Below are highlights of the research conducted by members of the FQI over the last few years.
Performance of a Kinetic Inductance Phonon-Mediated Detector at the NEXUS Cryogenic Facility, arXiv:2402.04473 (2024)
Machine Learning for Arbitrary Single-Qubit Rotations on an Embedded Device, arXiv:2411.13037 (2024)
Confinement and Kink Entanglement Asymmetry on Quantum Ising Chain, arXiv:2312.08601 (2024). Quantum 8, 1462 (2024).
Optimal mass variables for semivisible jets, arXiv:2303.16253 (2023). SciPost Phys. Core 6, 067 (2023)
Quantum circuit fidelity estimation using machine learning, Quantum Mach. Intell. 6, 1 (2024). arXiv:2212.00677 (2024)
Fermion determinants on a quantum computer, arXiv:2407.13080 (2024)
Qumode transfer between continuous- and discrete-variable devices, PhysRevA.109.032419 (2024)
Noise-induced transition in optimal solutions of variational quantum algorithms, arXiv:2403.02762 (2024)
Simulating scalar field theories on quantum computers with limited resources, PhysRevA.107.032603 (2023)
Stimulated emission of signal photons from dark matter waves , arXiv:2305.03700 (2024)
Teleportation Systems Toward a Quantum Internet, PRXQuantum.1.020317, 2020
Toward Quantum Simulations of Z2 Gauge Theory Without State Preparation, arXiv:2011.11677, 2020
Large Scale Simulations of Quantum Systems on HPC with Analytics for HEP Algorithms, arXiv:2011.13143, 2020
SU(2) non-Abelian gauge field theory in one dimension on digital quantum computers, arXiv:1908.06935, 2019.
σ Models on Quantum Computers, Phys. Rev. Lett. 123.9, p. 090501, 2019.*#
Parton Physics on a Quantum Computer, arXiv:1908.10439, 2019. [hep-lat].*
General Methods for Digital Quantum Simulation of Gauge Theories, Phys. Rev. D100.3, p. 034518, 2019.*
Optimal Control for the Quantum Simulation of Nuclear Dynamics, arXiv:1908.08222, 2019.*
Simulations of Subatomic Many-Body Physics on a Quantum Frequency Processor, Phys. Rev. A 100 no.1, 012320, 2019.*
Digitizing Gauge Fields: Lattice Monte Carlo Results for Future Quantum Computers, Phys. Rev. A 99 no.6, 062341, 2019.†
Gluon Field Digitization for Quantum Computers, arXiv: 1906:11213, 2019.*
Putting the squeeze on axions, Physics Today 72, 6, 48, 2019.†‡#
Digitization of scalar fields for quantum computing, Phys. Rev. A 99, no.5, 052335, 2019.*
Protecting superconducting qubits from phonon mediated decay, Appl. Phys. Lett. 114(20), 202601, 2019.
Quantum Computing as a High School Module, arXiv:1905.00282, 2019.†
Oracles for Gauss’s law on digital quantum computers, Phys. Rev. A 99 no.4, 042301, 2019.*
Minimally-Entangled State Preparation of Localized Wavefunctions on Quantum Computers, arXiv:1904.10440, 2019.*
Entanglement Suppression and Emergent Symmetries of Strong Interactions, Phys. Rev. Lett. 122 no.10, 102001, 2019.*
Development of transmon qubits solely from optical lithography on 300 mm wafers, Quantum Science and Technology Vol. 4, Num. 2, 2019.
Continuous symmetries and approximate quantum error correction, arXiv:1902.07714, 2019.*#
Matter-wave Atomic Gradiometer Interferometric Sensor (MAGIS-100) at Fermilab, arXiv:1812.00482 , 2018.*#
Tailoring non-Abelian lattice gauge theory for quantum simulation, arXiv:1812.07554, 2018.*#
Simulating quantum field theory with a quantum computer, PoS LATTICE2018, 024, 2018. *#
Simulation of Nonequilibrium Dynamics on a Quantum Computer, Phys. Rev. Lett. 121 (17), p. 170501, 2018.*
Three-dimensional superconducting resonators at T < 20 mK with the photon lifetime up to τ = 2 seconds, arXiv:1810.03703, 2018.†
Digital quantum computation of fermion-boson interacting systems, Phys. Rev. A 98 no.4, 042312, 2018.†
Gauss’s Law, Duality, and the Hamiltonian Framework of Lattice Gauge Theory, PoS LATTICE2018, 227, 2018.*#
Quantum memory with millisecond coherence in circuit QED, Phys. Rev. B 94, 014506. 2016.#
Electron-Phonon Systems on a Universal Quantum Computer, Phys. Rev. Lett. 121, 110504, 2018.*
Quantum Sensing for High Energy Physics, arXiv:1803.11306, 2018.*#
Understanding Quality Factor Degradation in Superconducting Niobium Cavities at Low Microwave Field Amplitudes, Phys. Rev. Lett. 119, 264801, 2017.*
High-Kinetic Inductance Additive Manufactured Superconducting Microwave Cavity, Appl. Phys. Lett. 111(20), 2017.*
Breaking the 49-qubit barrier in the simulation of quantum circuits, arXiv: 1710:05867, 2017.*
Cavity State Manipulation Using Photon-Number Selective Phase Gates, Phys. Rev. Lett. 115, 137002, 2015.#
Single-photon Resolved Cross-Kerr Interaction for Autonomous Stabilization of Photon-number States, Phys. Rev. Lett. 115, 180501. 2015.#
Reaching 10 ms single photon lifetimes for superconducting aluminum cavities, Appl. Phys. Lett. 102(19). 2013.#
*This work is supported by the Department of Energy.
†This work is supported by the Department of Energy through the QuantISED for High Energy Physics program.
‡This work is supported by the Heising-Simons Foundation.
#This work is supported by the National Science Foundation.
§This work is supported by the Moore Foundation.