InQubator for Quantum Simulation (IQuS)
InQubator for Quantum Simulation (IQuS)
Past Events
- Approaching the Continuum Limit of Gauge Theories on Quantum Computers (Marc Illa, InQubator for Quantum Simulation, University of Washington) -
- Quantum simulation of far-from-equilibrium dynamics of gauge theories (Jad C. Halimeh, Max Planck Institute of Quantum Optics and LMU Munich) -
- Evidence for particle production in simulations of scattering on a quantum computer (Nikita Zemlevskiy, InQubator for Quantum Simulation, University of Washington) -
- Superconducting Circuits for Noise-Resilient Qubits (Max Hays, Massachusetts Insitute of Technology) -
- Programmable adiabatic demagnetization for systems with trivial and topological excitations (Mark Rudner, University of Washington) -
- TBA (Lewis Anderson, IBM UK) -
- Error-corrected fermionic quantum processors with neutral atoms (Robert Ott, IQOQI & University of Innsbruck) -
- Quantum diagonalization methods for lattice models and chemistry beyond the reach of exact solutions (Antonio Mezzacapo, IBM) -
- Fast scrambling as an uncertainty relation (Amit Vikram, University of Colorado Boulder) -
- Lindblad engineering for Gibbs state preparation under ETH (Yuta Kikuchi, Quantinuum) -
- What can the high-energy physics and QIS communities learn from each other? (Daniel Bowring, Fermilab) -
- TBA (Lena Funcke, University of Bonn) -
- 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) -
- Loop-string-hadron approach to SU(3) lattice Yang-Mills theory: Gauge invariant Hilbert space of a trivalent vertex (Jesse Stryker, Lawrence Berkeley National Laboratory) -
- 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) -
- Entanglement, Chaos and Thermalization (Niklas Mueller (IQuS)) -
- Quantum Computing for the Simplest Nuclear Physics Problem (Ionel Stetcu (Los Alamos National Lab.)) -
- Real-time scattering in Ising Field Theory (Ash Milsted (AWS Center for Quantum Computing, Pasadena)) -
- Entanglement of Astrophysical Neutrinos (Baha Balantekin (Univ. of Wisconsin, Madison)) -
- Magic Spreading in Many-Body Systems (Emmanuele Tirrito (Univ. of Trento)) -
- An Experimental(ist’s) View of Vacuum Entanglement (Douglas Beck (Univ. of Illinois, Urbana-Champaign)) -
- Quantum Phase Transitions: A Qutrit Perspective and Novel Order Parameter Discovery (Enrique Rico Ortega (Ikerbasque @ UPVH/EHU, Spain)) -
- Complexity, Entanglement, and Stabilizer Entropy (Alioscia Hamma (Univ. of Napoli and INFN, Italy)) -
- Tensor Network States and the Simulation of Out-of-Equilibrium Many-Body Dynamics (Mari Carmen Banuls (Max Planck Institute for Quantum Optics, Munich)) -
- Entanglement and Quantum Simulation of Nuclear Many-Body Systems (Denis Lacroix (Paris-Saclay Univ - IJCLab, France) and Thomas Papenbrock (Univ. of Tennessee and Oak Ridge National Lab.)) -
- Entropy Inspired Entanglement Forging in Quantum Many-Body Problems (Axel Perez-Obiol (Uinv. Autonoma de Barcelona, Spain)) -
- Dynamical Manifestations of Many-body Quantum Chaos and the Benefits of Opening the System (Lea Santos (Univ. of Connecticut)) -
- Variational Quantum Algorithms for Quantum Sensing (Raphael Kaubruegger (JILA, Colorado Univ. , Boulder)) -
- Multi-scale Entanglement Renormalization Methods for Classical and Quantum Computers (Thomas Barthel (Duke Univ.)) -
- Synthetic Gauge Fields in Trapped-Ion Crystals: From Background Peierls Phases to Z2 Gauge Theories (Alejandro Bermudez (Instituto de Fisica, Teorica, CSIC-UAM, Madrid Spain)) -
- Ab initio Advances for Open-shell and Heavy Nuclei (Achim Schwenk (TU Darmstadt)) -
- Quantum Simulation with Ultracold Atoms – From Static Gauge Fields to Gauge Theories (Monika Aidelsburger (Max Planck Institute for Quantum Optics, Munich)) -
- Recent Advances in Tensor Network State Methods via AI Accelerators and Global Mode Optimization (Ors Legeza (Wigner Research Center for Physics, Hungary)) -
- Entanglement: a possible source of information on nuclear structure? (Wolfgang Mittig (Michigan State Univ. and FRIB) and Yassid Ayyad (Univ. de Snatiago de Compostela)) -
- Fathoming Many-body Entanglement: Lessons from Space-like Detectors in Quantum Field Vacuums (Natalie Klco (Duke Univ.)) -
- Accuracy Guarantees and Quantum Advantage for Analog Quantum Simulators (Rahul Trivedi (Max Planck Institute for Quantum Optics, Munich)) -
- Long Range Entanglement using Dynamic Circuits (Ed Chen (IBM-Quantum, San Jose)) -
- Entanglement in Many-Body Systems: From Nuclei to Quantum Computers and Back (InQubator for Quantum Simulation workshop) - , , , , , , , , , , ,
- Key Aspects of (Modern) Nuclear Many-Body Theory (Heiko Hergert (Michigan State Univ.)) -
- 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) -