Einloggen

Simulation of far-from-equilibrium quantum many-body dynamics - SimQuDyn

30. März 2026 bis 2. April 2026
Main LMU Physics Building
Europe/Berlin Zeitzone

Contact

Liste der Beiträge

33 von 33 angezeigt
  1. 2. Quantum Simulation and Quantum Computing with Ultracold Fermionic Atoms in Optical Lattices
    Immanuel Bloch
    30.03.26, 09:30
  2. 3. A route toward digital quantum magnetism
    Michael Knap
    30.03.26, 10:00
  3. 4. Spin-resolved microscopy of strontium SU(N) Fermi-Hubbard systems
    Leticia Tarruell
    30.03.26, 11:00
    Talk
  4. 5. Quantum and classical algorithms for many-body Gibbs states
    Dima Abanin
    30.03.26, 11:30
    Talk
  5. 6. Simulating particle collisions using quantum computers
    Roland Farrell
    30.03.26, 13:30
    Talk
  6. 7. Observation of hadron scattering in a lattice gauge theory on a quantum computer
    Julian Schuhmacher
    30.03.26, 14:00
  7. 8. Hybrid Analog-Digital Quantum Simulation with Ultracold Fermions
    Philipp Preiss
    30.03.26, 15:00
    Talk

    Understanding strongly correlated many-fermion systems remains one of the central open challenges in condensed matter physics. Quantum gas microscopes have enabled major advances in this direction by providing analog quantum simulators with single-site- and single-atom-resolved control and detection. However, compared to digital quantum information processors, analog platforms remain limited...

    Go to contribution page
  8. 9. Microscopic Dynamics of False Vacuum Decay in the 2+1D Quantum Ising Model
    Umberto Borla
    30.03.26, 15:30
    Talk

    False vacuum decay is a prominent phenomenon relevant to elementary particle physics and early-universe cosmology. Understanding its microscopic dynamics is currently a major challenge and research thrust. Recent advances in numerical techniques allow for the extraction of related signatures in tractable systems in two spatial dimensions over intermediate timescales. Here, we focus on the 2 +...

    Go to contribution page
  9. 10. Observation of constructive interference at the edge of quantum ergodicity
    Nikita Astrakhantsev
    30.03.26, 16:00
  10. 12. Studying doped magnet with a Rydberg quantum simulator
    Antoine Browaeys
    31.03.26, 09:30
    Talk
  11. 13. Preparing and probing quantum many-body states in Rydberg quantum simulators
    Hannes Pichler
    31.03.26, 10:00
    Talk
  12. 14. New tools for resource-efficient digital simulation with atom arrays
    Jake Covey
    31.03.26, 11:00

    Arrays of neutral atoms in optical tweezers are an excellent setting for simulating the dynamics of quantum matter. Programmable control over each atom and their interactions in the array offers new capabilities for compiling Hamiltonians that are not amenable to direct analog simulations with global control, and it offers the possibility to perform simulations at the logical level to obviate...

    Go to contribution page
  13. 15. State preparation and detection for quantum simulation of particle collisions
    Federica Surace
    31.03.26, 11:30
    Talk
  14. 16. Quantum computing with metastable atomic qubits
    Johannes Zeiher
    31.03.26, 13:30
    Talk
  15. 17. Superconducting Pairing Correlations on a 98-qubit Trapped-Ion Quantum Computer
    Henrik Dreyer
    31.03.26, 14:00
    Talk
  16. 18. What can AI agents do for quantum physics?
    Florian Marquardt
    31.03.26, 15:00
    Talk
  17. 19. On the role of quantum fluctuations in variational quantum optimization algorithms
    Dries Sels
    31.03.26, 15:30
  18. 20. Ultra-high resolution spectral functions using complex-time Krylov spaces
    Sebastian Paeckel
    31.03.26, 16:00
  19. 21. Quantum simulation with neutral atoms: from analog to digital
    Sasha Geim
    01.04.26, 09:30
    Talk
  20. 22. Emergent Gauge Theories and Universal Codes from Analog and Digital Quantum Dynamics
    Ruben Verresen
    01.04.26, 10:00
    Talk
  21. 23. An infinite hierarchy of multi-copy quantum learning advantages
    Richard Kueng
    01.04.26, 11:00
    Talk

    Learning properties of quantum states from measurement data is a fundamental challenge in quantum information. The sample complexity of such tasks depends crucially on the measurement primitive. While shadow tomography achieves sample-efficient learning by allowing entangling measurements across many copies, it requires prohibitively deep circuits. At the other extreme, two-copy measurements...

    Go to contribution page
  22. 24. Probing Complex Quantum Dynamics with Pauli Path Spectroscopy
    Andreas Elben
    01.04.26, 11:30
    Talk
  23. 25. Open quantum many-body systems: thermalization and efficient mixing
    Álvaro Alhambra
    01.04.26, 15:30
    Talk
  24. 26. Many-body memories
    Ethan Lake
    01.04.26, 16:00
    Talk
  25. 27. Quenches across the Bose Glass transition
    Ulrich Schneider
    02.04.26, 09:30
    Talk
  26. 28. Fading ergodicity
    Lev Vidmar
    02.04.26, 10:00
    Talk
  27. 29. Creating and Exploring Bose-Einstein Condensates of Dipolar Molecules
    Sebastian Will
    02.04.26, 11:00
    Talk
  28. 30. Ergodicity breaking meets criticality in a gauge-theory quantum simulator
    Ana Hudomal
    02.04.26, 11:30
    Talk
  29. 31. Preparing injective PEPs with gapped parent Hamiltonians.
    Rahul Trivedi
    02.04.26, 13:30
    Talk

    Projected entangled pair states (PEPs) describe area law states that are believed to be ground states of gapped Hamiltonians in 2 and higher dimension. I will present a few results concerning a class of PEPs which additionally satisfy an injectivity condition - these PEPs can describe states that are not topologically ordered but are still ground states of gapped local Hamiltonians. First, I...

    Go to contribution page
  30. 32. Running Quantum Computers in Discovery Mode
    Benedikt Placke
    02.04.26, 14:00
    Talk

    We propose using quantum computers in conjunction with classical machine learning to discover instances of interesting quantum many-body dynamics. Concretely, an “interest function” is defined for a given circuit (family) instance that can be evaluated on a quantum computer. The circuit is then adapted by a classical learning agent to maximize interest. We illustrate this approach using two...

    Go to contribution page
  31. 33. Floquet superheating
    Hongzheng Zhao
    02.04.26, 15:00
    Talk
  32. 34. Non-ergodic dynamics in SU(2) lattice gauge theory: scars, fragmentation, and disorder-free localization
    Giovanni Cataldi
    02.04.26, 15:30
    Talk

    Non-Abelian lattice gauge theories provide a setting where local constraints reshape far-from-equilibrium quantum many-body dynamics and can obstruct thermalization.
    In a (1+1)D SU(2) lattice gauge theory with dynamical matter, three non-ergodic phenomena are identified, each with a different origin. In regimes where the gauge-invariant dynamics is otherwise ergodic, low-overhead...

    Go to contribution page
  33. 11. Poster Session