Your search keyword '"Wang, Yong-Yi"' showing total 12 results

1. Characterizing dynamical criticality of many-body localization transitions from the Fock-space perspective

Author

Sun, Zheng-Hang, Wang, Yong-Yi, Cui, Jian, Fan, Heng, and Heyl, Markus

Subjects

Quantum Physics, Condensed Matter - Disordered Systems and Neural Networks

Abstract

Characterizing the nature of many-body localization transitions (MBLTs) and their potential critical behaviors has remained a challenging problem. In this work, we study the dynamics of the displacement, quantifying the spread of the radial probability distribution in the Fock space, for systems with MBLTs, and perform a finite-size scaling analysis. We find that the scaling exponents satisfy theoretical bounds, and can identify universality classes. We show that reliable extrapolations to the thermodynamic limit for the MBLT induced by quasiperiodic fields is possible even for computationally accessible system sizes. Our work highlights that the displacement is a valuable tool for studying MBLTs, as relevant to ongoing experimental efforts.

Published

2024

2. Exploring Hilbert-Space Fragmentation on a Superconducting Processor

Author

Wang, Yong-Yi, Shi, Yun-Hao, Sun, Zheng-Hang, Chen, Chi-Tong, Wang, Zheng-An, Zhao, Kui, Liu, Hao-Tian, Ma, Wei-Guo, Wang, Ziting, Li, Hao, Zhang, Jia-Chi, Liu, Yu, Deng, Cheng-Lin, Li, Tian-Ming, He, Yang, Liu, Zheng-He, Peng, Zhen-Yu, Song, Xiaohui, Xue, Guangming, Yu, Haifeng, Huang, Kaixuan, Xiang, Zhongcheng, Zheng, Dongning, Xu, Kai, and Fan, Heng

Subjects

Quantum Physics, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics

Abstract

Isolated interacting quantum systems generally thermalize, yet there are several counterexamples for the breakdown of ergodicity, such as many-body localization and quantum scars. Recently, ergodicity breaking has been observed in systems subjected to linear potentials, termed Stark many-body localization. This phenomenon is closely associated with Hilbert-space fragmentation, characterized by a strong dependence of dynamics on initial conditions. Here, we experimentally explore initial-state dependent dynamics using a ladder-type superconducting processor with up to 24 qubits, which enables precise control of the qubit frequency and initial state preparation. In systems with linear potentials, we observe distinct non-equilibrium dynamics for initial states with the same quantum numbers and energy, but with varying domain wall numbers. This distinction becomes increasingly pronounced as the system size grows, in contrast with disordered interacting systems. Our results provide convincing experimental evidence of the fragmentation in Stark systems, enriching our understanding of the weak breakdown of ergodicity., Comment: main text: 7 pages, 4 figures; supplementary: 13 pages, 14 figures

Published

2024

3. High-order topological pumping on a superconducting quantum processor

Author

Deng, Cheng-Lin, Liu, Yu, Zhang, Yu-Ran, Li, Xue-Gang, Liu, Tao, Chen, Chi-Tong, Liu, Tong, Lu, Cong-Wei, Wang, Yong-Yi, Li, Tian-Ming, Fang, Cai-Ping, Zhou, Si-Yun, Song, Jia-Cheng, Xu, Yue-Shan, He, Yang, Liu, Zheng-He, Huang, Kai-Xuan, Xiang, Zhong-Cheng, Wang, Jie-Ci, Zheng, Dong-Ning, Xue, Guang-Ming, Xu, Kai, Yu, H. F., and Fan, Heng

Subjects

Quantum Physics

Abstract

High-order topological phases of matter refer to the systems of $n$-dimensional bulk with the topology of $m$-th order, exhibiting $(n-m)$-dimensional boundary modes and can be characterized by topological pumping. Here, we experimentally demonstrate two types of second-order topological pumps, forming four 0-dimensional corner localized states on a 4$\times$4 square lattice array of 16 superconducting qubits. The initial ground state of the system for half-filling, as a product of four identical entangled 4-qubit states, is prepared using an adiabatic scheme. During the pumping procedure, we adiabatically modulate the superlattice Bose-Hubbard Hamiltonian by precisely controlling both the hopping strengths and on-site potentials. At the half pumping period, the system evolves to a corner-localized state in a quadrupole configuration. The robustness of the second-order topological pump is also investigated by introducing different on-site disorder. Our work studies the topological properties of high-order topological phases from the dynamical transport picture using superconducting qubits, which would inspire further research on high-order topological phases.

Published

2024

4. Disorder-induced topological pumping on a superconducting quantum processor

Author

Liu, Yu, Zhang, Yu-Ran, Shi, Yun-Hao, Liu, Tao, Lu, Congwei, Wang, Yong-Yi, Li, Hao, Li, Tian-Ming, Deng, Cheng-Lin, Zhou, Si-Yun, Liu, Tong, Zhang, Jia-Chi, Liang, Gui-Han, Mei, Zheng-Yang, Ma, Wei-Guo, Liu, Hao-Tian, Liu, Zheng-He, Chen, Chi-Tong, Huang, Kaixuan, Song, Xiaohui, Zhao, SP, Tian, Ye, Xiang, Zhongcheng, Zheng, Dongning, Nori, Franco, Xu, Kai, and Fan, Heng

Subjects

Quantum Physics

Abstract

Thouless pumping, a dynamical version of the integer quantum Hall effect, represents the quantized charge pumped during an adiabatic cyclic evolution. Here we report experimental observations of nontrivial topological pumping that is induced by disorder even during a topologically trivial pumping trajectory. With a 41-qubit superconducting quantum processor, we develop a Floquet engineering technique to realize cycles of adiabatic pumping by simultaneously varying the on-site potentials and the hopping couplings. We demonstrate Thouless pumping in the presence of disorder and show its breakdown as the strength of disorder increases. Moreover, we observe two types of topological pumping that are induced by on-site potential disorder and hopping disorder, respectively. Especially, an intrinsic topological pump that is induced by quasi-periodic hopping disorder has never been experimentally realized before. Our highly controllable system provides a valuable quantum simulating platform for studying various aspects of topological physics in the presence of disorder.

Published

2024

5. Probing spin hydrodynamics on a superconducting quantum simulator

Author

Shi, Yun-Hao, Sun, Zheng-Hang, Wang, Yong-Yi, Wang, Zheng-An, Zhang, Yu-Ran, Ma, Wei-Guo, Liu, Hao-Tian, Zhao, Kui, Song, Jia-Cheng, Liang, Gui-Han, Mei, Zheng-Yang, Zhang, Jia-Chi, Li, Hao, Chen, Chi-Tong, Song, Xiaohui, Wang, Jieci, Xue, Guangming, Yu, Haifeng, Huang, Kaixuan, Xiang, Zhongcheng, Xu, Kai, Zheng, Dongning, and Fan, Heng

Subjects

Quantum Physics

Abstract

Characterizing the nature of hydrodynamical transport properties in quantum dynamics provides valuable insights into the fundamental understanding of exotic non-equilibrium phases of matter. Experimentally simulating infinite-temperature transport on large-scale complex quantum systems is of considerable interest. Here, using a controllable and coherent superconducting quantum simulator, we experimentally realize the analog quantum circuit, which can efficiently prepare the Haar-random states, and probe spin transport at infinite temperature. We observe diffusive spin transport during the unitary evolution of the ladder-type quantum simulator with ergodic dynamics. Moreover, we explore the transport properties of the systems subjected to strong disorder or a tilted potential, revealing signatures of anomalous subdiffusion in accompany with the breakdown of thermalization. Our work demonstrates a scalable method of probing infinite-temperature spin transport on analog quantum simulators, which paves the way to study other intriguing out-of-equilibrium phenomena from the perspective of transport., Comment: Main text: 13 pages, 5 figures; Supplementary: 17 pages, 16 figures, 1 table

Published

2023

6. Variational generation of spin squeezing on one-dimensional quantum devices with nearest-neighbor interactions

Author

Sun, Zheng-Hang, Wang, Yong-Yi, Zhang, Yu-Ran, Nori, Franco, and Fan, Heng

Subjects

Quantum Physics

Abstract

Efficient preparation of spin-squeezed states is important for quantum-enhanced metrology. Current protocols for generating strong spin squeezing rely on either high dimensionality or long-range interactions. A key challenge is how to generate considerable spin squeezing in one-dimensional systems with only nearest-neighbor interactions. Here, we develop variational spin-squeezing algorithms to solve this problem. We consider both digital and analog quantum circuits for these variational algorithms. After the closed optimization loop of the variational spin-squeezing algorithms, the generated squeezing can be comparable to the strongest squeezing created from two-axis twisting. By analyzing the experimental imperfections, the variational spin-squeezing algorithms proposed in this work are feasible in recent developed noisy intermediate-scale quantum computers.

Published

2023

7. Two-level approximation of transmons in quantum quench experiments

Author

Yan, H. S., Wang, Yong-Yi, Zhao, S. K., Yang, Z. H., Wang, Z. T., Xu, Kai, Tian, Ye, Yu, H. F., Fan, Heng, and Zhao, S. P.

Subjects

Quantum Physics

Abstract

Quantum quench is a typical protocol in the study of nonequilibrium dynamics of quantum many-body systems. Recently, a number of experiments with superconducting transmon qubits are reported, in which the spin and hard-core boson models with two energy levels on individual sites are used. The transmons are a multilevel system and the coupled qubits are governed by the Bose-Hubbard model. How well they can be approximated by a two-level system has been discussed and analysed in different ways for specific experiments in the literature. Here, we numerically investigate the accuracy and validity of the two-level approximation for the multilevel transmons based on the concept of Loschmidt echo. Using this method, we are able to calculate the fidelity decay (i.e., the time-dependent overlap of evolving wave functions) due to the state leakage to transmon high energy levels. We present the results for different system Hamiltonians with various initial states, qubit coupling strength, and external driving, and for two kinds of quantum quench experiments with time reversal and time evolution in one direction. We show quantitatively the extent to which the fidelity decays with time for changing coupling strength (or on-site interaction over coupling strength) and filled particle number or locations in the initial states under specific system Hamiltonians, which may serve as a way for assessing the two-level approximation of transmons. Finally, we compare our results with the reported experiments using transmon qubits.

Published

2023

8. Quantum simulation of topological zero modes on a 41-qubit superconducting processor

Author

Shi, Yun-Hao, Liu, Yu, Zhang, Yu-Ran, Xiang, Zhongcheng, Huang, Kaixuan, Liu, Tao, Wang, Yong-Yi, Zhang, Jia-Chi, Deng, Cheng-Lin, Liang, Gui-Han, Mei, Zheng-Yang, Li, Hao, Li, Tian-Ming, Ma, Wei-Guo, Liu, Hao-Tian, Chen, Chi-Tong, Liu, Tong, Tian, Ye, Song, Xiaohui, Zhao, S. P., Xu, Kai, Zheng, Dongning, Nori, Franco, and Fan, Heng

Subjects

Quantum Physics

Abstract

Quantum simulation of different exotic topological phases of quantum matter on a noisy intermediate-scale quantum (NISQ) processor is attracting growing interest. Here, we develop a one-dimensional 43-qubit superconducting quantum processor, named as Chuang-tzu, to simulate and characterize emergent topological states. By engineering diagonal Aubry-Andr$\acute{\mathrm{e}}$-Harper (AAH) models, we experimentally demonstrate the Hofstadter butterfly energy spectrum. Using Floquet engineering, we verify the existence of the topological zero modes in the commensurate off-diagonal AAH models, which have never been experimentally realized before. Remarkably, the qubit number over 40 in our quantum processor is large enough to capture the substantial topological features of a quantum system from its complex band structure, including Dirac points, the energy gap's closing, the difference between even and odd number of sites, and the distinction between edge and bulk states. Our results establish a versatile hybrid quantum simulation approach to exploring quantum topological systems in the NISQ era., Comment: Main text: 6 pages, 4 figures; Supplementary: 16 pages, 14 figures

Published

2022

9. Observation of critical phase transition in a generalized Aubry-Andr\'e-Harper model on a superconducting quantum processor with tunable couplers

Author

Li, Hao, Wang, Yong-Yi, Shi, Yun-Hao, Huang, Kaixuan, Song, Xiaohui, Liang, Gui-Han, Mei, Zheng-Yang, Zhou, Bozhen, Zhang, He, Zhang, Jia-Chi, Chen, Shu, Zhao, Shiping, Tian, Ye, Yang, Zhan-Ying, Xiang, Zhongcheng, Xu, Kai, Zheng, Dongning, and Fan, Heng

Subjects

Quantum Physics

Abstract

Quantum simulation enables study of many-body systems in non-equilibrium by mapping to a controllable quantum system, providing a new tool for computational intractable problems. Here, using a programmable quantum processor with a chain of 10 superconducting qubits interacted through tunable couplers, we simulate the one-dimensional generalized Aubry-Andr\'e-Harper model for three different phases, i.e., extended, localized and critical phases. The properties of phase transitions and many-body dynamics are studied in the presence of quasi-periodic modulations for both off-diagonal hopping coefficients and on-site potentials of the model controlled respectively by adjusting strength of couplings and qubit frequencies. We observe the spin transport for initial single- and multi-excitation states in different phases, and characterize phase transitions by experimentally measuring dynamics of participation entropies. Our experimental results demonstrate that the newly developed tunable coupling architecture of superconducting processor extends greatly the simulation realms for a wide variety of Hamiltonians, and may trigger further investigations on various quantum and topological phenomena., Comment: 12 pages, 4 figures, with Supplementary Materials

Published

2022

10. Improving the performance of quantum approximate optimization for preparing non-trivial quantum states without translational symmetry

Author

Sun, Zheng-Hang, Wang, Yong-Yi, Cui, Jian, and Fan, Heng

Subjects

Quantum Physics, Condensed Matter - Disordered Systems and Neural Networks

Abstract

The variational preparation of complex quantum states using the quantum approximate optimization algorithm (QAOA) is of fundamental interest, and becomes a promising application of quantum computers. Here, we systematically study the performance of QAOA for preparing ground states of target Hamiltonians near the critical points of their quantum phase transitions, and generating Greenberger-Horne-Zeilinger (GHZ) states. We reveal that the performance of QAOA is related to the translational invariance of the target Hamiltonian: Without the translational symmetry, for instance due to the open boundary condition (OBC) or randomness in the system, the QAOA becomes less efficient. We then propose a generalized QAOA assisted by the parameterized resource Hamiltonian (PRH-QAOA), to achieve a better performance. In addition, based on the PRH-QAOA, we design a low-depth quantum circuit beyond one-dimensional geometry, to generate GHZ states with perfect fidelity. The experimental realization of the proposed scheme for generating GHZ states on Rydberg-dressed atoms is discussed. Our work paves the way for performing QAOA on programmable quantum processors without translational symmetry, especially for recently developed two-dimensional quantum processors with OBC., Comment: 21 pages, 15 figures

Published

2022

11. Quantum simulation of Hawking radiation and curved spacetime with a superconducting on-chip black hole

Author

Shi, Yun-Hao, Yang, Run-Qiu, Xiang, Zhongcheng, Ge, Zi-Yong, Li, Hao, Wang, Yong-Yi, Huang, Kaixuan, Tian, Ye, Song, Xiaohui, Zheng, Dongning, Xu, Kai, Cai, Rong-Gen, and Fan, Heng

Subjects

Quantum Physics, General Relativity and Quantum Cosmology

Abstract

Hawking radiation is one of the quantum features of a black hole that can be understood as a quantum tunneling across the event horizon of the black hole, but it is quite difficult to directly observe the Hawking radiation of an astrophysical black hole. Here, we report a fermionic lattice-model-type realization of an analogue black hole by using a chain of 10 superconducting transmon qubits with interactions mediated by 9 transmon-type tunable couplers. The quantum walks of quasi-particle in the curved spacetime reflect the gravitational effect near the black hole, resulting in the behaviour of stimulated Hawking radiation, which is verified by the state tomography measurement of all 7 qubits outside the horizon. In addition, the dynamics of entanglement in the curved spacetime is directly measured. Our results would stimulate more interests to explore the related features of black holes using the programmable superconducting processor with tunable couplers., Comment: 25 pages, 19 figures

Published

2021

12. Stark many-body localization transitions in superconducting circuits

Author

Wang, Yong-Yi, Sun, Zheng-Hang, and Fan, Heng

Subjects

Quantum Physics, Condensed Matter - Disordered Systems and Neural Networks

Abstract

Recent numerical and experimental works have revealed a disorder-free many-body localization (MBL) in an interacting system subjecting to a linear potential, known as the Stark MBL. The conventional MBL, induced by disorder, has been widely studied by using quantum simulations based on superconducting circuits. Here, we consider the Stark MBL in two types of superconducting circuits, i.e., the 1D array of superconducting qubits, and the circuit where non-local interactions between qubits are mediated by a resonator bus. We calculate the entanglement entropy and participate entropy of the highly-excited eigenstates, and obtain the lower bound of the critical linear potential $\gamma_{c}$, using the finite-size scaling collapse. Moreover, we study the non-equilibrium properties of the Stark MBL. In particular, we observe an anomalous relaxation of the imbalance, dominated by the power-law decay $t^{-\xi}$. The exponent $\xi$ satisfies $\xi\propto|\gamma-\gamma_{c}|^{\nu}$ when $\gamma<\gamma_{c}$, and vanishes for $\gamma\geq \gamma_{c}$, which can be employed to estimate the $\gamma_{c}$. Our work indicates that superconducting circuits are a promising platform for investigating the critical properties of the Stark MBL transition., Comment: 9+7 pages, 10+7 figures, 2 tables

Published

2021