Seminars
Seminars
Upcoming Events
Christian Forssen - Chalmers University of Technology
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PAT C-421
Antoine Belley - Massachusetts Institute of Technology
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PAT C-421
Petr Navratil - TRIUMF
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PAT C-421
Past Events
- S@INT Seminar: "Tight Symmetry Energy Parameter Constraints from Neutron Skin Measurements" (James Lattimer - Stony Brook University) -
- Exploring Fundamental Physics with Galaxy Surveys (Mikhail Ivanov, Institute of Advanced Study ) -
- QIS in Physics: Quantum computations and simulations without error correction (Rahul Trivedi, University of Washington) -
- General Exam (Michael Clancy (Advisor: David Kaplan), University of Washington) -
- S@INT Seminar: "The Stability-Causality Theorem" (Lorenzo Gavassino - Vanderbilt University) -
- Precision Cosmology: from CMB to 21cm (Zhilei Xu, MIT) -
- The Quantum Scientific Computing Open User Testbed (QSCOUT): a "white-box" quantum computer for research (Susan Clark, Sandia National Labs) -
- Detectable dark photon dark matter (David Cyncynates, University of Washington) -
- QIS in Physics: Probing interactions in quantum materials and vibrating molecular strings (Arthur Barnard, University of Washington) -
- Isobar collisions with a 3D initial state (Chun Shen, Wayne State University) -
- Ab initio PGCM and applications to light nuclei (Jean-Paul Ebran, CEA) -
- Particle Tracking Reconstruction with the ExaTrkX Pipeline (Dr. Xiangyang Ju, Lawrence Berkeley National Lab) -
- Applicability of hydrodynamics in high-energy collisions (Dekrayat Almaalol, University of Illinois Urbana-Champaign) -
- S@INT Seminar: "Simulating jet quenching in detail" (Abhijit Majumder - Wayne State University) -
- Coupled cluster computations of radii and neutron skins (Gaute Hagen, Oak Ridge National Laboratory) -
- Light-ion collisions as a laboratory for effective theories of nuclei (Wilke van der Schee, CERN/Utrecht University) -
- Ab initio computations of deformed nuclei (Thomas Papenbrock, University of Tennessee) -
- Multi-particle correlations and nuclear structure (You Zhou, Niels Bohr Institute) -
- State-of-the-art nucleon-nucleon interactions (Maria Piarulli, Washington University of St. Louis) -
- Dense Nuclear Matter Equation of State from Heavy-Ion Collisions (Agnieszka Sorensen, Institute for Nuclear Theory) -
- Collective phenomena in small systems (Wei Li, Rice University) -
- Effective field theories of QCD for nuclei at low energy (Heiko Hergert, Michigan State University) -
- TBA (Annabelle Bohrdt, Harvard) -
- QIS in Physics: Unitarity, causality, and entanglement in a geometric theory of scattering (Silas Beane, University of Washington) -
- Probing nuclear symmetry energy (Bao-An Li, Texas A&M University-Commerce) -
- Neutron skin determinations via isobar collisions (HaoJie Xu, Huzhou University) -
- Nuclear structure input and CME (Guo-Liang Ma, Fudan University) -
- First Data from the FASER ecperiment at the LHC Run3 (Shih-Chieh Hsu, University of Washington) -
- Engineering atomic and solid-state quantum sensors for magnetometry and inertial sensing (Jennifer Choy, University of Wisconsin at Madison) -
- Impact of small-x evolution of nuclear deformations and application to isobar collisions (Pragya Singh, University of Jyvuäskylä) -
- Constraining parameters of initial condition in isobar collisions (Seyed Farid Taghavi, Technical University of Munich) -
- Relativistic energy-density functional (Jie Meng, Peking University) -
- Neutron skin sensitivity of weak probes in isobar collisions (Weiyao Ke, Los Alamos National Laboratory) -
- Deformation of A=96 isobars (Tomas Rodriguez, Universidad Complutense de Madrid) -
- The Future of Gravitational Wave Astronomy (Joey Key, UW Bothell) -
- Nuclear deformation and shape coexistence around 96Zr and 96Ru (Magda Zielińska, CEA Saclay) -
- Isobar collisions as precision nuclear structure probes (Jiangyong Jia, Stony Brook University) -
- Interplay of neutron skin and EOS (Pawel D. Danielewicz, Michigan State University) -
- Isobar run: Motivation and Outcome (Fuqiang Wang, Purdue University) -
- TBA (Matthew Luzum, University of São Paulo) -
- Nuclear deformations across the nuclide chart (Anatoli Afanasjev, Mississippi State University) -
- What can we learn with tau leptons at the LHC? (Quentin Buat, University of Washington) -
- Dense matter from nuclear reactions in astro- and heavy-ion physics (Shunji Nishimura, RIKEN) -
- Data-driven initial conditions for heavy-ion collisions (Govert Nijs, Massachusetts Institute of Technology) -
- Demonstration of algorithmic quantum speedup (Daniel Lidar, University of Southern California) -
- Bayesian analyses of heavy-ion collisions: status and prospects (Jean-Francois Paquet, Vanderbilt University) -
- State-of-the-art calculations for large nuclei (Benjamin Bally, CEA Paris-Saclay) -
- Overview of nuclear deformation in low-energy experiments (Kathrin Wimmer, GSI Helmholtz Centre for Heavy Ion Research) -
- Azimuthal anisotropy in heavy-ion collisions (Jean-Yves Ollitrault, Paris-Saclay University) -
- Nuclear deformation: origin and properties (Witold Nazarewicz, Michigan State University) -