Your search keyword '"Zhang, Yu-Ran"' showing total 194 results

1. Suppressed Energy Relaxation in the Quantum Rabi Model at the Critical Point

Author

Chen, Ye-Hong, Shi, Zhi-Cheng, Zhang, Yu-Ran, Nori, Franco, and Xia, Yan

Subjects

Quantum Physics

Abstract

We derive a modified master equation for the quantum Rabi model in the parameter regime where quantum criticality can occur. The modified master equation can avoid some unphysical predictions, such as excitations in the system at zero temperature and emission of ground-state photons. Due to spectrum collapse, we find that there is mostly no energy relaxation in the system at the critical point. For the same reason, phase coherence rapidly reduces and vanishes at the critical point. We analyze the quantum metrological limits of the system in the presence of dephasing. These results show a strong limitation on the precision of phase-shift estimation., Comment: 7 pages, two figures, comments are welcome

Published

2024

2. Noisy Probabilistic Error Cancellation and Generalized Physical Implementability

Author

Jin, Tian-Ren, Xu, Kai, Zhang, Yu-Ran, and Fan, Heng

Subjects

Quantum Physics

Abstract

Quantum decoherent noises have significantly influenced the performance of practical quantum processors. Probabilistic error cancellation quantum error mitigation method quasiprobabilistically simulates the noise inverse operations, which are not physical channels, to cancel the noises. Physical implementability is the minimal cost to simulate a non-physical quantum operation with physical channels by the quasiprobabilistic decomposition. However, in practical, this cancellation may also be influenced by noises, and the implementable channels are not all of the physical channels, so the physical implementability is not sufficient to completely depict the practical situation of the probabilistic error cancellation method. Therefore, we generalize the physical implementability to an arbitrary convex set of free quantum resources and discuss several of its properties. We demonstrate the way to optimally cancel the error channel with the noisy Pauli basis. In addition, we also discuss the several properties relevant to this generalization. We expect that its properties and structures will be investigated comprehensively, and it will have more applications in the field of quantum information processing.

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. Dynamics of quantum coherence in many-body localized systems

Author

Chen, Jin-Jun, Xu, Kai, Ren, Li-Hang, Zhang, Yu-Ran, and Fan, Heng

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We demonstrate that the dynamics of quantum coherence serves as an effective probe for identifying dephasing, which is a distinctive signature of many-body localization (MBL). Quantum coherence can be utilized to measure both the local coherence of specific subsystems and the total coherence of the whole system in a consistent manner. Our results reveal that the local coherence of small subsystems decays over time following a power law in the MBL phase, while it reaches a stable value within the same time window in the Anderson localized (AL) phase. In contrast, the total coherence of the whole system exhibits logarithmic growth during the MBL phase and reaches a stable value in the AL phase. Notably, this dynamic characteristic of quantum coherence remains robust even with weak interactions and displays unbounded behavior in infinite systems. Our results provide insights into understanding many-body dephasing phenomena in MBL systems and propose a novel feasible method for identifying and characterizing MBL phases in experiments.

Published

2024

5. 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

6. Recovery of damaged information via scrambling in indefinite casual order

Author

Jin, Tian-Ren, Li, Tian-Ming, Wang, Zheng-An, Xu, Kai, Zhang, Yu-Ran, and Fan, Heng

Subjects

Quantum Physics

Abstract

Scrambling prevents the access to local information with local operators and therefore can be used to protect quantum information from damage caused by local perturbations. Even though partial quantum information can be recovered if the type of the damage is known, the initial target state cannot be completely recovered, because the obtained state is a mixture of the initial state and a maximally mixed state. Here, we demonstrate an improved scheme to recover damaged quantum information via scrambling in indefinite causal order. We show that scheme with indefinite causal order can record information of the damage and distill the initial state from the damaged state simultaneously. It allows us to retrieve initial information versus any damage. Moreover, by iterating the schemes, the initial quantum state can be completely recovered. In addition, we experimentally demonstrate our schemes on the cloud-based quantum computer, named as Quafu. Our work proposes a feasible scheme to protect whole quantum information from damage, which is also compatible with other techniques such as quantum error corrections and entanglement purification protocols. We expect that our scheme will be useful in the both quantum information recovery from the damage and systems bench-marking.

Published

2023

7. Reentrant Non-Hermitian Skin Effect Induced by Correlated Disorder

Author

Jin, Wei-Wu, Liu, Jin, Wang, Xin, Zhang, Yu-Ran, Huang, Xueqin, Wei, Xiaomin, Ju, Wenbo, Liu, Tao, Yang, Zhongmin, and Nori, Franco

Subjects

Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The interplay of non-Hermiticity and disorder drastically influences the system's localization properties, giving rise to intriguing quantum phenomena. Although the intrinsic non-Hermitian skin effect (NHSE) is robust against weak disorder even in a one-dimensional system, it becomes Anderson localization under strong disorder. Here, we study an Anderson localization-delocalization transition by coupling a strongly disordered Hatano-Nelson (HN) chain to a disordered Hermitian chain with their disorders anti-symmetrically correlated with each other. Regardless of the disorder strength, as the inter-chain coupling strength increases, an Anderson delocalization can occur. This leads to a reentrant NHSE due to the interplay of nonreciprocal hopping and correlated disorder. Furthermore, the Anderson localization-delocalization transition is well captured by the real-space winding number. This reentrant NHSE, under anti-symmetric disorder, is a remarkably nontrivial physical phenomenon without a Hermitian counterpart. We then experimentally test this phenomenology by implementing our model in electrical circuits, and observe the reentrant NHSE by measuring the voltage response., Comment: 15 pages, 9 figures including both theoretical and experimental results. Comments are welcome

Published

2023

8. 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

9. 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

10. 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

Published

2024

11. Logarithmic light cone, slow entanglement growth, and quantum memory

Author

Zeng, Yu, Hamma, Alioscia, Zhang, Yu-Ran, Liu, Qiang, Li, Rengang, Fan, Heng, and Liu, Wu-Ming

Subjects

Quantum Physics

Abstract

Effective light cones, characterized by Lieb-Robinson bounds, emerge in non-relativistic local quantum systems. Here, we present several analytical results derived from logarithmic light cones (LLCs), which can arise in the one-dimensional XXZ model with random fields and in a phenomenological model of many-body localization (MBL). In the LLC regime, we prove that the entanglement growth is upper-bounded by logarithmic time with an additional subleading double-logarithmic term stemming from a real asymptotic solution of the \emph{Lambert W} function. In the context of the XXZ model, recent numerical results suggest that the double-logarithmic term correlates with number entropy. We also show that information scrambling is logarithmically slow in the LLC regime. Furthermore, we demonstrate that the LLC supports long-lived quantum memories under unitary time evolution as quantum codes with macroscopic code distance and an exponentially scaling lifetime. Our analytical results provide benchmarks for future numerical explorations of the MBL regime on large time scales., Comment: 7+3 pages, 2 figures. In version 3, the proof of Theorem 1 was refined and we demonstrated that the logarithmic light cone implies that entanglement grows at most logarithmically with time, with an additional double-logarithmic correction

Published

2023

12. Metrological detection of multipartite entanglement through dynamical symmetries

Author

Zhang, Yu-Ran and Nori, Franco

Subjects

Quantum Physics

Abstract

Multipartite entanglement, characterized by the quantum Fisher information (QFI), plays a central role in quantum-enhanced metrology and understanding quantum many-body physics. With a dynamical generalization of the Mazur-Suzuki relations, we provide a rigorous lower bound on the QFI for the thermal Gibbs states in terms of dynamical symmetries, i.e., operators with periodic time dependence. We demonstrate that this bound can be saturated when considering a complete set of dynamical symmetries. Moreover, this lower bound with dynamical symmetries can be generalized to the QFI matrix and to the QFI for the thermal pure states, predicted by the eigenstate thermalization hypothesis. Our results reveal a new perspective to detect multipartite entanglement and other generalized variances in an equilibrium system, from its nonstationary dynamical properties, and is promising for studying emergent nonequilibrium many-body physics., Comment: 6+4 pages, 2+0 figures

Published

2023

13. Nonmesonic Quantum Many-Body Scars in a 1D Lattice Gauge Theory

Author

Ge, Zi-Yong, Zhang, Yu-Ran, and Nori, Franco

Subjects

Condensed Matter - Strongly Correlated Electrons, Quantum Physics

Abstract

We investigate the meson excitations (particle-antiparticle bound states) in quantum many-body scars of a 1D $\mathbb{Z}_2$ lattice gauge theory coupled to a dynamical spin-$\frac{1}{2}$ chain as a matter field. By introducing a string representation of the physical Hilbert space, we express a scar state $\ket {\Psi_{n,l}}$ as a superposition of all string bases with an identical string number $n$ and a total length $l$. For the small-$l$ scar state $\ket {\Psi_{n,l}}$, the gauge-invariant spin exchange correlation function of the matter field hosts an exponential decay as the distance increases, indicating the existence of stable mesons. However, for large $l$, the correlation function exhibits a power-law decay, signaling the emergence of nonmesonic excitations. Furthermore, we show that this mesonic-nonmesonic crossover can be detected by the quench dynamics, starting from two low-entangled initial states, respectively, which are experimentally feasible in quantum simulators. Our results expand the physics of quantum many-body scars in lattice gauge theories and reveal that the nonmesonic state can also manifest ergodicity breaking., Comment: 7+2 pages, 4+1 figures

Published

2023

14. 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

15. Bounded light cone and robust topological order out of equilibrium

Author

Zeng, Yu, Hamma, Alioscia, Zhang, Yu-Ran, Cao, Jun-Peng, Fan, Heng, and Liu, Wu-Ming

Subjects

Quantum Physics

Abstract

The ground state degeneracy of topologically ordered gapped Hamiltonians is the bedrock for self-correcting quantum memories, which are unfortunately not stable away from equilibrium even at zero temperature. This plague precludes practical robust self-correction since stability at zero temperature is a prerequisite for finite-temperature robustness. In this work, we show that the emergence of a bounded light cone renders the unitary time evolution a quasi-adiabatic continuation that preserves topological order, with the initial ground space retaining its macroscopic distance at all times as a quantum code. We also show how bounded light cones can emerge through suitable perturbations in Kitaev's toric code and honeycomb model. Our results suggest that topological orders and self-correcting quantum memories can be dynamically robust at zero temperature., Comment: 7+5 pages, 4+3 figures. the Supplemental Material is updated. In version 4, we show the emergence of a bounded light cone in the disordered Kitaev's honeycomb model

Published

2022

16. Simulating Chern insulators on a superconducting quantum processor

Author

Xiang, Zhong-Cheng, Huang, Kaixuan, Zhang, Yu-Ran, Liu, Tao, Shi, Yun-Hao, Deng, Cheng-Lin, Liu, Tong, Li, Hao, Liang, Gui-Han, Mei, Zheng-Yang, Yu, Haifeng, Xue, Guangming, Tian, Ye, Song, Xiaohui, Liu, Zhi-Bo, Xu, Kai, Zheng, Dongning, Nori, Franco, and Fan, Heng

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The quantum Hall effect, fundamental in modern condensed matter physics, continuously inspires new theories and predicts emergent phases of matter. Here we experimentally demonstrate three types of Chern insulators with synthetic dimensions on a programable 30-qubit-ladder superconducting processor. We directly measure the band structures of the 2D Chern insulator along synthetic dimensions with various configurations of Aubry-Andr\'e-Harper chains and observe dynamical localisation of edge excitations. With these two signatures of topology, our experiments implement the bulk-edge correspondence in the synthetic 2D Chern insulator. Moreover, we simulate two different bilayer Chern insulators on the ladder-type superconducting processor. With the same and opposite periodically modulated on-site potentials for two coupled chains, we simulate topologically nontrivial edge states with zero Hall conductivity and a Chern insulator with higher Chern numbers, respectively. Our work shows the potential of using superconducting qubits for investigating different intriguing topological phases of quantum matter., Comment: main text: 18 pages, 9 figures; supplementary information: 25 pages, 26 figures

Published

2022

17. Observation of a superradiant phase transition with emergent cat states

Author

Zheng, Ri-Hua, Ning, Wen, Chen, Ye-Hong, Lü, Jia-Hao, Shen, Li-Tuo, Xu, Kai, Zhang, Yu-Ran, Xu, Da, Li, Hekang, Xia, Yan, Wu, Fan, Yang, Zhen-Biao, Miranowicz, Adam, Lambert, Neill, Zheng, Dongning, Fan, Heng, Nori, Franco, and Zheng, Shi-Biao

Subjects

Quantum Physics

Abstract

Superradiant phase transitions (SPTs) are important for understanding light-matter interactions at the quantum level, and play a central role in criticality-enhanced quantum sensing. So far, SPTs have been observed in driven-dissipative systems, but the emergent light fields did not show any nonclassical characteristic due to the presence of strong dissipation. Here we report an experimental demonstration of the SPT featuring the emergence of a highly nonclassical photonic field, realized with a resonator coupled to a superconducting qubit, implementing the quantum Rabi model. We fully characterize the light-matter state by Wigner matrix tomography. The measured matrix elements exhibit quantum interference intrinsic of a photonic mesoscopic superposition, and reveal light-matter entanglement, Comment: 20 pages, 19 figures, 2 tables

Published

2022

18. Multipartite entanglement of the topologically ordered state in a perturbed toric code

Author

Zhang, Yu-Ran, Zeng, Yu, Liu, Tao, Fan, Heng, You, J. Q., and Nori, Franco

Subjects

Quantum Physics

Abstract

We demonstrate that multipartite entanglement, witnessed by the quantum Fisher information (QFI), can characterize topological quantum phase transitions in the spin-$\frac{1}{2}$ toric code model on a square lattice with external fields. We show that the QFI density of the ground state can be written in terms of the expectation values of gauge-invariant Wilson loops for different sizes of square regions and identify $\mathbb{Z}_2$ topological order by its scaling behavior. Furthermore, we use this multipartite entanglement witness to investigate thermalization and disorder-assisted stabilization of topological order after a quantum quench. Moreover, with an upper bound of the QFI, we demonstrate the absence of finite-temperature topological order in the 2D toric code model in the thermodynamic limit. Our results provide insights to topological phases, which are robust against external disturbances, and are candidates for topologically protected quantum computation., Comment: 6+4 pages, 3+0 figures

Published

2021

19. Simulating Chern insulators on a superconducting quantum processor

Author

Xiang, Zhong-Cheng, Huang, Kaixuan, Zhang, Yu-Ran, Liu, Tao, Shi, Yun-Hao, Deng, Cheng-Lin, Liu, Tong, Li, Hao, Liang, Gui-Han, Mei, Zheng-Yang, Yu, Haifeng, Xue, Guangming, Tian, Ye, Song, Xiaohui, Liu, Zhi-Bo, Xu, Kai, Zheng, Dongning, Nori, Franco, and Fan, Heng

Published

2023

20. Deterministic one-way logic gates on a cloud quantum computer

Author

Yang, Zhi-Peng, Baishya, Alakesh, Ku, Huan-Yu, Zhang, Yu-Ran, Kockum, Anton Frisk, Chen, Yueh-Nan, Li, Fu-Li, Tsai, Jaw-Shen, and Nori, Franco

Subjects

Quantum Physics

Abstract

One-way quantum computing is a promising candidate for fault-tolerant quantum computing. Here, we propose new protocols to realize a deterministic one-way CNOT gate and one-way $X$-rotations on quantum-computing platforms. By applying a delayed-choice scheme, we overcome a limit of most currently available quantum computers, which are unable to implement further operations on measured qubits or operations conditioned on measurement results from other qubits. Moreover, we decrease the error rate of the one-way logic gates, compared to the original protocol using local operations and classical communication (LOCC). In addition, we apply our deterministic one-way CNOT gate in the Deutsch-Jozsa algorithm to show the feasibility of our proposal. We demonstrate all these one-way gates and algorithms by running experiments on the cloud quantum-computing platform IBM Quantum Experience.

Published

2021

21. Probing Operator Spreading via Floquet Engineering in a Superconducting Circuit

Author

Zhao, S. K., Ge, Zi-Yong, Xiang, Zhongcheng, Xue, G. M., Yan, H. S., Wang, Z. T., Wang, Zhan, Xu, H. K., Su, F. F., Yang, Z. H., Zhang, He, Zhang, Yu-Ran, Guo, Xue-Yi, Xu, Kai, Tian, Ye, Yu, H. F., Zheng, D. N., Fan, Heng, and Zhao, S. P.

Subjects

Quantum Physics

Abstract

Operator spreading, often characterized by out-of-time-order correlators (OTOCs), is one of the central concepts in quantum many-body physics. However, measuring OTOCs is experimentally challenging due to the requirement of reversing the time evolution of systems. Here we apply Floquet engineering to investigate operator spreading in a superconducting 10-qubit chain. Floquet engineering provides an effective way to tune the coupling strength between nearby qubits, which is used to demonstrate quantum walks with tunable couplings, reversed time evolution, and the measurement of OTOCs. A clear light-cone-like operator propagation is observed in the system with multiple excitations, and has a nearly equal velocity as the single-particle quantum walk. For the butterfly operator that is nonlocal (local) under the Jordan-Wigner transformation, the OTOCs show distinct behaviors with (without) a signature of information scrambling in the near integrable system., Comment: 6+12 pages, 4 figures

Published

2021

22. Metrological characterisation of non-Gaussian entangled states of superconducting qubits

Author

Xu, Kai, Zhang, Yu-Ran, Sun, Zheng-Hang, Li, Hekang, Song, Pengtao, Xiang, Zhongcheng, Huang, Kaixuan, Li, Hao, Shi, Yun-Hao, Chen, Chi-Tong, Song, Xiaohui, Zheng, Dongning, Nori, Franco, Wang, H., and Fan, Heng

Subjects

Quantum Physics

Abstract

Multipartite entangled states are significant resources for both quantum information processing and quantum metrology. In particular, non-Gaussian entangled states are predicted to achieve a higher sensitivity of precision measurements than Gaussian states. On the basis of metrological sensitivity, the conventional linear Ramsey squeezing parameter (RSP) efficiently characterises the Gaussian entangled atomic states but fails for much wider classes of highly sensitive non-Gaussian states. These complex non-Gaussian entangled states can be classified by the nonlinear squeezing parameter (NLSP), as a generalisation of the RSP with respect to nonlinear observables, and identified via the Fisher information. However, the NLSP has never been measured experimentally. Using a 19-qubit programmable superconducting processor, here we report the characterisation of multiparticle entangled states generated during its nonlinear dynamics. First, selecting 10 qubits, we measure the RSP and the NLSP by single-shot readouts of collective spin operators in several different directions. Then, by extracting the Fisher information of the time-evolved state of all 19 qubits, we observe a large metrological gain of 9.89$^{+0.28}_{-0.29}$ dB over the standard quantum limit, indicating a high level of multiparticle entanglement for quantum-enhanced phase sensitivity. Benefiting from high-fidelity full controls and addressable single-shot readouts, the superconducting processor with interconnected qubits provides an ideal platform for engineering and benchmarking non-Gaussian entangled states that are useful for quantum-enhanced metrology., Comment: 13+12 pages, 10+2 figures

Published

2021

23. Observation of strong and weak thermalization in a superconducting quantum processor

Author

Chen, Fusheng, Sun, Zheng-Hang, Gong, Ming, Zhu, Qingling, Zhang, Yu-Ran, Wu, Yulin, Ye, Yangsen, Zha, Chen, Li, Shaowei, Guo, Shaojun, Qian, Haoran, Huang, He-Liang, Yu, Jiale, Deng, Hui, Rong, Hao, Lin, Jin, Xu, Yu, Sun, Lihua, Guo, Cheng, Li, Na, Liang, Futian, Peng, Cheng-Zhi, Fan, Heng, Zhu, Xiaobo, and Pan, Jian-Wei

Subjects

Quantum Physics

Abstract

We experimentally study the ergodic dynamics of a 1D array of 12 superconducting qubits with a transverse field, and identify the regimes of strong and weak thermalization with different initial states. We observe convergence of the local observable to its thermal expectation value in the strong-thermalizaion regime. For weak thermalization, the dynamics of local observable exhibits an oscillation around the thermal value, which can only be attained by the time average. We also demonstrate that the entanglement entropy and concurrence can characterize the regimes of strong and weak thermalization. Our work provides an essential step towards a generic understanding of thermalization in quantum systems., Comment: 6+6 pages, 4+8 figures

Published

2021

24. Protecting topological order by dynamical localization

Author

Zeng, Yu, Hamma, Alioscia, Zhang, Yu-Ran, Cao, Jun-Peng, Fan, Heng, and Liu, Wu-Ming

Subjects

Quantum Physics, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Strongly Correlated Electrons

Abstract

As a prototype model of topological quantum memory, two-dimensional toric code is genuinely immune to generic local static perturbations, but fragile at finite temperature and also after non-equilibrium time evolution at zero temperature. We show that dynamical localization induced by disorder makes the time evolution a local unitary transformation at all times, which keeps topological order robust after a quantum quench. We verify this conclusion by investigating the Wilson loop expectation value and topological entanglement entropy. Our results suggest that the two dimensional topological quantum memory can be dynamically robust at zero temperature., Comment: 7+11 pages, 2+5 figures

Published

2021

25. Observation of thermalization and information scrambling in a superconducting quantum processor

Author

Zhu, Qingling, Sun, Zheng-Hang, Gong, Ming, Chen, Fusheng, Zhang, Yu-Ran, Wu, Yulin, Ye, Yangsen, Zha, Chen, Li, Shaowei, Guo, Shaojun, Qian, Haoran, Huang, He-Liang, Yu, Jiale, Deng, Hui, Rong, Hao, Lin, Jin, Xu, Yu, Sun, Lihua, Guo, Cheng, Li, Na, Liang, Futian, Peng, Cheng-Zhi, Fan, Heng, Zhu, Xiaobo, and Pan, Jian-Wei

Subjects

Quantum Physics

Abstract

Understanding various phenomena in non-equilibrium dynamics of closed quantum many-body systems, such as quantum thermalization, information scrambling, and nonergodic dynamics, is a crucial for modern physics. Using a ladder-type superconducting quantum processor, we perform analog quantum simulations of both the $XX$ ladder and one-dimensional (1D) $XX$ model. By measuring the dynamics of local observables, entanglement entropy and tripartite mutual information, we signal quantum thermalization and information scrambling in the $XX$ ladder. In contrast, we show that the $XX$ chain, as free fermions on a 1D lattice, fails to thermalize, and local information does not scramble in the integrable channel. Our experiments reveal ergodicity and scrambling in the controllable qubit ladder, and opens the door to further investigations on the thermodynamics and chaos in quantum many-body systems., Comment: 5 pages, 4 figures, and supplementary materials with 10 pages, 3 tables and 14 figures

Published

2021

26. Observation of Bloch Oscillations and Wannier-Stark Localization on a Superconducting Processor

Author

Guo, Xue-Yi, Ge, Zi-Yong, Li, Hekang, Wang, Zhan, Zhang, Yu-Ran, Song, Peangtao, Xiang, Zhongcheng, Song, Xiaohui, Jin, Yirong, Xu, Kai, Zheng, Dongning, and Fan, Heng

Subjects

Quantum Physics, Condensed Matter - Quantum Gases

Abstract

The Bloch oscillation (BO) and Wannier-Stark localization (WSL) are fundamental concepts about metal-insulator transitions in condensed matter physics. These phenomena have also been observed in semiconductor superlattices and simulated in platforms such as photonic waveguide arrays and cold atoms. Here, we report experimental investigation of BOs and WSL simulated with a 5-qubit programmable superconducting processor, of which the effective Hamiltonian is an isotropic $XY$ spin chain. When applying a linear potential to the system by properly tuning all individual qubits, we observe that the propagation of a single spin on the chain is suppressed. It tends to oscillate near the neighborhood of their initial positions, which demonstrates the characteristics of BOs and WSL. We verify that the WSL length is inversely correlated to the potential gradient. Benefiting from the precise single-shot simultaneous readout of all qubits in our experiments, we can also investigate the thermal transport, which requires the joint measurement of more than one qubits. The experimental results show that, as an essential characteristic for BOs and WSL, the thermal transport is also blocked under a linear potential. Our experiment would be scalable to more superconducting qubits for simulating various of out-of-equilibrium problems in quantum many-body systems., Comment: 8+12 pages, 4 figures

Published

2020

27. Quantifying quantum non-Markovianity based on quantum coherence via skew information

Author

Shao, Lian-He, Zhang, Yu-Ran, Luo, Yu, Xi, Zhengjun, and Fei, Shao-Ming

Subjects

Quantum Physics

Abstract

Based on the nonincreasing property of quantum coherence via skew information under incoherent completely positive and trace-preserving maps, we propose a non-Markovianity measure for open quantum processes. As applications, by applying the proposed measure to some typical noisy channels, we find that it is equivalent to the three previous measures of non-Markovianity for phase damping and amplitude damping channels, i.e., the measures based on the quantum trace distance, dynamical divisibility, and quantum mutual information. For the random unitary channel, it is equivalent to the non-Markovianity measure based on $l_1$ norm of coherence for a class of output states and it is incompletely equivalent to the measure based on dynamical divisibility. We also use the modified Tsallis relative $\alpha$ entropy of coherence to detect the non-Markovianity of dynamics of quantum open systems, the results show that the modified Tsallis relative $\alpha$ entropy of coherence are more comfortable than the original Tsallis relative $\alpha$ entropy of coherence for small $\alpha$., Comment: 13 pages, 5 figures

Published

2020

28. Probing the dynamical phase transition with a superconducting quantum simulator

Author

Xu, Kai, Sun, Zheng-Hang, Liu, Wuxin, Zhang, Yu-Ran, Li, Hekang, Dong, Hang, Ren, Wenhui, Zhang, Pengfei, Nori, Franco, Zheng, Dongning, Fan, Heng, and Wang, H.

Subjects

Quantum Physics

Abstract

Non-equilibrium 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 the dynamical phase transition, merging different concepts of dynamical criticality, are observed by measuring the non-equilibrium order parameter, nonlocal correlations, and the Loschmidt echo. Moreover, near the dynamical critical point, we obtain the optimal spin squeezing of $-7.0\pm 0.8$ decibels, showing multipartite entanglement useful for measurements with precision five-fold beyond the standard quantum limit. Based on the capability of entangling qubits simultaneously and the accurate single-shot readout of multi-qubit states, this superconducting quantum simulator can be used to study other problems in non-equilibrium quantum many-body systems., Comment: 13 pages, 13 figures

Published

2019

29. Observation of energy resolved many-body localization

Author

Guo, Qiujiang, Cheng, Chen, Sun, Zheng-Hang, Song, Zixuan, Li, Hekang, Wang, Zhen, Ren, Wenhui, Dong, Hang, Zheng, Dongning, Zhang, Yu-Ran, Mondaini, Rubem, Fan, Heng, and Wang, H.

Subjects

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

Abstract

Many-body localization (MBL) describes a quantum phase where an isolated interacting system subject to sufficient disorder displays non-ergodic behavior, evading thermal equilibrium that occurs under its own dynamics. Previously, the thermalization-MBL transition has been largely characterized with the growth of disorder. Here, we explore a new axis, reporting on an energy resolved MBL transition using a 19-qubit programmable superconducting processor, which enables precise control and flexibility of both disorder strength and initial state preparations. We observe that the onset of localization occurs at different disorder strengths, with distinguishable energy scales, by measuring time-evolved observables and many-body wavefunctions related quantities. Our results open avenues for the experimental exploration of many-body mobility edges in MBL systems, whose existence is widely debated due to system size finiteness, and where exact simulations in classical computers become unfeasible., Comment: 9 pages, 5 figures + supplementary information

Published

2019

30. Topological band theory for non-Hermitian systems from the Dirac equation

Author

Ge, Zi-Yong, Zhang, Yu-Ran, Liu, Tao, Li, Si-Wen, Fan, Heng, and Nori, Franco

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, High Energy Physics - Theory, Quantum Physics

Abstract

We identify and investigate two classes of non-Hermitian systems, i.e., one resulting from Lorentz-symmetry violation (LSV) and the other from a complex mass (CM) with Lorentz invariance, from the perspective of quantum field theory. The mechanisms to break, and approaches to restore, the bulk-boundary correspondence in these two types of non-Hermitian systems are clarified. The non-Hermitian system with LSV shows a non-Hermitian skin effect, and its topological phase can be characterized by mapping it to the Hermitian system via a non-compact $U(1)$ gauge transformation. In contrast, there exists no non-Hermitian skin effect for the non-Hermitian system with CM. Moreover, the conventional bulk-boundary correspondence holds in this (CM) system. We also consider a general non-Hermitian system in the presence of both LSV and CM, and we generalize its bulk-boundary correspondence., Comment: 14 pages, 4 figures

Published

2019

31. Nonmesonic Quantum Many-Body Scars in a 1D Lattice Gauge Theory

Author

Ge, Zi-Yong, primary, Zhang, Yu-Ran, additional, and Nori, Franco, additional

Published

2024

32. Second-Order Topological Phases in Non-Hermitian Systems

Author

Liu, Tao, Zhang, Yu-Ran, Ai, Qing, Gong, Zongping, Kawabata, Kohei, Ueda, Masahito, and Nori, Franco

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

A $d$-dimensional second-order topological insulator (SOTI) can host topologically protected $(d - 2)$-dimensional gapless boundary modes. Here we show that a 2D non-Hermitian SOTI can host zero-energy modes at its corners. In contrast to the Hermitian case, these zero-energy modes can be localized only at one corner. A 3D non-Hermitian SOTI is shown to support second-order boundary modes, which are localized not along hinges but anomalously at a corner. The usual bulk-corner (hinge) correspondence in the second-order 2D (3D) non-Hermitian system breaks down. The winding number (Chern number) based on complex wavevectors is used to characterize the second-order topological phases in 2D (3D). A possible experimental situation with ultracold atoms is also discussed. Our work lays the cornerstone for exploring higher-order topological phenomena in non-Hermitian systems., Comment: 26 pages, 18 figures, including supplemental material

Published

2018

33. Characterization of topological states via dual multipartite entanglement

Author

Zhang, Yu-Ran, Zeng, Yu, Fan, Heng, You, J. Q., and Nori, Franco

Subjects

Quantum Physics

Abstract

We demonstrate that multipartite entanglement is able to characterize one-dimensional symmetry-protected topological order, which is witnessed by the scaling behavior of the quantum Fisher information of the ground state with respect to the spin operators defined in the dual lattice. We investigate an extended Kitaev chain with a $\mathbf{Z}$ symmetry identified equivalently by winding numbers and paired Majorana zero modes at each end. The topological phases with high winding numbers are detected by the scaling coefficient of the quantum Fisher information density with respect to generators in different dual lattices. Containing richer properties and more complex structures than bipartite entanglement, the dual multipartite entanglement of the topological state has promising applications in robust quantum computation and quantum metrology, and can be generalized to identify topological order in the Kitaev honeycomb model., Comment: 7+14 pages, 4+7 figures

Published

2017

34. Experimental valley qubit state tomography and coherence induced uncertainty relations in monolayer WSe$_2$

Author

Zhang, Yu-Ran, Wang, Jing, Zhu, Chuanrui, Fan, Heng, and Liu, Baoli

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Velleytronics as a new electronic conception is an emerging exciting research field with wide potential applications, which is attracting great research interests for their extraordinary properties. The localized electronic spins by optical generation of valley polarization with spin-like quantum numbers are promising candidates for implementing quantum-information processing in solids. It is expected that a single qubit preparation can be realized optically by using combination of left- and right-circularly polarized lights. Significantly in a series of experiments, this has already been well achieved by linearly polarized laser representing equal weights of left- and right-circular components resulting in formation of a valley exciton as a specific pseudo-spin qubit with equal amplitudes for spin up and spin down. Further researches on the control of valley pseudospin using longitudinal magnetic field and optical Stark effect have been reported. However, a general qubit preparation has not yet been demonstrated. Moreover as a platform for quantum information processing, the precise readout of a qubit state is necessary, for which the state tomography is a standard method in obtaining all information of a qubit state density matrix., Comment: 5 pages, 4 figures

Published

2017

35. The Geometry of Quantum Coherence for Two Qubit $X$ States

Author

Wang, Yao-Kun, Shao, Lian-He, and Zhang, Yu-Ran

Subjects

Quantum Physics

Abstract

We plot the geometry of several distance-based quantifiers of coherence for Bell-diagonal states. We find that along with both $l_{1}$ norm and relative entropy of coherence changes continuously from zero to one, their surfaces move from the separable regions to the entangled regions. Based on this fact, it is more illuminating to use an intuitive geometry to explain quantum states with nonzero coherence can be used for entanglement creation, rather than the other way around. We find the necessary and sufficient conditions that quantum discord of Bell-diagonal states equal to its relative entropy of coherence and depict the surfaces of the equality. We give surfaces of relative entropy of coherence for $X$ states. We show the surfaces of dynamics of relative entropy of coherence for Bell-diagonal states under local nondissipative channels and find that all coherence under local nondissipative channels decrease., Comment: 10 pages, 9 figures

Published

2017

36. Quantum coherence and geometric quantum discord

Author

Hu, Ming-Liang, Hu, Xueyuan, Wang, Jie-Ci, Peng, Yi, Zhang, Yu-Ran, and Fan, Heng

Subjects

Quantum Physics

Abstract

Quantum coherence and quantum correlations are of fundamental and practical significance for the development of quantum mechanics.They are also cornerstones of quantum computation and quantum communication theory. Searching physically meaningful and mathematically rigorous quantifiers of them are long-standing concerns of the community of quantum information science, and various faithful measures have been introduced so far. We review in this paper the measures of discordlike quantum correlations for bipartite and multipartite systems, the measures of quantum coherence for any single quantum system, and their relationship in different settings. Our aim is to provide a full review about the resource theory of quantum coherence, including its application in many-body systems, and the discordlike quantum correlations which were defined based on the various distance measures of states. We discuss the interrelations between quantum coherence and quantum correlations established in an operational way, and the fundamental characteristics of quantum coherence such as their complementarity under different basis sets, their duality with path information of an interference experiment, their distillation and dilution under different operations, and some new viewpoints of the superiority of the quantum algorithms from the perspective of quantum coherence. Additionally, we review properties of geometric quantum correlations and quantum coherence under noisy quantum channels. Finally, the main progresses for the study of quantum correlations and quantum coherence in the relativistic settings are reviewed. All these results provide an overview for the conceptual implications and basic connections of quantum coherence, quantum correlations, and their potential applications in various related subjects of physics., Comment: 82 pages, 8 figures; Final version to be published in Physics Reports

Published

2017

37. One-way deficit and quantum phase transitions in $XY$ model and extended Ising model

Author

Wang, Yao-Kun, Zhang, Yu-Ran, and Fan, Heng

Subjects

Quantum Physics

Abstract

Originating in questions regarding work extraction from quantum systems coupled to a heat bath, quantum deficit, a kind of quantum correlations besides entanglement and quantum discord, links quantum thermodynamics with quantum correlations. In this paper, we evaluate the one-way deficit of two adjacent spins in the bulk for the $XY$ model and its extend model: the extended Ising model. We find that the one-way deficit susceptibility is able to characterize the quantum phase transitions in the $XY$ model and even the topological phase transitions in the extend Ising model. This study may enlighten extensive studies of quantum phase transitions from the perspective of quantum information processing and quantum computation, including finite-temperature phase transitions, topological phase transitions and dynamical phase transitions of a variety of quantum many-body systems., Comment: 6 pages, 5 figures, one more contributor

Published

2017

38. Complementary relation of quantum coherence and quantum correlations in multiple measurements

Author

Fan, Zeyang, Peng, Yi, Zhang, Yu-Ran, Liu, Shang, Mu, Liang-Zhu, and Fan, Heng

Subjects

Quantum Physics

Abstract

Quantum coherence and quantum correlations lie in the center of quantum information science, since they both are considered as fundamental reasons for significant features of quantum mechanics different from classical mechanics. We present a group of complementary relations for quantum coherence and quantum correlations; specifically, we focus on thermal discord and conditional information in scenarios of multiple measurements. We show that the summation of quantum coherence quantified in different bases has a lower bound, resulting from entropic uncertainty relations with multiple measurements. Similar results are also obtained for thermal discord and for post-measurement conditional information with multiple measurements in a multipartite system. These results indicate the general applications of the uncertainty principle to various concepts of quantum information., Comment: 7 pages

Published

2016

39. Phase diagram of quantum critical system via local convertibility of ground state

Author

Liu, Si-Yuan, Quan, Quan, Chen, Jin-Jun, Zhang, Yu-Ran, Yang, Wen-Li, and Fan, Heng

Subjects

Quantum Physics

Abstract

We investigate the relationship between two kinds of ground-state local convertibility and quantum phase transitions in XY model. The local operations and classical communications (LOCC) convertibility is examined by the majorization relations and the entanglement-assisted local operations and classical communications (E- LOCC) via Renyi entropy interception. In the phase diagram of XY model, LOCC convertibility and ELOCC convertibility of ground-states are presented and compared. It is shown that different phases in the phase dia- gram of XY model can have different LOCC or ELOCC convertibility, which can be used to detect the quantum phase transition. This study will enlighten extensive studies of quantum phase transitions from the perspective of local convertibility, e.g., finite-temperature phase transitions and other quantum many-body models., Comment: 5 pages, 4 figures

Published

2015

40. Experimental testing of entropic uncertainty relations with multiple measurements in pure diamond

Author

Xing, Jian, Zhang, Yu-Ran, Liu, Shang, Chang, Yan-Chun, Yue, Jie-Dong, Fan, Heng, and Pan, Xin-Yu

Subjects

Quantum Physics

Abstract

One unique feature of quantum mechanics is the Heisenberg uncertainty principle, which states that the outcomes of two incompatible measurements cannot simultaneously achieve arbitrary precision. In an information-theoretic context of quantum information, the uncertainty principle can be formulated as entropic uncertainty relations with two measurements for a quantum bit (qubit) in two-dimensional system. New entropic uncertainty relations are studied for a higher-dimensional quantum state with multiple measurements, the uncertainty bounds can be tighter than that expected from two measurements settings and cannot result from qubits system with or without a quantum memory. Here we report the first room-temperature experimental testing of the entropic uncertainty relations with three measurements in a natural three-dimensional solid-state system: the nitrogen-vacancy center in pure diamond. The experimental results confirm the entropic uncertainty relations for multiple measurements. Our result represents a more precise demonstrating of the fundamental uncertainty principle of quantum mechanics., Comment: 8 pages, 5 figures, 2 tables

Published

2015

41. Coherence susceptibility as a probe of quantum phase transitions

Author

Chen, Jin-Jun, Cui, Jian, Zhang, Yu-Ran, and Fan, Heng

Subjects

Quantum Physics, Condensed Matter - Statistical Mechanics, Condensed Matter - Strongly Correlated Electrons

Abstract

We introduce a coherence susceptibility method, based on the fact that it signals quantum fluctuations, for identifying quantum phase transitions, which are induced by quantum fluctuations. This method requires no prior knowledge of order parameter, and there is no need for careful considerations concerning the choice of a bipartition of the system. It can identify different types of quantum phase transition points exactly. At finite temperatures, where quantum criticality is influenced by thermal fluctuations, our method can pinpoint the temperature frame of quantum criticality, which perfectly coincides with recent experiments., Comment: Accepted version

Published

2015

42. Majorization relation in quantum critical systems

Author

Huai, Lin-Ping, Zhang, Yu-Ran, Liu, Si-Yuan, Yang, Wen-Li, Qu, Shi-Xian, and Fan, Heng

Subjects

Quantum Physics

Abstract

The most basic local conversion is local operations and classical communications (LOCC), which is also the most natural restriction in quantum information processing. We investigate the conversions between the ground states in quantum critical systems via LOCC and propose an novel method to reveal the different convertibility via majorization relation when a quantum phase transition occurs. The ground-state local convertibility in the one-dimensional transverse field Ising model is studied. It is shown that the LOCC convertibility changes nearly at the phase transition point. The relation between the order of quantum phase transitions and the LOCC convertibility is discussed. Our results are compared with the corresponding results using the Renyi entropy and the LOCC convertibility with assisted entanglement., Comment: 4 pages, 4 figures

Published

2015

43. Quantifying Coherence in Infinite Dimensional Systems

Author

Zhang, Yu-Ran, Shao, Lian-He, Li, Yongming, and Fan, Heng

Subjects

Quantum Physics

Abstract

We study the quantification of coherence in infinite dimensional systems, especially the infinite dimensional bosonic systems in Fock space. We show that given the energy constraints, the relative entropy of coherence serves as a well-defined quantification of coherence in infinite dimensional systems. Via using the relative entropy of coherence, we also generalize the problem to multi-mode Fock space and special examples are considered. It is shown that with a finite average particle number, increasing the number of modes of light can enhance the relative entropy of coherence. With the mean energy constraint, our results can also be extended to other infinite-dimensional systems., Comment: 5 pages, 2 figures

Published

2015

44. Observation of energy-resolved many-body localization

Author

Guo, Qiujiang, Cheng, Chen, Sun, Zheng-Hang, Song, Zixuan, Li, Hekang, Wang, Zhen, Ren, Wenhui, Dong, Hang, Zheng, Dongning, Zhang, Yu-Ran, Mondaini, Rubem, Fan, Heng, and Wang, H.

Published

2021

45. Operation triggered quantum clock synchronization

Author

Yue, Jie-Dong, Zhang, Yu-Ran, and Fan, Heng

Subjects

Quantum Physics

Abstract

We present a novel quantum clock synchronization(QCS) scheme of multiple parties which uses operation as the trigger to start the evolution of the initial state, where existing QCS protocols use measurement to start the evolution. Since the trigger is the unitary operation, we have protected entanglement of remote nodes, and after concentration of the qubits to the center node, general measurements of the total state is possible. We show that our protocol links the QCS problem to a multiple phase estimation problem. We use the Fisher information to give the precision of the synchronization, and explicitly show that the Heisenberg scale of synchronization is achieved in the two party case. We also show that our protocol is very efficient in synchronizing a clock to the average time of other clocks. The precision has an $O(\sqrt{d})$ advantage of the precision of the average time's estimation over the best possible strategy using measurement triggered QCS. The precision is also Heisenberg scale.

Published

2014

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

Author

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

Published

2023

47. Demonstration of Entanglement-Enhanced Phase Estimation in Solid

Author

Liu, Gang-Qin, Zhang, Yu-Ran, Chang, Yan-Chun, Yue, Jie-Dong, Fan, Heng, and Pan, Xin-Yu

Subjects

Quantum Physics

Abstract

Precise parameter estimation plays a central role in science and technology. The statistical error in estimation can be decreased by repeating measurement, leading to that the resultant uncertainty of the estimated parameter is proportional to the square root of the number of repetitions in accordance with the central limit theorem. Quantum parameter estimation, an emerging field of quantum technology, aims to use quantum resources to yield higher statistical precision than classical approaches. Here, we report the first room-temperature implementation of entanglement-enhanced phase estimation in a solid-state system: the nitrogen-vacancy centre in pure diamond. We demonstrate a super-resolving phase measurement with two entangled qubits of different physical realizations: an nitrogen-vacancy centre electron spin and a proximal ${}^{13}$C nuclear spin. The experimental data shows clearly the uncertainty reduction when entanglement resource is used, confirming the theoretical expectation. Our results represent an elemental demonstration of enhancement of quantum metrology against classical procedure., Comment: 9 pages including the supplementary material, 6 figures in main text plus 3 figures in supplementary material

Published

2014

48. Multipartite distribution property of one way discord beyond measurement

Author

Liu, Si-Yuan, Zhang, Yu-Ran, Yang, Wen-Li, and Fan, Heng

Subjects

Quantum Physics

Abstract

We investigate the distribution property of one way discord in multipartite system by introducing the concept of polygamy deficit for one way discord. The difference between one way discord and quantum discord is analogue to the difference between entanglement of assistance and entanglement of formation. For tripartite pure states, two kinds of polygamy deficits are presented with the equivalent expressions and physical interpretations regardless of measurement. For four-partite pure states, we provide a condition which makes one way discord polygamy being satisfied. Those results can be applicable to multipartite quantum systems and are complementary to our understanding of the shareability of quantum correlations., Comment: 5 pages, 2 figures

Published

2014

49. Global quantum discord and quantum phase transition in XY model

Author

Liu, Si-Yuan, Zhang, Yu-Ran, Yang, Wen-Li, and Fan, Heng

Subjects

Quantum Physics

Abstract

We study the relationship between the behavior of global quantum correlations and quantum phase transitions in XY model. We find that the two kinds of phase transitions in the studied model can be characterized by the features of global quantum discord (GQD) and the corresponding quantum correlations. We demonstrate that the maximum of the sum of all the nearest neighbor bipartite GQDs is effective and accurate for signaling the Ising quantum phase transition, in contrast, the sudden change of GQD is very suitable for characterizing another phase transition in the XY model. This may shed lights on the study of properties of quantum correlations in different quantum phases., Comment: 6 pages, 4 figures

Published

2014

50. Quantum Metrological Bounds for Vector Parameter

Author

Zhang, Yu-Ran and Fan, Heng

Subjects

Quantum Physics

Abstract

Precise measurement is crucial to science and technology. However, the rule of nature imposes various restrictions on the precision that can be achieved depending on specific methods of measurement. In particular, quantum mechanics poses the ultimate limit on precision which can only be approached but never be violated. Depending on analytic techniques, these bounds may not be unique. Here, in view of prior information, we investigate systematically the precision bounds of the total mean-square error of vector parameter estimation which contains $d$ independent parameters. From quantum Ziv-Zakai error bounds, we derive two kinds of quantum metrological bounds for vector parameter estimation, both of which should be satisfied. By these bounds, we show that a constant advantage can be expected via simultaneous estimation strategy over the optimal individual estimation strategy, which solves a long-standing problem. A general framework for obtaining the lower bounds in a noisy system is also proposed., Comment: 8 pages, 4 figures

Published

2014