates and polymer-based coatings designed to stabilize proteins and mitigate inflammatory foreign body responses to implanted biomaterials. Collectively\, these studies showcase how multiscale modeling can accelerate rational engineering of polymer interfaces across applications spanning plastics circularity\, sustainable materials\, and health. \nBio: Kayla G. Sprenger\, Ph.D.\, is an Assistant Professor in the Chemical and Biological Engineering Department at the University of Colorado Boulder. Dr. Sprenger received her Ph.D. in Chemical Engineering in 2017 from the University of Washington-Seattle with Dr. Jim Pfaendtner. Her Ph.D. was focused on the development and use of molecular simulation tools to study the structure and function of biomolecules at interfaces. She completed her postdoctoral studies in 2020 at MIT in the Institute for Medical Engineering & Science with Dr. Arup Chakraborty\, developing agent-based models of stochastic biological processes. Her lab at CU Boulder is now focused on utilizing multiscale computational approaches to understand and engineer interfaces for broad applications ranging from sustainable energy to health and medicine.
URL:https://www.quantumx.washington.edu/calendar/mse-seminar-robert-hickey/
LOCATION:Washington
CATEGORIES:Materials Science & Engineering
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260518T160000
DTEND;TZID=America/Los_Angeles:20260518T160000
DTSTAMP:20260501T214532Z
CREATED:20260319T222503Z
LAST-MODIFIED:20260501T214532Z
UID:9460-1779120000-1779120000@www.quantumx.washington.edu
SUMMARY:Physics Seminar: Erez Berg (UC Santa Barbara)
DESCRIPTION:PAA A102Colloquiahttps://phys.washington.edu/events/2026-05-18/tba
URL:https://www.quantumx.washington.edu/calendar/physics-seminar-erez-berg-uc-santa-barbara/
LOCATION:PAA A102
CATEGORIES:Physics
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260520T113000
DTEND;TZID=America/Los_Angeles:20260520T123000
DTSTAMP:20260519T194525Z
CREATED:20260319T220905Z
LAST-MODIFIED:20260519T194525Z
UID:9247-1779276600-1779280200@www.quantumx.washington.edu
SUMMARY:Chemistry Seminar: Prof. Zhi Heng Loh
DESCRIPTION:Event interval: Single day eventCampus location: Chemistry Building (CHB)Campus room: CHB 102Accessibility Contact: chem59x@uw.eduEvent Types: Academics\,Lectures/SeminarsLink: https://web.spms.ntu.edu.sg/~zhiheng/"TBD"Associate Professor Zhi Heng Loh – School of Chemistry\, Chemical Engineering and Biotechnology\, Nanyang Technological University\, SingaporeHost: Munira Khalil
URL:https://www.quantumx.washington.edu/calendar/chemistry-seminar-prof-zhi-heng-loh/
LOCATION:Chemistry Building (CHB)
CATEGORIES:Chemistry
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260522T153000
DTEND;TZID=America/Los_Angeles:20260522T153000
DTSTAMP:20260514T214534Z
CREATED:20260513T205437Z
LAST-MODIFIED:20260514T214534Z
UID:10717-1779463800-1779463800@www.quantumx.washington.edu
SUMMARY:: Direct neutrino mass search with the KATRIN experiment and beyond
DESCRIPTION:: Direct neutrino mass search with the KATRIN experiment and beyond\nCENPA Conference Room (NPL 178)\nSeminars\nhttps://phys.washington.edu/events/2026-05-22/direct-neutrino-mass-search-katrin-experiment-and-beyond
URL:https://www.quantumx.washington.edu/calendar/direct-neutrino-mass-search-with-the-katrin-experiment-and-beyond/
LOCATION:CENPA Conference Room (NPL 178)\, 4311 Mason Place\, Seattle\, Washington\, 98195
CATEGORIES:Physics
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260527T160000
DTEND;TZID=America/Los_Angeles:20260527T170000
DTSTAMP:20260527T194524Z
CREATED:20251212T232653Z
LAST-MODIFIED:20260527T194524Z
UID:7898-1779897600-1779901200@www.quantumx.washington.edu
SUMMARY:Weston T. and Sheila Borden Endowed Lecture in Theoretical Chemistry: Prof. Benedetta Mennucci
DESCRIPTION:Event interval: Single day eventCampus location: Electrical and Computer Engineering Building (ECE)Campus room: ECE 125Accessibility Contact: chem59x@uw.eduEvent Types: Lectures/SeminarsEvent sponsors: This lecture is supported by the Weston and Sheila Borden Endowed Fund in Chemistry\, established by the Bordens in 2015.\nWeston T. Borden served on the University of Washington chemistry faculty for 31 years. His research involved the use of molecular orbital (MO) theory and MO-based calculations to understand and predict the structures and reactions of organic and organometallic molecules. Sheila Borden received her B.Sc. and Ph.D. degrees in chemistry from the University of Newcastle upon Tyne. After a year at the University of Oslo\, she joined the staff of the Royal Society of Chemistry\, where she eventually became managing editor of the RSC's organic chemistry journals. In 2004\, she moved to the University of North Texas to lead the JACS Editorial Office.Link: https://molecolab.dcci.unipi.it/ \nWeston T. and Sheila Borden Endowed Lecture in Theoretical Chemistry \n"Photoactivated biological functions: Bridging Electronic Excitations to Functional Response through Multiscale Simulations"Professor Benedetta Mennucci  – Department of Chemistry\, University of PisaHost: Xiaosong Li \nLiving organisms across all domains of life rely on specialized light-sensitive proteins to detect and respond to light. Although these systems adopt diverse molecular strategies\, they share a common triggering event: the electronic excitation of a chromophoric unit embedded within the protein. This initial excitation is subsequently converted into different forms of energy and propagated through the system\, ultimately leading to a biological response. The underlying processes span multiple spatial and temporal scales\, ranging from ultrafast electronic dynamics localized on the chromophoric unit to much slower\, large-scale conformational changes of the protein matrix. Here\, a multiscale computational framework is presented to describe this cascade of events in a unified manner . Its application to a representative system demonstrates how the approach enables a consistent\, end-to-end description from photoexcitation to functional response . \nReferences Salvadori\, G.\, Mazzeo\, P.\, Accomasso\, D.\, Cupellini\, L. & Mennucci\, B. Deciphering Photoreceptors Through Atomistic Modeling from Light Absorption to Conformational Response. J. Mol. Biol. 436\, 168358 (2024). Mennucci\, B. A quantum chemical perspective of photoactivated biological functions. Pure Appl. Chem. 97\, 1239–1254 (2025). Arcidiacono\, A.\, Bondanza\, M.\, Cupellini\, L. & Mennucci\, B. Atomistic simulations reveal the photoactivation mechanism of a carotenoid-binding photoreceptor. Proc. Natl. Acad. Sci. 123\, e2515214123 (2026). \nGuest parking on campus is hosted by the Department of Chemistry. Please contact us (preferably by May 26) to request a parking registration link. If it is an option for you\, we encourage you to carpool or take public transit.
URL:https://www.quantumx.washington.edu/calendar/weston-t-and-sheila-borden-endowed-lecture-in-theoretical-chemistry-prof-benedetta-mennucci/
LOCATION:Electrical and Computer Engineering Building (ECE)
CATEGORIES:Chemistry
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260601T143000
DTEND;TZID=America/Los_Angeles:20260601T152000
DTSTAMP:20260601T161527Z
CREATED:20251212T223137Z
LAST-MODIFIED:20260601T161527Z
UID:7837-1780324200-1780327200@www.quantumx.washington.edu
SUMMARY:MSE Seminar: Joe Falson
DESCRIPTION:Event interval: Single day eventCampus location: Sieg Building (SIG)Campus room: 134Accessibility Contact: Matthew Yankowitz\, myank@uw.eduEvent Types: Lectures/Seminars \nTitle: Unconventional conventional superconductivity in two dimensions \nAbstract: I will present results on the thin film synthesis and characterization of ultra-thin superconducting compounds ranging from layered intermetallics to refractory metal oxides\, with a focus on their critical field dependence at very low temperatures.  I will show that in dissimilar material system systems\, field-enhanced and field-induced superconductivity is a prevalent phenomenon. By studying these compounds through the lens of competing depairing channels\, we can reveal that it is plausible that in all cases the unconventional behavior is due to interactions with localized magnetic moments in the structure\, without the need for invoking unconventional pairing scenarios as the leading explanation. I will finally provide an outlook for how this may be a useful knob to tune between competing order parameters. \nBio: Joe Falson is an Assistant Professor in the Department of Applied Physics and Materials Science at Caltech\, joining the faculty in 2020. His research focuses on thin film quantum matter\, with a specific focus on ultra-thin\, underexplored materials\, where the lab synthesizes materials using molecular beam epitaxy and studies them using ultra-low temperature techniques. He completed his PhD at the University of Tokyo and his postdoc at the Max Planck Institute for Solid State Research. 
URL:https://www.quantumx.washington.edu/calendar/mse-seminar-joe-falson/
LOCATION:Sieg Building (SIG)
CATEGORIES:Materials Science & Engineering
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260629T103000
DTEND;TZID=America/Los_Angeles:20260629T120000
DTSTAMP:20260528T194530Z
CREATED:20260226T201644Z
LAST-MODIFIED:20260528T194530Z
UID:9040-1782729000-1782734400@www.quantumx.washington.edu
SUMMARY:Chemistry Seminar: Prof. Shun-ichi Ishiuchi
DESCRIPTION:Event interval: Single day eventAccessibility Contact: chem59x@uw.eduEvent Types: Academics\,Lectures/SeminarsLink: https://www.irfi.titech.ac.jp/wrhi-archive/en/people/shun-ichi-ishiuchi/index.html \n"TBD"Professor Shun-ichi Ishiuchi – Department of Chemistry\, Institute of Science TokyoHosts: Matthew Bush and Sotiris Xantheas
URL:https://www.quantumx.washington.edu/calendar/chemistry-seminar-prof-shun-ichi-ishiuchi-institute-of-science-tokyo/
LOCATION:Washington
CATEGORIES:Chemistry
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260716T140000
DTEND;TZID=America/Los_Angeles:20260716T153000
DTSTAMP:20260713T165307Z
CREATED:20260713T165304Z
LAST-MODIFIED:20260713T165307Z
UID:11916-1784210400-1784215800@www.quantumx.washington.edu
SUMMARY:IRL: Qiskit Global Summer School
DESCRIPTION:Qiskit Global Summer School kicks off on Monday\, July 13. \n\n\n\nThis meetup is designed for anyone who has registered with IBM Quantum as a participant in QGSS26. \n\n\n\nCome join us so that we can meet each other\, ask questions\, and find ways to connect during the summer school. \n\n\n\nIf you aren’t registered for QGSS26\, but are interested in learning how to get started with Qiskit\, you can check out these resources: \n\n\n\n\nQiskit YouTube Channel – there are several videos under the heading\, Get Started with Qiskit Today\n\n\n\nIBM Quantum Learning Platform – you could look at this class first\, “Start Using a Quantum Computer”.\n\n\n\n\nNatalie Hawkins is a Tier 2 Qiskit Advocate and mentor for the QGSS26\, as well as a UW CSE alum; she will be hosting the event. She can share things she has learned as a participant at past QGSS’s. \n\n\n\n\n\n\n\n\n\nhttps://www.meetup.com/seattle-quantum-computing-meetup/events/315633098/?eventOrigin=group_events_list
URL:https://www.quantumx.washington.edu/calendar/irl-qiskit-global-summer-school/
LOCATION:Gates Center (CSE2)\, G04\, 3800 E Stevens Way NE\, Seattle\, Washington\, 98195
CATEGORIES:Computer Science & Engineering
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260730T110000
DTEND;TZID=America/Los_Angeles:20260730T120000
DTSTAMP:20260708T162753Z
CREATED:20260629T230113Z
LAST-MODIFIED:20260708T162753Z
UID:11561-1785409200-1785412800@www.quantumx.washington.edu
SUMMARY:Supporting disabled students in research: AccessComputing discussion
DESCRIPTION:Event interval: Single day eventAccessibility Contact: blaser@uw.eduEvent Types: Diversity Equity Inclusion\,Information Sessions\,Lectures/SeminarsEvent sponsors: AccessComputingLink: https://washington.zoom.us/meeting/register/JMkgqE94R2qKuYs29t5vZg#/registrationAccessComputing invites you to join us for an online (Zoom) community discussion about supporting disabled students in research.  We'll have an interactive discussion about the 2022 article Students with Disabilities in Life Science Undergraduate Research Experiences: Challenges and Opportunities by Gin\, Pais\, et al (check out the abstract below!) and how the computing community can benefit from the findings.  Registrants may wish to read the paper in advance of the meeting.Registration RequiredAccommodation Note: Zoom auto captions will be enabled. For ASL\, CART\, or additional accommodations contact Brianna Blaser at blaser@uw.edu. ———————-Students with Disabilities in Life Science Undergraduate Research Experiences: Challenges and Opportunities. Gin LE\, Pais D\, Cooper KM\, Brownell SE. CBE Life Sci Educ. 2022 Jun; 21(2): ar32.Abstract: Individuals with disabilities are underrepresented in postsecondary science education and in science careers\, yet few studies have explored why this may be. A primary predictor of student persistence in science is participating in undergraduate research. However\, it is unclear to what extent students with disabilities are participating in research and what the experiences of these students in research are. To address this gap in the literature\, in study 1\, we conducted a national survey of more than 1200 undergraduate researchers to determine the percent of students with disabilities participating in undergraduate research in the life sciences. We found that 12% of undergraduate researchers we surveyed self-identified as having a disability\, which indicates that students with disabilities are likely underrepresented in undergraduate research. In study 2\, we conducted semistructured interviews with 20 undergraduate researchers with disabilities. We identified unique challenges experienced by students with disabilities in undergraduate research\, as well as some possible solutions to these challenges. Further\, we found that students with disabilities perceived that they provide unique contributions to the research community. This work provides a foundation for creating undergraduate research experiences that are more accessible and inclusive for students with disabilities.This discussion is supported by AccessUR2PhD. Any opinions\, findings\, and conclusions or recommendations expressed in this material are those of the author(s) and do not necessarily reflect the views of the Computing Research Association or the DO-IT Center.
URL:https://www.quantumx.washington.edu/calendar/supporting-disabled-students-in-research-accesscomputing-discussion/
LOCATION:Washington
CATEGORIES:Computer Science & Engineering
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260731T000000
DTEND;TZID=America/Los_Angeles:20260801T235959
DTSTAMP:20260708T162753Z
CREATED:20260629T225841Z
LAST-MODIFIED:20260708T162753Z
UID:11562-1785456000-1785628799@www.quantumx.washington.edu
SUMMARY:CREATE Accessibility Hackathon\, Summer ‘26
DESCRIPTION:Event interval: Ongoing eventCampus location: Bill & Melinda Gates Center for Computer Science & Engineering (CSE2)Accessibility Contact: create-contact@uw.eduEvent Types: Diversity Equity Inclusion\,Special Events\,Student Activities\,WorkshopsEvent sponsors: CREATE and the UW Paul G. Allen Center for Computer Science and EngineeringTarget Audience: Everyone\, regardless of technical experience. People with lived experience of disability encouragedLink: https://create.uw.edu/2026-create-accessibility-hackathon/ \nJoin CREATE to brainstorm ideas for an accessible future through AI.  \nOver two days\, participants will meet as a whole and in groups\, brainstorm project ideas\, start to build solutions\, present their ideas\, and provide feedback. Lunch\, snack\, mentoring and support will be provided. The event will take place on the UW Seattle campus. Virtual attendance is possible for some portions of the event. \nSee the Hackathon web page for details and schedule.Register now
URL:https://create.uw.edu/2026-create-accessibility-hackathon/#new_tab
LOCATION:Bill & Melinda Gates Center for Computer Science & Engineering (CSE2)
CATEGORIES:Computer Science & Engineering
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20261021T160000
DTEND;TZID=America/Los_Angeles:20261021T170000
DTSTAMP:20260708T162744Z
CREATED:20260513T205640Z
LAST-MODIFIED:20260708T162744Z
UID:10646-1792598400-1792602000@www.quantumx.washington.edu
SUMMARY:Weston T. and Sheila Borden Endowed Lecture in Theoretical Chemistry: Dr. Ned Sibert
DESCRIPTION:Event interval: Single day eventCampus room: TBDAccessibility Contact: chem59x@uw.eduEvent Types: Lectures/SeminarsEvent sponsors: This lecture is supported by the Weston and Sheila Borden Endowed Fund in Chemistry\, established by the Bordens in 2015. \nWeston T. Borden served on the University of Washington chemistry faculty for 31 years. His research involved the use of molecular orbital (MO) theory and MO-based calculations to understand and predict the structures and reactions of organic and organometallic molecules. Sheila Borden received her B.Sc. and Ph.D. degrees in chemistry from the University of Newcastle upon Tyne. After a year at the University of Oslo\, she joined the staff of the Royal Society of Chemistry\, where she eventually became managing editor of the RSC’s organic chemistry journals. In 2004\, she moved to the University of North Texas to lead the JACS Editorial Office.Link: https://sibert.chem.wisc.edu/ \nWeston T. and Sheila Borden Endowed Lecture in Theoretical Chemistry \n“Title TBD”Professor Ned Sibert  – Department of Chemistry\, University of WisconsinHost: Anne McCoy
URL:https://www.quantumx.washington.edu/calendar/weston-t-and-sheila-borden-endowed-lecture-in-theoretical-chemistry-dr-ned-sibert/
LOCATION:Washington
CATEGORIES:Chemistry
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BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20261119T123000
DTEND;TZID=America/Los_Angeles:20261119T133000
DTSTAMP:20260708T162335Z
CREATED:20260629T225026Z
LAST-MODIFIED:20260708T162335Z
UID:11426-1795091400-1795095000@www.quantumx.washington.edu
SUMMARY:: Searching for chiral superconductors using ultrasound
DESCRIPTION:Speaker: Brad Ramshaw\, Cornell University\nFor more than a century\, superconductors have been the paradigmatic ‘quantum material’\, providing fundamental discoveries like gauge symmetry breaking and impacting technologies from medical imaging to quantum computing. Despite their central importance\, characterizing new types of superconductors is still a difficult task: all superconductors have zero resistance\, but their more subtle properties related to entanglement and topology are hard to probe experimentally. I will introduce chiral topological superconductors in two dimensions – a type of superconductivity with a ‘knot’ in the superconducting wave function. These superconductors can host Majorana edge modes and bound states in their vortex cores\, but finding a real-life example has proven challenging. I will show how we use ultrasound – deforming a crystalline lattice in a manner not unlike how gravity waves deform spacetime – to test whether a particular superconductor has the ‘right ingredients’ to be a 2D topological superconductor. I will present the progress we have made thus far – ruling out many proposed candidate materials and discovering an unexpected new type of superconductivity along the way. Most recently\, this has led us to the discovery of a multi-component superconducting state in UTe2 under hydrostatic pressure – a state that may indeed be topological. Finally\, I will give a prognosis for what I think the most promising route is for discovering a 2D topological superconductor.
URL:https://phys.washington.edu/events/2026-11-19/searching-chiral-superconductors-using-ultrasound#new_tab
LOCATION:PAT C520
CATEGORIES:Physics
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