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DTSTART;TZID=America/Los_Angeles:20260302T143000
DTEND;TZID=America/Los_Angeles:20260302T153000
DTSTAMP:20260501T205726
CREATED:20251120T224014Z
LAST-MODIFIED:20260302T203029Z
UID:7259-1772461800-1772465400@www.quantumx.washington.edu
SUMMARY:MSE Seminar: Xiaoxi Wang
DESCRIPTION:Event interval: Single day eventCampus location: Bagley Hall (BAG)Campus room: 154Accessibility Contact: Matthew Yankowitz\, myank@uw.eduEvent Types: Lectures/Seminars \nTitle: Materials Development and Case Study for Aerospace Applications \nAbstract: The talk will focus on materials development and case studies for aerospace applications\, highlighting innovations in advanced materials such as composites\, plastics\, and foams used in commercial airplanes. Dr. Wang will cover his career journey\, the critical roles of materials and process engineers in aerospace\, and specific case studies including cryogenic insulation\, foam ducts\, foam art frames\, and expandable tooling for composites repair and manufacturing. Emphasizing the importance of meeting design loads\, environmental conditions\, and maintainability while balancing cost\, manufacturability\, sustainability\, safety\, and lifecycle value. Dr. Wang will also reflect on his professional growth\, encouraging active involvement in professional associations\, persistence\, and embracing diversity\, underscoring the broad impact of materials throughout an aircraft’s lifecycle. \nBio: Dr. Xiaoxi Wang\, a Boeing Technical Fellow and Society of Plastics Engineers (SPE) Fellow\, is from the Boeing Commercial Airplanes Product Development (BAC PD) focusing on Technology\, Materials\, and Sustainability. Holder of 47 issued U.S. patents with 27 more pending\, his work has been adopted across more than 3\,000 Boeing aircrafts\, including 737\, 787 and 777X. Dr. Wang produced over 20 publications for major journals and international conferences. Prior to joining Boeing in 2012\, he was a Senior Scientist and an National Science Foundation (NSF) Grant Awardee/PI in MicroGREEN Polymers Inc. He takes leadership roles in professional organizations including Society of Plastics Engineers (SPE)\, Asian American Engineer of the Year (AAEOY)\, Foam Expo North America\, Boeing collaboration with University of Washington Materials Science & Engineering Department\, Boeing Leadership Network (BLN)\, and Boeing Asian and Pacific Association (BAPA). He was elected as Conference Chair for FOAMS® 2026.Dr. Wang earned his Ph.D. in Mechanical Engineering from University of Washington in 2007. He was named 2025 BCA PD Engineer of the Year.
URL:https://www.quantumx.washington.edu/calendar/mse-seminar-tbd-5/
LOCATION:Bagley Hall (BAG)
CATEGORIES:Materials Science & Engineering
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260302T160000
DTEND;TZID=America/Los_Angeles:20260302T160000
DTSTAMP:20260501T205726
CREATED:20251218T214908Z
LAST-MODIFIED:20260302T191601Z
UID:8018-1772467200-1772467200@www.quantumx.washington.edu
SUMMARY:Dmitri Shklovskii\, Flatiron Institute
DESCRIPTION:PAA A-102Colloquiahttps://phys.washington.edu/events/2026-03-02/tba
URL:https://www.quantumx.washington.edu/calendar/dmitri-shklovskii-flatiron-institute/
LOCATION:PAA A-102
CATEGORIES:Physics
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260305T103000
DTEND;TZID=America/Los_Angeles:20260305T113000
DTSTAMP:20260501T205726
CREATED:20260226T202059Z
LAST-MODIFIED:20260304T213030Z
UID:9045-1772706600-1772710200@www.quantumx.washington.edu
SUMMARY:UW ECE Research Colloquium Lecture Series: Shuhan Liu\, Stanford University
DESCRIPTION:Event interval: Single day eventCampus location: Electrical and Computer Engineering Building (ECE)Campus room: ECE 037Accessibility Contact: events@ece.uw.eduEvent Types: Lectures/SeminarsLink: https://www.ece.uw.edu/colloquia/middas-memory-integration-and-data-dis-aggregation/ \nMIDDAS: Memory Integration and Data Dis-Aggregation \nAbstract \nSince the invention of the integrated circuit in 1958\, the integration of exponentially more devices onto a single chip has transformed    computing—yet memory remains largely separated from logic\, resulting in a “memory wall”. Recent advances in memory research have introduced a variety of new memory technologies. My research focus\, Memory Integration and Data Dis-Aggregation (MIDDAS)\, envisions a future where massive\, diverse memories are physically integrated yet functionally store disaggregated data. MIDDAS encompasses a continuous spectrum of memory characteristics. This is exemplified by BRIDGE (Blended Retention-Indexed Diverse Gain cEll)\, a gain cell memory platform developed in my PhD research. The 2-transistor (2T) gain cell memory offers high density and CMOS integration compatibility. By introducing oxide semiconductor (OS) transistors with ultra-low leakage current (< 1e-17 A/μm)\, BRIDGE expands the design space to support retention times spanning microseconds to seconds. BRIDGE is demonstrated on fabricated N40 CMOS+X monolithic 3D integration chip with Atomic-Layer-Deposited (ALD) Indium Tin Oxide (ITO) FET. Hybrid gain cell (OS-Si) demonstrates 3x density and lower energy compared to high-density (HD) SRAM\, scalable to N5 and beyond. Furthermore\, integrating gain cells with non-volatile memories (e.g.\, RRAM) unlocks synergistic system-level benefits from device-circuit-architecture co-design\, embodying the “1+1>2” philosophy where diverse memory technologies collaboratively enhance system functionality through integration. MIDDAS repositions memory as a scalable\, intelligent toolbox for AI-era computing\, capitalizing on the predictability of memory access\, bridging device innovation with software demands. \nBiography \nShuhan Liu is a PhD candidate at Stanford University\, advised by H.-S. Philip Wong. She earned B.S. degree from Peking University in 2020. She received 2024 IEEE EDS PhD Fellowship and 2024 IEEE IEDM Best Student Paper Award.
URL:https://www.quantumx.washington.edu/calendar/uw-ece-research-colloquium-lecture-series-shuhan-liu-stanford-university/
LOCATION:Electrical and Computer Engineering (ECE)\, Room 037\, 185 W Stevens Wy NE\, Seattke\, Washington\, 98185
CATEGORIES:Electrical & Computer Engineering
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260306T133000
DTEND;TZID=America/Los_Angeles:20260306T143000
DTSTAMP:20260501T205726
CREATED:20251230T225622Z
LAST-MODIFIED:20260407T182845Z
UID:8279-1772803800-1772807400@www.quantumx.washington.edu
SUMMARY:Maxwell Parsons (University of Washington)\, QISE Seminar: Engineering Qubit Control for Scalable Quantum Systems
DESCRIPTION:Abstract \n\n\n\nQuantum computing is advancing along two primary scaling paradigms: distributed quantum systems connected through entanglement networks\, and increasingly large individual quantum processors. Both approaches require not only long-lived qubits\, but control architectures deliberately engineered to support error correction at scale. In my laboratory\, we investigate these paradigms through complementary experimental platforms: color-center quantum memories for networked architectures and reconfigurable neutral-atom arrays for large-scale processors. \n\n\n\nIn color-center systems\, an optically-addressable central electronic spin coherently couples to nearby nuclear spins to form a modular quantum memory with a photonic interface\, suitable for quantum networking. Here\, dominant limitations arise from structured environmental spin-noise and the common fluctuator associated with optical transitions of the electronic state. We are developing control strategies tailored to this noise environment\, engineering microwave and optical protocols that stabilize multi-spin registers and extend usable memory lifetimes in a manner compatible with networked error-correction schemes. \n\n\n\nIn neutral-atom systems\, we explore opportunities enabled by three-dimensional qubit geometries uniquely accessible in optically trapped atom arrays. Three-dimensional connectivity offers architectural advantages for efficient error correction\, but imposes stringent requirements on local optical control and crosstalk suppression. At the same time\, three-dimensional geometries can enable scaling in physical qubit number due to the re-use of optical power across layers of qubits for trapping and gate control.  We are co-designing 3D neutral-atom architectures and scalable optical control hardware to match qubit geometry to fault-tolerant operation and are establishing a dedicated testbed for developing and characterizing these strategies. \n\n\n\nAcross both efforts\, the central theme is control–architecture co-design: engineering qubit control systems that are intentionally matched to geometry\, noise environment\, and error-correction strategy. \n\n\n\nBio \n\n\n\nMax Parsons is an Assistant Professor in the Department of Electrical & Computer Engineering. His research focuses on advancing quantum hardware for computing\, sensing\, and communication by developing scalable control of neutral atoms and solid-state quantum systems. At UW\, he leads efforts in optical control of qubits and experimental testbeds for neutral atom quantum processors and spin-defect quantum memories.  Parsons completed his PhD in Physics at Harvard University in 2016\, where he pioneered techniques for laser cooling and atom-resolved imaging of fermionic atoms for quantum simulation. Prior to joining UW in 2022 to develop the QT3 lab\, he worked in industry on mixed-reality displays at Meta’s Reality Labs and on neutral-atom quantum computing hardware at Atom Computing. He is an inventor on more than 35 patents in quantum computing and mixed-reality technologies.
URL:https://www.quantumx.washington.edu/calendar/maxwell-parsons-university-of-washington/
LOCATION:Electrical and Computer Engineering (ECE)\, Room 037\, 185 W Stevens Wy NE\, Seattke\, Washington\, 98185
CATEGORIES:Electrical & Computer Engineering
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260309T143000
DTEND;TZID=America/Los_Angeles:20260309T153000
DTSTAMP:20260501T205726
CREATED:20251120T223945Z
LAST-MODIFIED:20260309T210026Z
UID:7260-1773066600-1773070200@www.quantumx.washington.edu
SUMMARY:MSE Seminar: Shuolong Yang
DESCRIPTION:Event interval: Single day eventCampus location: Bagley Hall (BAG)Campus room: 154Accessibility Contact: Matthew Yankowitz\, myank@uw.eduEvent Types: Lectures/Seminars \nTitle: Engineering Topological Quantum Matter in Space and Time. \nAbstract: Topology has emerged as a unifying principle in modern condensed matter physics and materials science\, enabling quantum phases that are remarkably robust yet exquisitely sensitive to their underlying environment. While traditional approaches to topological materials discovery rely on chemistry\, the rise of moiré quantum materials suggests a different strategy: engineering topology by tailoring the physical environment. \n In this talk I will highlight my group’s recent efforts to control scalable topological quantum matter using two fundamental physical knobs – space and time. We constructed a unique testbed to manipulate and probe materials at femtosecond time scale and atomic-layer spatial scale . In space\, by precision control of dimensionality\, we demonstrate 2-quintuple-layer Bi2Te3 and MnBi2Te4/Bi2Te3 as robust 2D topological insulators with an inverted gap greater than 100 meV\, suggesting a potential quantum spin Hall effect operating at ambient temperature . In time\, we show that topological electronic states carry intrinsic layer-dependent vibrational fingerprints. By “listening” to these frequencies as the states couple to coherent phonons\, we develop a quantum stethoscope capable of resolving long-standing puzzles in magnetic topological insulators\, including the elusive broken-symmetry energy gap . In combined space-time co-engineering\, I will present our latest results integrating photonic crystal cavities with ultrathin topological insulators to realize cavity-driven Floquet engineering . This platform represents a new class of physical-environment control experiments\, where the ground states of topological materials are reshaped simultaneously in space and time. Together\, these examples illustrate a paradigm in which topological phenomena can be designed and manipulated by engineering the physical environment\, and potentially stabilized near ambient conditions – opening pathways toward scalable quantum materials and devices. \nReferences C. Yan et al. Rev. Sci. Instrum. 92\, 113907 (2021) W. Lee et al. In revision (2026) W. Lee et al. Nature Phys. 19\, 950 (2023) K. D. Nguyen et al. Science Advances 10\, eadn5696 (2024) Y. Bai et al. In preparation \nBio: Dr. Shuolong Yang is an Assistant Professor of molecular engineering at the University of Chicago. He pioneered the approach to combine atomic-level materials synthesis with time-domain photoemission spectroscopy. He is recognized by an NSF CAREER award\, a DOE Early Career award\, and a NASA Early Career Faculty award. He is a Moore Foundation Investigator and named a 2025 Emerging Investigator by Nanoscale.
URL:https://www.quantumx.washington.edu/calendar/mse-seminar-tbd/
LOCATION:Bagley Hall (BAG)
CATEGORIES:Materials Science & Engineering
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260310T133000
DTEND;TZID=America/Los_Angeles:20260310T143000
DTSTAMP:20260501T205726
CREATED:20260310T174419Z
LAST-MODIFIED:20260310T175343Z
UID:9413-1773149400-1773153000@www.quantumx.washington.edu
SUMMARY:IQuS Research Seminar: Stephen Jordan (Google Quantum AI)
DESCRIPTION:Optimization by Decoded Quantum Interferometry \n\n\n\nAchieving superpolynomial speedups for optimization has long been a central goal for quantum algorithms. I will discuss Decoded Quantum Interferometry (DQI)\, a quantum algorithm descended from Regev’s reduction\, that uses the quantum Fourier transform to reduce optimization problems to decoding problems. For approximating optimal polynomial fits over finite fields\, DQI achieves a superpolynomial speedup over known classical algorithms. The speedup arises because the problem’s algebraic structure is reflected in the decoding problem\, which can be solved efficiently. Whether DQI can also attain quantum advantage for algebraically unstructured optimization problems such as max-k-XORSAT remains an open question. One reason for optimism is that the sparsity of the clause structure in max-k-XORSAT is reflected in the dual decoding problem\, which is for LDPC codes. I will describe some current lines of attack on this open question\, as well as generalizations of DQI for preparing Gibbs states of Hamiltonians. This talk will target a broad audience without assuming deep background in quantum algorithms.
URL:https://www.quantumx.washington.edu/calendar/iqus-research-seminar-stephen-jordan-google-quantum-ai/
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:20260310T153000
DTEND;TZID=America/Los_Angeles:20260310T163000
DTSTAMP:20260501T205726
CREATED:20251212T224148Z
LAST-MODIFIED:20260310T220031Z
UID:7841-1773156600-1773160200@www.quantumx.washington.edu
SUMMARY:Chemistry Seminar: Christopher Grieco
DESCRIPTION:Event interval: Single day eventCampus location: Bagley Hall (BAG)Campus room: BAG 260Accessibility Contact: chem59x@uw.eduEvent Types: Academics\,Lectures/SeminarsLink: https://www.auburn.edu/cosam/faculty/chemistry/grieco/index.htm \n"Probing Charge Carriers in Mixed Ionic-Electronic Conducting Polymers"Assistant Professor Christopher Grieco – Department of Chemistry and Biochemistry\, Auburn UniversityHosts: Munira Khalil and David Ginger  \nConjugated polymers continue to emerge as next-generation electronic materials for mixed ionic-electronic conduction applications\, ranging from biomedical sensing to energy storage. However\, their development is hampered by a lack of rational design principles due to missing fundamental knowledge about how ion-charge interactions and dynamic polymer nanostructure influence charge transport and storage along polymer chains. In this talk\, I will first discuss how we are exploiting the ultrafast dynamics of photoexcited charge carriers to provide details on their nanoscale environment and trapping behavior. Then I will show how in situ electronic and vibrational spectroscopy of polymer electrodes can be used to track their complex nanoscale dynamics during charging\, revealing insights into nanostructures that support the formation of mobile carriers. \n  \nDr. Chris Grieco is an assistant professor of chemistry at Auburn University\, where his research group develops laser spectroscopy methods to probe charge carriers in conducting polymers used in electrochemical applications ranging from bioelectronics to batteries. Prior to Auburn\, Chris earned his Ph.D. in chemistry at Penn State University where he worked with Prof. John Asbury studying how to improve exciton and charge carrier dynamics in organic molecules and polymers for solar cells. Chris then worked with Prof. Bern Kohler as a postdoctoral scholar at the Ohio State University\, where he developed ultrafast transient absorption spectroscopy methods for probing the elusive structure and photochemistry of the eumelanin biopigment.
URL:https://www.quantumx.washington.edu/calendar/chemistry-seminar-prof-christopher-grieco/
LOCATION:Bagley Hall (BAG)
CATEGORIES:Chemistry
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260311T113000
DTEND;TZID=America/Los_Angeles:20260311T123000
DTSTAMP:20260501T205726
CREATED:20251212T224247Z
LAST-MODIFIED:20260310T220031Z
UID:7891-1773228600-1773232200@www.quantumx.washington.edu
SUMMARY:Chemistry Seminar: Jay Foley
DESCRIPTION:Event interval: Single day eventCampus location: Chemistry Building (CHB)Campus room: CHB 102Accessibility Contact: chem59x@uw.eduEvent Types: Academics\,Lectures/SeminarsLink: https://chemistry.charlotte.edu/directory/jay-foley-phd \n"Looking out for the tiniest lights: controlling chemistry and quantum states by confining light to small volumes" \nPolariton chemistry exploits the strong interaction between quantized excitations in molecules and quantized photon states in optical cavities to affect chemical reactivity.  Molecular polaritons have been experimentally realized by the coupling of electronic\, vibrational\, and rovibrational transitions to photon modes\, which has spurred tremendous theoretical effort to model and explain how polariton formation can influence chemistry.  I will present recent work in my group aimed at making the accurate computational modeling of molecular polaritons routine.  In particular\, I will describe a class of approaches called ab initio cavity quantum electrodynamics that treat molecular electronic degrees of freedom and photon degrees of freedom on equal quantum mechanical footing\, and can provide atomistic detail into the structure and reactivity of molecules under strong light-matter coupling. I will discuss applications of those techniques to modeling chemistry under electronic strong coupling\, and in using cavity-molecule interactions to generate entanglement. I will also highlight some pedagogical developments that we have developed to introduce students to computational molecular science tools within the context of strong light-matter coupling. \nAssociate Professor Jay Foley – Department of Chemistry\, University of North Carolina CharlotteHost: Niri Govind
URL:https://www.quantumx.washington.edu/calendar/chemistry-seminar-jay-foley/
LOCATION:Chemistry Building (CHB)
CATEGORIES:Chemistry
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260312T123000
DTEND;TZID=America/Los_Angeles:20260312T133000
DTSTAMP:20260501T205726
CREATED:20260202T185845Z
LAST-MODIFIED:20260202T185917Z
UID:8766-1773318600-1773322200@www.quantumx.washington.edu
SUMMARY:T Serkan Kasirga (Bilkent University): Optoelectronics and phase transitions of atomically thin materials via proximity engineering nbsp
DESCRIPTION:Speaker: T Serkan Kasirga\, Bilkent University\nUnlike three-dimensional materials\, screening of the interaction across quasiparticles in atomically thin materials can significantly alter their electronic and phononic properties. Earlier studies have demonstrated that dielectric screening can modify material parameters\, including electronic mobility\, conductivity\, Raman modes\, Seebeck coefficient\, and photoluminescence\, in semiconducting two-dimensional (2D) materials. In this talk\, I will discuss our efforts on finding novel two-dimensional materials with phase transitions via interlayer space modification and how screening modification via substrate engineering can be used in conjunction with scanning photocurrent microscopy to investigate the fundamental properties of 2D materials\, such as photoresponse mechanisms. Moreover\, I will illustrate how metals can be used to achieve screening\, despite the odds\, at the ultimate proximity to control the excitonic light emission from semiconducting 2D materials. Ultimately\, I will attempt to demonstrate how screening effects can be leveraged to enhance various electronic and optical properties of two-dimensional materials.
URL:https://www.quantumx.washington.edu/calendar/t-serkan-kasirga-bilkent-university-optoelectronics-and-phase-transitions-of-atomically-thin-materials-via-proximity-engineering-nbsp/
LOCATION:PAT C520
CATEGORIES:Physics
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260313T133000
DTEND;TZID=America/Los_Angeles:20260313T143000
DTSTAMP:20260501T205726
CREATED:20251230T225900Z
LAST-MODIFIED:20260407T183017Z
UID:8281-1773408600-1773412200@www.quantumx.washington.edu
SUMMARY:Bo Peng (Pacific Northwest National Laboratory)\, QISE Seminar: When Quantum Systems Remember: Fractional Open-System Dynamics via Random Time
DESCRIPTION:Abstract: Real quantum systems are never perfectly isolated: coupling to an environment causes relaxation and decoherence. The standard “memoryless” (Markovian) description—Lindblad dynamics—often predicts simple exponential decay. Yet in many physical settings\, environmental correlations persist\, producing memory effects and non-exponential relaxation. The key question is not whether history matters\, but how memory decays in time. In this talk\, I will introduce a fractional-calculus framework that organizes unitary dynamics\, Markovian master equations\, and long-memory non-Markovian behavior within a single hierarchy. The central idea is “selective memory”: long-time behavior is often governed by a small subset of slowly decaying correlations rather than the full microscopic history. Technically\, fractional dynamics can be understood as standard Lindblad evolution running under a randomized clock (Bochner–Phillips subordination)\, which preserves physical consistency (complete positivity) while generating algebraic long-time tails. I will illustrate how memory alters the shape of relaxation—not just the decay rate—using simple qubit examples and published benchmarks\, and I will briefly discuss how the same structure would enable scalable simulation without explicit time-history storage. \n\n\n\nBio: Bo Peng is a computational scientist at Pacific Northwest National Laboratory (PNNL) in the Physical and Computational Sciences Directorate. His research operates at the intersection of many-body electronic structure theory\, Green’s-function approaches to spectroscopy and excited states\, quantum algorithms for chemistry and materials\, and advanced computing/HPC for large-scale simulation. He develops both theoretical frameworks and production-quality computational tools\, with contributions ranging from coupled-cluster/downfolding ideas to open quantum dynamics models that incorporate environmental memory. More broadly\, his work aims to connect accurate microscopic theory with scalable computation and emerging quantum hardware\, enabling predictive simulations of complex molecular and condensed-phase systems. He is also dedicated to mentoring and collaborates widely across national laboratories and academia.
URL:https://www.quantumx.washington.edu/calendar/bo-peng-pacific-northwest-national-laboratory/
LOCATION:Electrical and Computer Engineering (ECE)\, Room 037\, 185 W Stevens Wy NE\, Seattke\, Washington\, 98185
CATEGORIES:Computer Science & Engineering
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260316T160000
DTEND;TZID=America/Los_Angeles:20260316T170000
DTSTAMP:20260501T205726
CREATED:20251212T233249Z
LAST-MODIFIED:20260316T223034Z
UID:7893-1773676800-1773680400@www.quantumx.washington.edu
SUMMARY:George H. Cady Endowed Lecture in Inorganic Chemistry: Hemamala Karunadasa
DESCRIPTION:Event interval: Single day eventAccessibility Contact: chem59x@uw.edu \nEvent Types: Academics\,Lectures/Seminars  \nEvent sponsors: The George H. Cady Endowed Lectureship in Chemistry was established in memory of Prof. Cady by his family and many friends and colleagues in 1994. George H. Cady earned his bachelor’s degree from the University of Kansas and Ph.D. from the University of California\, Berkeley\, in 1930 under the direction of Joel H. Hildebrand. Cady held positions at the University of South Dakota\, M.I.T.\, U.S. Rubber Company\, and Pittsburgh Plate Glass before joining the UW as assistant professor in 1938. He worked on the Manhattan Project (1942-43)\, chaired the Department of Chemistry (1961-65)\, and became professor emeritus in 1972. Prof. Cady was a distinguished inorganic chemist who\, among many honors\, shared the first Prix Moisson\, a prestigious prize named after the father of fluorine chemistry. \nLink: https://chemistry.stanford.edu/people/hemamala-karunadasa   \nGeorge H. Cady Endowed Lecture in Inorganic Chemistry“TBD”Professor Hemamala Karunadasa – Department of Chemistry\, Stanford University \nHost: Douglas Reed
URL:https://www.quantumx.washington.edu/calendar/george-h-cady-endowed-lecture-in-inorganic-chemistry-hemamala-karunadasa/
LOCATION:Johnson Hall (JHN)
CATEGORIES:Chemistry
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260317T153000
DTEND;TZID=America/Los_Angeles:20260317T163000
DTSTAMP:20260501T205726
CREATED:20251211T214549Z
LAST-MODIFIED:20260317T223029Z
UID:7894-1773761400-1773765000@www.quantumx.washington.edu
SUMMARY:Chemistry Seminar: Hemamala Karunadasa
DESCRIPTION:Event interval: Single day eventCampus location: Bagley Hall (BAG)Campus room: BAG 260Accessibility Contact: chem59x@uw.eduEvent Types: Academics\,Lectures/SeminarsLink: https://chemistry.stanford.edu/people/hemamala-karunadasa"TBD"Professor Hemamala Karunadasa – Department of Chemistry\, Stanford UniversityHost: Douglas Reed
URL:https://www.quantumx.washington.edu/calendar/inorganic-chemistry-seminar-hemamala-karunadasa/
LOCATION:Bagley Hall (BAG)
CATEGORIES:Chemistry
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260330T143000
DTEND;TZID=America/Los_Angeles:20260330T153000
DTSTAMP:20260501T205726
CREATED:20251209T190836Z
LAST-MODIFIED:20260330T221530Z
UID:7728-1774881000-1774884600@www.quantumx.washington.edu
SUMMARY:MSE Seminar: Yun Hang Hu
DESCRIPTION:Event interval: Single day eventAccessibility Contact: Matthew Yankowitz\, myank@uw.eduEvent Types: Lectures/SeminarsTitle: TBDAbstract: TBDBio: TBD
URL:https://www.quantumx.washington.edu/calendar/mse-seminar-yun-hang-hu/
CATEGORIES:Materials Science & Engineering
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/Los_Angeles:20260330T153000
DTEND;TZID=America/Los_Angeles:20260330T163000
DTSTAMP:20260501T205726
CREATED:20251212T224635Z
LAST-MODIFIED:20260330T221531Z
UID:7895-1774884600-1774888200@www.quantumx.washington.edu
SUMMARY:Chemistry Seminar: Wei Min
DESCRIPTION:Event interval: Single day eventCampus location: Bagley Hall (BAG)Campus room: BAG 260Accessibility Contact: chem59x@uw.eduEvent Types: Academics\,Lectures/SeminarsLink: https://www.chem.columbia.edu/content/wei-min \n"Lighting up chemical bonds for biomedicine"Professor Wei Min – Department of Chemistry\, Columbia UniversityHosts: Daniel Chiu\, Joshua Vaughan\, Dan Fu\, Bo Zhang \nInnovations in imaging have revolutionized life science and medicine. Among various imaging modalities\, vibrational imaging has emerged as a major technology\, by visualizing the fundamental chemical bonds inside living cells and tissues with high sensitivity\, speed\, specificity and resolution. In this talk I will first introduce recent advances in theoretical understanding and technical innovations of vibrational imaging. In particular\, I will discuss stimulated Raman scattering (SRS) microscopy\, which can amplify the otherwise feeble Raman scattering signal by up to 100 million times. Then I will highlight new research areas and applications\, including (1) single-molecule chemical spectroscopy\, (2) single-particle nanomedicine and nanoplastics\, (3) super-resolution chemical nanoscopy\, (4) super-multiplexed imaging for brain mapping\, and (5) vibrational spatial omics.   \nWei Min received his B.S. from Peking University in 2003 and Ph.D. from Harvard University in 2008 studying single-molecule biophysics with Prof. Sunney Xie. After continuing his postdoctoral work in Xie group\, Dr. Min joined the faculty at Columbia University in 2010\, and was promoted to Full Professor there in 2017. Dr. Min's contribution has been recognized by a number of honors\, including Biophotonics Technology Innovator Award from SPIE (2023)\, Raman Award for the Most Innovative Technological Development (2022)\, Craver Award of Vibrational Spectroscopy (2022)\, Scientific Achievement Award from Royal Microscopical Society (2021)\, Pittsburgh Conference Achievement Award (2019)\, Analyst Emerging Investigator Lectureship (2018)\, Coblentz Award of Molecular Spectroscopy (2017)\, the ACS Early Career Award in Experimental Physical Chemistry (2017)\, Camille Dreyfus Teacher-Scholar Award (2015)\, Alfred P. Sloan Research Fellowship (2013)\, and NIH Director's New Innovator Award (2012).   \n 
URL:https://www.quantumx.washington.edu/calendar/chemistry-seminar-wei-min/
LOCATION:Bagley Hall (BAG)
CATEGORIES:Chemistry
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DTSTART;TZID=America/Los_Angeles:20260331T133000
DTEND;TZID=America/Los_Angeles:20260331T143000
DTSTAMP:20260501T205726
CREATED:20260325T220352Z
LAST-MODIFIED:20260325T220754Z
UID:9963-1774963800-1774967400@www.quantumx.washington.edu
SUMMARY:Alioscia Hamma (University of Naples Federico II): Why is Magic Important (in Holography)
DESCRIPTION:In recent years\, the notion of magic in quantum physics – originally confined to more esoteric quantum information processing subfields – has attracted the attention of the community of quantum many-body physics\, quantum chaos and complexity\, high-energy physics\, AdS-CFT and the foundations of quantum mechanics. In this talk\, I will show why and how quantum magic matters to holography\, how it describes gravitational back-reaction\, and set up a program of entanglement-magic duality.
URL:https://www.quantumx.washington.edu/calendar/alioscia-hamma-university-of-naples-federico-ii-why-is-magic-important-in-holography/
LOCATION:PAB C421\, 3910 15th Ave NE\, Seattle\, WA\, 98195
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DTSTART;TZID=America/Los_Angeles:20260331T153000
DTEND;TZID=America/Los_Angeles:20260331T163000
DTSTAMP:20260501T205726
CREATED:20251212T233329Z
LAST-MODIFIED:20260331T223033Z
UID:7896-1774971000-1774974600@www.quantumx.washington.edu
SUMMARY:Chemistry Seminar: Wei Min
DESCRIPTION:Event interval: Single day eventAccessibility Contact: chem59x@uw.eduEvent Types: Academics\,Lectures/SeminarsLink: https://www.chem.columbia.edu/content/wei-min"TBD"Professor Wei Min – Department of Chemistry\, Columbia UniversityHosts: Daniel Chiu\, Joshua Vaughan\, Dan Fu\, Bo Zhang
URL:https://www.quantumx.washington.edu/calendar/chemistry-seminar-wei-min-2/
LOCATION:Bagley Hall (BAG)
CATEGORIES:Chemistry
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