Hekang Li scite author profile

We report on deterministic generation of 18-qubit genuinely entangled Greenberger-Horne-Zeilinger (GHZ) state and multi-component atomic Schrödinger cat states of up to 20 qubits on a quantum processor, which features 20 superconducting qubits interconnected by a bus resonator. By engineering a one-axis twisting Hamiltonian enabled by the resonator-mediated interactions, the system of qubits initialized coherently evolves to an over-squeezed, non-Gaussian regime, where atomic Schrödinger cat states, i.e., superpositions of atomic coherent states including GHZ state, appear at specific time intervals in excellent agreement with theory. With high controllability, we are able to take snapshots of the dynamics by plotting quasidistribution Q-functions of the 20qubit atomic cat states, and globally characterize the 18-qubit GHZ state which yields a fidelity of 0.525 ± 0.005 confirming genuine eighteen-partite entanglement. Our results demonstrate the largest entanglement controllably created so far in solid state architectures, and the process of generating and detecting multipartite entanglement may promise applications in practical quantum metrology, quantum information processing and quantum computation.

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Observation of energy-resolved many-body localization

Guo

et al. 2020

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Probing dynamical phase transitions with a superconducting quantum simulator

et al. 2020

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Nonequilibrium quantum many-body systems, which are difficult to study via classical computation, have attracted wide interest. Quantum simulation can provide insights into these problems. Here, using a programmable quantum simulator with 16 all-to-all connected superconducting qubits, we investigate the dynamical phase transition in the Lipkin-Meshkov-Glick model with a quenched transverse field. Clear signatures of dynamical phase transitions, merging different concepts of dynamical criticality, are observed by measuring the nonequilibrium order parameter, nonlocal correlations, and the Loschmidt echo. Moreover, near the dynamical critical point, we obtain a spin squeezing of −7.0 ± 0.8 dB, showing multipartite entanglement, useful for measurements with precision fivefold beyond the standard quantum limit. On the basis of the capability of entangling qubits simultaneously and the accurate single-shot readout of multiqubit states, this superconducting quantum simulator can be used to study other problems in nonequilibrium quantum many-body systems, such as thermalization, many-body localization, and emergent phenomena in periodically driven systems.

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Observation of a Dynamical Quantum Phase Transition by a Superconducting Qubit Simulation

et al. 2019

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A dynamical quantum phase transition can occur during time evolution of sudden quenched quantum systems across a phase transition. It corresponds to the nonanalytic behavior at a critical time of the rate function of the quantum state return amplitude, analogous to nonanalyticity of the free energy density at the critical temperature in macroscopic systems. A variety of many-body systems can be represented in momentum space as a spin-1/2 state evolving on the Bloch sphere, where each momentum mode is decoupled and thus can be simulated independently by a single qubit. Here, we report the observation of a dynamical quantum phase transition in a superconducting qubit simulation of the quantum quench dynamics of many-body systems. We take the Ising model with a transverse field as an example for demonstration. In our experiment, the spin state, which is initially polarized longitudinally, evolves based on a Hamiltonian with adjustable parameters depending on the momentum and strength of the transverse magnetic field. The time evolving quantum state is read out by state tomography. Evidence of dynamical quantum phase transitions, such as paths of time evolution states on the Bloch sphere, non-analytic behavior of the dynamical free energy and the emergence of Skyrmion lattice in momentum-time space, is observed. The experimental data agrees well with theoretical and numerical calculations. The experiment demonstrates for the first time explicitly the topological invariant, both topologically trivial and non-trivial, for dynamical quantum phase transitions. Our results show that the quantum phase transitions of this class of many-body systems can be simulated successfully with a single qubit by varying certain control parameters over the corresponding momentum range. * schen@iphy.ac.cn † dzheng@iphy.ac.cn ‡ hfan@iphy.ac.cn curring at critical temperature. The DQPT is intimately related to quantum phase transitions in many-body systems [20][21][22][24][25][26][27][28][29][30][31][32][33][34][35][36].Recently, experimental explorations of DQPT have been performed in ion-trap systems [3,5] and cold atom systems [4,6] with dozens of individual addressable qubits or a cloud of fermionic atoms. Our experiment follows the DQPT simulation approach by emulating a corresponding two-band model separately for each momentum mode with a single qubit. By ranging over the Brillouin zone of momentum space, the results are equivalent to that of simulating manybody systems in space. The finite size effect can be observed for a finite number of momenta implemented experimentally. Our experimental system consists of superconducting Xmon qubits, which is one of the most promising platforms for quantum simulation and quantum computation [37][38][39][40][41]. We provide concrete evidence that the DQPT is successfully simulated. In particular, we demonstrate experimentally the topological invariant in DQPT, which was studied recently in Refs. [24,33], and have obtained quantitatively the dynamical free energy and Skyrmion lattice.

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Hekang Li

Generation of multicomponent atomic Schrödinger cat states of up to 20 qubits

Observation of energy-resolved many-body localization

Probing dynamical phase transitions with a superconducting quantum simulator

Observation of a Dynamical Quantum Phase Transition by a Superconducting Qubit Simulation

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