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Past Events
- "Combining nuclear theory and neutron star observations to determine the properties of dense matter” (Andrew Steiner, University of Tennessee, Knoxville) -
- "Probing Neutron Star Interiors with Gravitational Waves" (Nicolas Yunes & Katerina Chatziioannou, Montana State University) -
- "The uncertainty quantifications in covariant density functional theory" (Anatoli Afanasjev, Mississippi State University) -
- "Constraining Neutron Star Properties from Laboratory Experiments" (Jorge Piekarewicz, Florida State University) -
- "Nuclear charge and neutron radii and nuclear matter: correlation analysis in Skyrme-DFT” (Witold Nazarewicz, Michigan State University) -
- "Connecting nuclear masses to the mysterious origins of the heavy elements" (Rebecca Surman, University of Notre Dame) -
- "Error plots, Bayesian methods, and model selection in EFT" (Natalie Klco & Daniel Phillips, University of Washington & Ohio University) -
- "Uncertainty quantification in ab initio nuclear theory” (Andreas Ekström, Chalmers University of Technology) -
- "Bayesian statistics applied to complex models of physical systems" (Ian Vernon, Durham University) -
- "Improving the accuracy and computational efficiency of BNS waveform models for measuring the neutron star equation of state" (Ben Lackey, Syracuse University) -
- "Application of Bayesian Methods to Finding Jets in Heavy Ion Collisions, and potential applications in Nuclear Security" (Ron Soltz, Lawrence Livermore National Laboratory) -
- "Propagating Nuclear Uncertainties from Databases to Applications" (Michael Buchoff, Lawrence Livermore National Laboratory) -
- "The Roles of Nuclear Physics and the Maximum Mass in Constraining the Neutron Star Radius" (James Lattimer, Stony Brook University) -
- "How well do we understand Beryllium-7 + proton -> Boron-8 + photon? A Bayesian Analysis Based on Effective Field Theory" (Xilin Zhang, University of Washington) -
- "Predictive ab initio many-body theory" (Kyle Wendt, Technische Universität Darmstadt) -
- "Transforming Heavy-Ion Physics into a Quantitative Science" (Scott Pratt, Michigan State University) -
- "The Essence of the Bayesian Paradigm" (Nozer Singpurwalla, City University of Hong Kong) -
- "Bayes this! Identifying and quantifying theoretical uncertainties." (Doron Gazit, Hebrew University of Jerusalem) -
- "Bayesian parameter estimation for effective field theories" (Sarah Wesolowski, Ohio State University) -
- "Bayesian constraint curve fitting for lattice QCD" (Chia Cheng Chang, Lawrence Berkeley National Laboratory) -
- "Bayes’ Rule and Laplace’s Big Data" (Sharon Bertsch McGrayne, Book Author) -
- "Statistical analysis of Nucleon-Nucleon interactions" (Rodrigo Navarro Perez, Lawrence Livermore National Laboratory) -
- "Fitting nonlocal energy density functionals for low-energy nuclear structure" (Karim Bennaceur, Université Claude Bernard) -
- "Optimisation of the shell-model Hamiltonian for heavy nuclei and the underlying uncertainty" (Chong Qi, KTH Stockholm) -
- "A poor man's attempt at fancy fitting of noisy lattice QCD data with exponentially degrading signal-to-noise ratios" (André Walker-Loud, Lawrence Berkeley National Laboratory) -
- Constraining the input parameters of a transport+hydrodynamics model of heavy ion collisions in RHIC beam energy scan range with the help of Gaussian emulators (Jussi Auvinen, Duke University) -
- An Example of Bayesian Model Calibration (Earl Lawrence, Los Alamos National Laboratory) -
- Sloppy nuclear energy density functionals: model reduction by manifold boundaries (Dario Vretenar, Universiy of Zagreb) -
- A Pedestrian's Perspective of Applying Bayesian Statistics in Effective Field Theories (Harald W. Griesshammer, George Washington University) -
- Extraction of quark-gluon-plasma properties via a model to data analysis of relativistic heavy-ion collisions (Jonah Bernhard/Steffen Bass, Duke University) -
- Baryon Spectroscopy: Data Consistency and Model Discrimination (David Ireland, University of Glasgow) -
- Going beyond generalized least squares algorithms for estimating nuclear data observables (Denise Neudecker, Los Alamos National Laboratory) -
- Sloppiness of nuclear structure models (Bartłomiej Szpak, IFJ PAN Krakow) -
- The Bayesian Unified Monte Carlo Method for Evaluating and Utilizing Nuclear Reaction Data (Donald Smith, formerly Argonne National Laboratory) -
- An introduction to Bayesian statistics and model calibration (Derek Bingham, Simon Fraser University) -
- "Basis light-front approach to nuclear physics" (Xingbo Zhao, Institute of Modern Physics, Chinese Academy of Sciences) -
- "Quantum Monte Carlo calculations with Delta-full and Pion-less effective field theory local potentials" (Alessandro Lovato, Argonne National Laboratory) -
- "The shell model as an ab initio tool" (Ragnar Stroberg, TRIUMF) -
- "Continuum states in the shell model" (Andrey Shirokov, Moscow State University) -
- "Description of the scattering process using complex-scaling method" (Rimantas Lazauskas, IPHC) -
- "NCSM with a Core: Deriving the Shell Model Microscopically" (Bruce R. Barrett, University of Arizona) -
- "Ab initio nuclear theory's symbiosis with relativistic quantum field theory" (James Vary, Iowa State University) -
- "Sensitivities and Correlations from chiral NN+3N Interactions in ab initio Nuclear Structure and Reaction Calculations" (Angelo Calci, TRIUMF) -
- "Nuclear Reactions in Lattice EFT" (Gautam Rupak, Mississippi State University) -
- "Strongly interacting nucleons: from few to many" (Alexandros Gezerlis, University of Guelph) -
- "Magnetic properties of light nuclei from lattice QCD" (Brian Tiburzi, City College of New York) -
- "Towards an understanding of clustering in nuclei" (Ulf Meißner, HISKP) -
- "From EFTs to nuclei" (Thomas Papenbrock, University of Tennessee) -
- "Nuclear physics from QCD: new questions and future directions" (Martin Savage, Institute for Nuclear Theory) -
- "Medium-mass isotopes from chiral and lattice QCD interactions" (Carlo Barbieri, University of Surrey) -