Advanced search

Filter By:

Journal Check one or more journals to show results from those journals only.

Choose more journals

Article type Check one or more article types to show results from those article types only.
Subject Check one or more subjects to show results from those subjects only.
Date Choose a date option to show results from those dates only.

Custom date range

Clear all filters
Sort by:
Showing 1–10 of 10 results
Advanced filters: Author: Nishad Maskara Clear advanced filters

  • Detection of topological phases in experiments is challenging, especially in the presence of incoherent noise. Cong et al. introduce a novel method combining error correction and renormalization-group flow and apply it to characterization of quantum spin liquid phases realized in a Rydberg-atom simulator.

    • Iris Cong
    • Nishad Maskara
    • Mikhail D. Lukin
    ResearchOpen Access
    Nature Communications
    Volume: 15, P: 1-14

  • Reconfigurable arrays of up to 448 neutral atoms are used to implement and combine the key elements of a universal, fault-tolerant quantum processing architecture and experimentally explore their underlying working mechanisms.

    • Dolev Bluvstein
    • Alexandra A. Geim
    • Mikhail D. Lukin
    ResearchOpen Access
    Nature
    Volume: 649, P: 39-46

  • Logical operations can be performed fault-tolerantly with only a constant number of syndrome extraction rounds for a broad class of quantum error correction codes, including the surface code with magic state inputs and feedforward, to achieve ‘transversal algorithmic fault tolerance’.

    • Hengyun Zhou
    • Chen Zhao
    • Mikhail D. Lukin
    Research
    Nature
    Volume: 646, P: 303-308

  • Digital quantum simulations of Kitaev’s honeycomb model are realized for two-dimensional fermionic systems using a reconfigurable atom-array processor and used to study the Fermi–Hubbard model on a square lattice.

    • Simon J. Evered
    • Marcin Kalinowski
    • Mikhail D. Lukin
    ResearchOpen Access
    Nature
    Volume: 645, P: 341-347

  • A programmable quantum simulator based on Rydberg atom arrays is used to study the collective dynamics of a quantum phase transition and observe the phenomenon of quantum coarsening.

    • Tom Manovitz
    • Sophie H. Li
    • Mikhail D. Lukin
    ResearchOpen Access
    Nature
    Volume: 638, P: 86-92

  • Quantum simulations of chemistry and materials are challenging due to the complexity of correlated systems. A framework based on reconfigurable qubit architectures and digital–analogue simulations provides a hardware-efficient path forwards.

    • Nishad Maskara
    • Stefan Ostermann
    • Susanne F. Yelin
    ResearchOpen Access
    Nature Physics
    Volume: 21, P: 289-297

  • A programmable quantum processor based on encoded logical qubits operating with up to 280 physical qubits is described, in which improvement of algorithmic performance using a variety of error-correction codes is enabled.

    • Dolev Bluvstein
    • Simon J. Evered
    • Mikhail D. Lukin
    ResearchOpen Access
    Nature
    Volume: 626, P: 58-65

  • The realization of two-qubit entangling gates with 99.5% fidelity on up to 60 rubidium atoms in parallel is reported, surpassing the surface-code threshold for error correction and laying the groundwork for neutral-atom quantum computers.

    • Simon J. Evered
    • Dolev Bluvstein
    • Mikhail D. Lukin
    ResearchOpen Access
    Nature
    Volume: 622, P: 268-272

  • A quantum processer is realized using arrays of neutral atoms that are transported in a parallel manner by optical tweezers during computations, and used for quantum error correction and simulations.

    • Dolev Bluvstein
    • Harry Levine
    • Mikhail D. Lukin
    ResearchOpen Access
    Nature
    Volume: 604, P: 451-456