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Quantum Information Science on the Intersections of Nuclear and AMO Physics

Jan 13 – 15, 2025
America/New_York timezone

Session

Session 5

Jan 15, 2025, 8:30 AM

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  1. 30. Quasiparton and quasifragmentation functions in the massive Schwinger model (25+5)
    Sebastian Grieninger (Stony Brook University)
    1/15/25, 8:30 AM

    We analyze the quasiparton distributions of the lightest meson in massive QED2. For increasing rapidity, we compute the spatial quasiparton distribution functions and amplitude for the lowest excited state numerically both at strong and weak coupling and compare them to light front results in the lowest Fock space approximation. Moreover, we introduce the concept of the quark...

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  2. 20. Quantum sensing assisted by near-term quantum algorithms (25+5)
    Akira Sone (University of Massachusetts Boston)
    1/15/25, 9:00 AM

    In this presentation, we explore near-term quantum algorithms designed to prepare optimal quantum states for applications in quantum sensing and metrology. These algorithms can be tailored for implementation on noisy intermediate-scale quantum (NISQ) devices. Specifically, we examine the variational quantum algorithms to estimate the quantum Fisher information for this task and highlight their...

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  3. 46. Enhancing Quantum Utility: simulating large-scale quantum spin chains on superconducting quantum computers (25+5)
    Kwangmin Yu (Brookhaven National Laboratory)
    1/15/25, 9:30 AM

    We present the quantum simulation of the frustrated quantum spin-1/2 antiferromagnetic Heisenberg spin chain with competing nearest-neighbor (𝐽1) and next-nearest-neighbor (𝐽2) exchange interactions in the real superconducting quantum computer with qubits ranging up to 100. In particular, we implement the Hamiltonian with the next-nearest neighbor exchange interaction in conjunction with the...

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  4. 37. Detection of nuclear decays with levitated mechanical quantum sensors (40+10)
    David Moore (Yale University)
    1/15/25, 10:30 AM

    The development of optomechanical systems—in which the motion of a massive object is controlled and measured using light—has revolutionized the detection of tiny forces over the past few decades. As such technologies reach, and even surpass, quantum measurement limits, they can enable the detection of tiny forces relevant in nuclear physics. I will present results from a recent...

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  5. 31. A lattice field theory of quantum circuits (25+5)
    Neill Warrington (MIT Center for Theoretical Physics)
    1/15/25, 11:20 AM
  6. 29. Quantum Sensor Networks (25+5)
    Alexey Gorshkov (University of Maryland and NIST)
    1/15/25, 11:50 AM

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