Talks
Talks
Past Events
- TBA (Lena Funcke, University of Bonn) -
- Echoes from ECOs - probing the dark sector with gravitational waves at atom interferometers (Hannah Banks (Dehmelt Fellow Candidate), Cambridge) -
- Thermodynamic computing for AI applications (Patrick Coles, Chief Scientist at Normal Computing) -
- Universal Euler-Cartan Circuits for Quantum Field Theories (Ananda Roy, Rutgers University) -
- Quantum simulation of materials in extreme conditions (Andrew Baczewski, Sandia National Lab) -
- Fault Tolerance with Dynamical Codes (Daniel Gottesmann, University of Maryland) -
- Surrogate Constructed Scalable Circuits ADAPT-VQE: A state preparation method for lattice field theories (Erik J. Gustafson, Research Institute for Advanced Computer Science, Mountain View) -
- Classical and Quantum Computing of Shear Viscosity for 2+1D SU(2) Gauge Theory (Xiaojun Yao) -
- What cannot be learned in the quantum universe? (Hsin-Yuan (Robert) Huang, Google Quantum AI and Caltech) -
- The Quantum Scientific Computing Open User Testbed (QSCOUT): Accelerating quantum computing improvements through project diversity (Susan Clark, Sandia National Lab) -
- Learning topological states using variational tensor network tomography (Yanting Teng, Harvard University) -
- Efficient Long-Range Entanglement using Dynamic Circuits (Elisa Bäumer, IBM) -
- Turning neutral atom systems into useful quantum computers (takes place in PAT C-423) (Ben Bloom, CTO & Founder Atom Computing) -
- Bath engineering magnetic order in quantum spin chains: An analytic approach (Dvira Segal, University of Toronto) -
- Emergent Holographic Forces from Quantum Circuits and Criticality (Jordan Cotler, Harvard University) -
- Additive quantities cannot be more than asymptotically continuous (Debbie Leung, University of Waterloo and Perimeter Institute) -
- Level-rank duality and 3d mirror symmetry (Niklas Garner, University of Washington) -
- Linear hydrodynamical stability and the laws of thermodynamics (Eric Mefford, University of Victoria) -
- Associativity is Enough (Natalie Paquette, University of Washington) -
- Randomness in conformal field theories (Moshe Rozali, UBC) -
- Emergence of space and time in holography (Hong Liu, MIT) -
- Efficient preparation of Tensor Network States (Note unusual time) (Ignacio Cirac, Max Planck Institute for Quantum Optics) -
- Evidence for the utility of quantum computing before fault tolerance (Abinhav Kandala, IBM Quantum) -
- Quantum Simulation and Computing with Long Ion Chains (Marko Cetina, Duke Quantum Center at Duke University) -
- Does provable absence of barren plateaus imply classical simulability? [note: unusual time] (Zoë Holmes, Swiss Federal Institute of Technology Lausanne) -
- Energy Transition (Dr. Kathryn Oseen-Senda) -
- Efficient separate quantification of state preparation errors and measurement errors on quantum computers and their mitigation [Attention room change, now in C423] (Tzu-Chieh Wei, C.N. Yang Institute, Stony Brook University) -
- From square plaquettes to triamond lattices for SU(2) gauge theory (Randy Lewis, York University) -
- Tapered Quantum Phase Estimation (room has changed! PAT C-421) (Andrew Sornborger, Los Alamos National Lab & Quantum Science Center -- Quantum Algorithms and Simulation Lead) -
- Simulating fermionic scattering using a digital quantum computing approach (Yahui Chai, DESY) -
- Variational quantum algorithm for quantum matter using Trotterized entanglement renormalization (Thomas Barthel, Duke University) -
- AI in Physics (Peter Morgan, CEO, Deep Learning Partnership) -
- Quantum many-body equilibration of fast neutrino flavor oscillations (Joshua Martin, Los Alamos National Lab) -
- Ultracold atoms as quantum simulators for neutron matter (Thomas Schaefer, North Carolina State University) -
- Crafting Generative Models & Unraveling High Energy Physics with Parameterized Quantum Circuits (Andrea Delgado, Oak Ridge National Lab) -
- IBM Qiskit Panel --Running Experiments on more than 100 Qubits (Roland Farell, IQuS) -
- A quantum simulation scheme and equilibration/thermalization physics of the Sachdev-Ye-Kitaev (SYK) model (Soumik Bandyopadhyay, University of Trento,) -
- Scalable Circuits for Preparing Ground States on Digital Quantum Computers: The Schwinger Model Vacuum on 100 Qubits (Marc Illa, IQuS) -
- Quantum scars and regular eigenstates in chaotic spinor condensates (Ceren Dag (Harvard)) -
- Speed Limits on the Propagation of Quantum Information (Alexey Gorshkov (UMD, NIST)) -
- TBA (Anatoli Polkovnikov (Boston University)) -
- Open quantum system dynamics within the Schwinger model (Felix Ringer (Old Dominion University)) -
- The scent of Eigenstate Thermalization in hadronic collisions at high multiplicity (Rob Pisarski (Brookhaven Nat'l Lab)) -
- Learning conservation laws in unknown quantum dynamics (Andreas Elben (Caltech)) -
- Quantum Simulation with Ultracold Atoms – From Hubbard Models to Gauge Theories (Monika Aidelsburger (MPI for Quantum Optics, LMU Munich)) -
- Real-time non-perturbative dynamics of jet production in Schwinger model: quantum entanglement and vacuum modification (Adrien Florio (Brookhaven Nat'l Lab)) -
- What can quantum thermodynamics do for you? (Nicole Yunger Halpern (UMD, NIST)) -
- Thermodynamics of oscillating neutrinos (Luke Johns (UC Berkeley)) -
- Perspectives from the Lattice (Alexei Bazavov (Michigan State)) -
- Prospects of correlated electron-photon systems for quantum simulation (Mohammad Hafezi (UMD, NIST)) -