Observation of many-body Fock space dynamics in two dimensions

Yao, Yunyan; Xiang, Liang; Guo, Zexian; Bao, Zehang; Yang, Yue; Song, Zixuan; Shi, Haohai; Zhu, Xuhao; Jin, Feitong; Chen, Jiachen; Xu, Shibo; Zhu, Zitian; Shen, Fan-Hao; Wang, Ning; Zhang, Chuanyu; Wu, Yunxiang; Zou, Yiren; Zhang, Pengfei; Li, Hekang; Wang, Zhen; Song, Cunxian; Cheng, Chen; Mondaini, Rubem; Wang, H.; You, J. Q.; Zhu, Shi‐Yao; Ying, Lei; Guo, Qiujiang

doi:10.1038/s41567-023-02133-0

Cited by 11 publications

(4 citation statements)

References 68 publications

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“…Its non-integrability renders quick thermalization and the absence of memory of the initial conditions throughout sufficiently long dynamics 36 . Therefore, the prospects of achieving a successful QST are slim: One expects diffusive behavior in Fock space 37 , making it unlikely to find a single state with the majority of the weight in at a later time. Yet, suppose the number of excitations is small compared to the total system size.…”

Section: Resultsmentioning

confidence: 99%

Enhanced quantum state transfer by circumventing quantum chaotic behavior

Xiang,

Chen,

Zhu

et al. 2024

Nat Commun

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The ability to realize high-fidelity quantum communication is one of the many facets required to build generic quantum computing devices. In addition to quantum processing, sensing, and storage, transferring the resulting quantum states demands a careful design that finds no parallel in classical communication. Existing experimental demonstrations of quantum information transfer in solid-state quantum systems are largely confined to small chains with few qubits, often relying upon non-generic schemes. Here, by using a superconducting quantum circuit featuring thirty-six tunable qubits, accompanied by general optimization procedures deeply rooted in overcoming quantum chaotic behavior, we demonstrate a scalable protocol for transferring few-particle quantum states in a two-dimensional quantum network. These include single-qubit excitation, two-qubit entangled states, and two excitations for which many-body effects are present. Our approach, combined with the quantum circuit’s versatility, paves the way to short-distance quantum communication for connecting distributed quantum processors or registers, even if hampered by inherent imperfections in actual quantum devices.

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Section: Resultsmentioning

confidence: 99%

Enhanced quantum state transfer by circumventing quantum chaotic behavior

Xiang,

Chen,

Zhu

et al. 2024

Nat Commun

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“…The latter entanglement structures have recently been identified ( 13 , 14 ) in a class of systems known as quantum many-body scars (QMBS) ( 15 – 17 ). When QMBS systems are prepared in special initial states, their dynamics become trapped in a subspace that does not mix with the thermalizing bulk of the spectrum, leading to the coherent time evolution of local observables ( 18 – 23 ). The observation of QMBS has triggered a flurry of theoretical efforts to understand and classify the general mechanisms of weak ergodicity breaking in isolated quantum systems ( 24 – 33 ).…”

Section: Introductionmentioning

confidence: 99%

Disorder-tunable entanglement at infinite temperature

Dong,

Desaules,

Gao

et al. 2023

Sci. Adv.

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Emerging quantum technologies hold the promise of unravelling difficult problems ranging from condensed matter to high-energy physics while, at the same time, motivating the search for unprecedented phenomena in their setting. Here, we use a custom-built superconducting qubit ladder to realize non-thermalizing states with rich entanglement structures in the middle of the energy spectrum. Despite effectively forming an “infinite” temperature ensemble, these states robustly encode quantum information far from equilibrium, as we demonstrate by measuring the fidelity and entanglement entropy in the quench dynamics of the ladder. Our approach harnesses the recently proposed type of non-ergodic behavior known as “rainbow scar,” which allows us to obtain analytically exact eigenfunctions whose ergodicity-breaking properties can be conveniently controlled by randomizing the couplings of the model without affecting their energy. The on-demand tunability of quantum correlations via disorder allows for in situ control over ergodicity breaking, and it provides a knob for designing exotic many-body states that defy thermalization.

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“…Recent proposals extend such an implementation to study the quench dynamics of spin-orbit coupled systems and topological physics. [25,26] Recent theoretical and experimental works have extended quantum walks to higher-dimensions, [27] which is beneficial to investigations of special phenomena in non-Hermitian systems, such as the non-Hermitian skin effect (NHSE) in higher dimensions, [28][29][30][31] many-body Fock states with two dimensions, [32] and in the generation of GKP states. [33] In particular, directional matter transport has been experimentally demonstrated in a twodimensional (2D) quantum walk of photons, [34] which underlies the emergence of NHSE and has potential applications in topological transport and device design.…”

mentioning

confidence: 99%

Experimental Proposal on Non-Hermitian Skin Effect by Two-dimensional Quantum Walk with a Single Trapped Ion

Hou 侯,

Tang 唐,

Xu 许

et al. 2024

Chinese Phys. Lett.

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Non-Hermitian Hamiltonians are widely used in describing open systems with gain and loss, among which a key phenomenon is the non-Hermitian skin effect. Here we report an experimental scheme to realize a two-dimensional (2D) discrete-time quantum walk with non-Hermitian skin effect in a single trapped ion. We show the coin and 2D walker states can be labeled in the spin of the ion and the coherent-state lattice of the ion motion, respectively. We numerically observe a directional bulk flow, whose orientations are controlled by dissipative parameters, showing the emergence of the non-Hermitian skin effect. We then discuss an experimental implementation of our scheme in a lasercontrolled trapped Ca+ ion. Our experimental proposal may be applicable to studies of dissipative quantum walk systems, and may be able to generalize to other platforms such as superconducting circuits and atoms in cavity.

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Observation of many-body Fock space dynamics in two dimensions

Cited by 11 publications

References 68 publications

Enhanced quantum state transfer by circumventing quantum chaotic behavior

Enhanced quantum state transfer by circumventing quantum chaotic behavior

Disorder-tunable entanglement at infinite temperature

Experimental Proposal on Non-Hermitian Skin Effect by Two-dimensional Quantum Walk with a Single Trapped Ion

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