Your search keyword '"Sun, Kai"' showing total 46 results

1. Observing tight triple uncertainty relations in two-qubit systems

Author

Wang, Yan, Zhou, Jie, Fan, Xing-Yan, Hao, Ze-Yan, Li, Jia-Kun, Liu, Zheng-Hao, Sun, Kai, Xu, Jin-Shi, Chen, Jing-Ling, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Quantum Physics

Abstract

As the fundamental tool in quantum information science, the uncertainty principle is essential for manifesting nonclassical properties of quantum systems. Plenty of efforts on the uncertainty principle with two observables have been achieved, making it an appealing challenge to extend the scenario to multiple observables. Here, based on an optical setup, we demonstrate the uncertainty relations in two-qubit systems involving three physical components with the tight constant $2/\sqrt{3}$, which signifies a more precise limit in the measurement of multiple quantum components and offers deeper insights into the trade-offs between observables. Furthermore, we reveal the correspondence of the maximal values of the uncertainty functions and the degree of entanglement, where the more uncertainty is proportional to the higher degree of entanglement. Our results provide a new insight into understanding the uncertainty relations with multiple observables and may motivate more innovative applications in quantum information science., Comment: 13 pages,16 figures

Published

2024

2. Ultra spectral sensitivity and non-local bi-impurity bound states from quasi-long-range non-hermitian skin modes

Author

Shu, Chang, Zhang, Kai, and Sun, Kai

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Quantum Gases, Physics - Optics, Quantum Physics

Abstract

A fundamental tenet of quantum mechanics is that the energy spectrum of a quantum system shall remain stable against infinitesimally weak and spatially confined perturbations. In this article, we demonstrate that this principle of spectral stability fails in non-Hermitian systems at the thermodynamic limit. Consider, for instance, a non-interacting non-Hermitian system $H_0$ with a couple of point-like impurities, each of which introduces a local short-range potential $V_i$ with $i=1, \ldots, n$ labeling the impurities. If the impurity potentials are sufficiently weak, introducing a single impurity will not alter the spectrum; that is, $H_0$ and $H_0 + V_1$ have nearly identical energy spectra. However, if a second impurity is introduced, $H_0 + V_1 + V_2$, we find that no matter how weak these local potentials are, as long as the distance between them is sufficiently large, significant alterations in the energy spectrum can arise, directly contradicting the traditional expectation of a stable spectrum. Remarkably, this phenomenon is non-local, and the impact of the perturbations increases exponentially with the distance between the two impurities. In other words, although the Hamiltonian is entirely local, its energy spectrum, which is blind to the presence of a single infinitesimally weak impurity, is capable of detecting the presence of two infinitesimally weak impurities separated by a large distance in space. Using Green's function techniques, we uncover the origin of this spectral sensitivity, which arises from the formation of non-local bi-impurity bound states: non-local stationary states with wavepackets propagating back-and-forth between the two impurities. We provide an analytic theory to identify and characterize such spectral instabilities, showing perfect agreement with numerical solutions., Comment: 16 pages, 11 figures

Published

2024

3. Algebraic non-Hermitian skin effect and unified non-Bloch band theory in arbitrary dimensions

Author

Zhang, Kai, Shu, Chang, and Sun, Kai

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Quantum Gases, Physics - Optics, Quantum Physics

Abstract

The non-Hermitian skin effect, characterized by a proliferation of exponentially-localized edge modes, has led to numerous novel physical phenomena that challenge the limits of conventional band theory. In sharp contrast to the traditional exponential localization, this manuscript reports a new kind of non-Hermitian skin effect, which we term the ``algebraic non-Hermitian skin effect." This effect emerges across a diverse spectrum of non-Hermitian systems in both two- and higher space dimensions. For 2D systems with algebraic non-Hermitian skin effect, on geometries such as a torus or cylinder, these systems exhibit behavior reminiscent of the conventional non-Hermitian skin effect, where eigenmodes are either bulk Bloch waves (on a torus) or exponentially localized edge modes (on a cylinder). However, if the same system is placed on a disk or any geometrical shape featuring open boundaries in all directions, the skin modes immediately transform into the algebraic form, with amplitude decaying as a power-law function of the distance from the boundary. To explore these novel effects, we formulate a unified generalized Brillouin zone (GBZ) framework that is universally applicable to all variations of non-Hermitian skin effects across any spatial dimension, developed through the usage of a generalized transfer-matrix approach. We find that in a $d$-dimensional non-Hermitian system, in general, the GBZ manifold's dimensionality must fall into the range from $d$ to $2d-1$, denoted by ${d \leq \dim\text{GBZ} \leq 2d-1}$. In 1D, this inequality is trivial because the upper and lower bounds converge, forcing the GBZ's dimensionality to match with that of the physical space. However, in 2D and above, this inequality indicates that there is no obligation for the GBZ's dimensionality to concur with the physical space's dimensionality, which gives rise to a new class of non-Hermitian skin effects., Comment: 19 pages, 5 figures

Published

2024

4. Photonic simulation of Majorana-based Jones polynomials

Author

Li, Jia-Kun, Sun, Kai, Hao, Ze-Yan, Liang, Jia-He, Tao, Si-Jing, Pachos, Jiannis K., Xu, Jin-Shi, Han, Yong-Jian, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Quantum Physics

Abstract

Jones polynomials were introduced as a tool to distinguish between topologically different links. Recently, they emerged as the central building block of topological quantum computation: by braiding non-Abelian anyons it is possible to realise quantum algorithms through the computation of Jones polynomials. So far, it has been a formidable task to evaluate Jones polynomials through the control and manipulation of non-Abelian anyons. In this study, a photonic quantum system employing two-photon correlations and non-dissipative imaginary-time evolution is utilized to simulate two inequivalent braiding operations of Majorana zero modes. The resulting amplitudes are shown to be mathematically equivalent to Jones polynomials at a particular value of their parameter. The high-fidelity of our optical platform allows us to distinguish between a wide range of links, such as Hopf links, Solomon links, Trefoil knots, Figure Eight knots and Borromean rings, through determining their corresponding Jones polynomials. Our photonic quantum simulator represents a significant step towards executing fault-tolerant quantum algorithms based on topological quantum encoding and manipulation.

Published

2024

5. An integral algorithm of exponential observables for interacting fermions in quantum Monte Carlo simulation

Author

Zhang, Xu, Pan, Gaopei, Chen, Bin-Bin, Sun, Kai, and Meng, Zi Yang

Subjects

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

Abstract

Exponential observables, formulated as $\log \langle e^{\hat{X}}\rangle$ where $\hat{X}$ is an extensive quantity, play a critical role in study of quantum many-body systems, examples of which include the free-energy and entanglement entropy. Given that $e^{X}$ becomes exponentially large (or small) in the thermodynamic limit, accurately computing the expectation value of this exponential quantity presents a significant challenge. In this Letter, we propose a comprehensive algorithm for quantifying these observables in interacting fermion systems, utilizing the determinant quantum Monte Carlo (DQMC) method. We have applied this novel algorithm to the 2D half-filled Hubbard model. At the strong coupling limit, our method showcases a significant accuracy improvement compared to conventional methods that are derived from the internal energy. We also illustrate that this novel approach delivers highly efficient and precise measurements of the nth R\'enyi entanglement entropy. Even more noteworthy is that this improvement comes without incurring increases in computational complexity. This algorithm effectively suppresses exponential fluctuations and can be easily generalized to other models., Comment: 5 pages, 2 figure

Published

2023

6. Edge theory of non-Hermitian skin modes in higher dimensions

Author

Zhang, Kai, Yang, Zhesen, and Sun, Kai

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Quantum Gases, Physics - Optics, Quantum Physics

Abstract

In this paper, we establish an effective edge theory to characterize non-Hermitian edge-skin modes in higher dimensions. We begin by proposing a bulk projection criterion to straightforwardly identify the localized edges of skin modes. Through an exact mapping, we show that the edge-skin mode shares the same bulk-boundary correspondence and localization characteristics as the zero-energy edge states in a Hermitian semimetal under open-boundary conditions, bridging the gap between non-Hermitian edge-skin effect and Hermitian semimetals. Another key finding is the introduction of ``skewness,'' a term we proposed to describe the characteristic decay direction of skin mode from the localized edge into the bulk. Remarkably, we demonstrate that skewness is an intrinsic quantity of the skin mode and can be analytically determined using the corresponding cylinder-geometry bulk Hamiltonian, without requiring any boundary details. Furthermore, we reveal that in the edge-skin effect, the spectrum exhibits anomalous spectral sensitivity to weak local disturbances, a feature that crucially distinguishes it from the corner-skin effect., Comment: 15 pages, 10 figures

Published

2023

7. Topologically Protected Exceptional Points and Reentrant $\mathcal{PT}$ Phase in an Exact Ternary Model

Author

Lee, Chulwon, Zhang, Kai, Miao, Jinyan, Sun, Kai, and Deng, Hui

Subjects

Physics - Optics, Quantum Physics

Abstract

In open, driven systems where parity-time symmetry is preserved, phenomena that defy conventional wisdom emerge near exceptional points, promising advances in photonics. While most studies focus on two-level systems of a conventional exceptional point, unconventional exceptional points as well as reentrant phases have been discovered in separate studies of higher-dimensional phase spaces. In this Letter, we present a minimal, analytical model that encompasses several key phenomena in higher-dimensional phase spaces, including reentrant PT phases, higher-order exceptional points, and anisotropic exceptional points. Using the exact analytical solution, we identify a new topological index as the unifying origin of these different phenomena. The simplicity of the model may furthermore facilitate experimental implementations for enhanced sensing and efficient polariton devices., Comment: 12 pages, 7 figures

Published

2023

8. Loss-induced universal one-way transport in periodically driven systems

Author

Shu, Chang, Zhang, Kai, and Sun, Kai

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

In this paper, we show that a periodically driven Aubry-Andr\'e-Harper model with imbalanced on-site gain/loss supports universal one-way transport that is immune to impurities and independent of initial excitations. We reveal the underlying mechanism that the periodic driving gives rise to the non-Hermitian skin effect in the effective Floquet Hamiltonian, thereby causing universal non-reciprocal transport. Additionally, we probe the time-average decay rate of the propagator under long-time bulk dynamics as a signature of the Floquet emergent non-Hermitian skin effect. Our results provide a feasible and controllable way to realize universal one-way transport that is easily accessible to experiments., Comment: 14 pages, 14 figures

Published

2023

9. Filtering one-way Einstein-Podolsky-Rosen steering

Author

Hao, Ze-Yan, Wang, Yan, Li, Jia-Kun, Xiang, Yu, He, Qiong-Yi, Liu, Zheng-Hao, Yang, Mu, Sun, Kai, Xu, Jin-Shi, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Quantum Physics

Abstract

Einstein-Podolsky-Rosen (EPR) steering, a fundamental concept of quantum nonlocality, describes one observer's capability to remotely affect another distant observer's state by local measurements. Unlike quantum entanglement and Bell nonlocality, both associated with the symmetric quantum correlation, EPR steering depicts the unique asymmetric property of quantum nonlocality. With the local filter operation in which some system components are discarded, quantum nonlocality can be distilled to enhance the nonlocal correlation, and even the hidden nonlocality can be activated. However, asymmetric quantum nonlocality in the filter operation still lacks a well-rounded investigation, especially considering the discarded parts where quantum nonlocal correlations may still exist with probabilities. Here, in both theory and experiment, we investigate the effect of reusing the discarded particles from local filter. We observe all configurations of EPR steering simultaneously and other intriguing evolution of asymmetric quantum nonlocality, such as reversing the direction of one-way EPR steering. This work provides a perspective to answer "What is the essential role of utilizing quantum steering as a resource?", and demonstrates a practical toolbox for manipulating asymmetric quantum systems with significant potential applications in quantum information tasks., Comment: 11pages, 6figures

Published

2023

10. Experimental demonstration of separating the waveparticle duality of a single photon with the quantum Cheshire cat

Author

Li, JiaKun, Sun, Kai, Wang, Yan, Hao, ZeYan, Liu, ZhengHao, Zhou, Jie, Fan, XingYan, Chen, JingLing, Xu, JinShi, Li, ChuanFeng, and Guo, GuangCan

Subjects

Quantum Physics

Abstract

As a fundamental characteristic of physical entities, waveparticle duality describes whether a microscopic entity exhibits wave or particle attributes depending on the specific experimental setup. This assumption is premised on the notion that physical properties are inseparable from the objective carrier. However, after the concept of the quantum Cheshire cats was proposed, which makes the separation of physical attributes from the entity possible, the premise no longer holds. Furthermore, an experimental demonstration of the separation of the wave and particle attributes inspired by this scenario remains scarce. In this work, we experimentally separated the wave and particle attributes of a single photon by exploiting the quantum Cheshire cat concept for the first time. By applying a weak disturbance to the evolution of the system, we achieve an effect similar to the quantum Cheshire cat and demonstrated the separation of the wave and particle attributes via the extraction of weak values. Our work provides a new perspective for the indepth understanding of waveparticle duality and promotes the application of weak measurements in fundamentals of quantum mechanics., Comment: 12 pages,4 figures, published in Light: Science & Applications

Published

2023

11. Direct measurement of particle statistical phase

Author

Wang, Yan, Piccolini, Matteo, Hao, Ze-Yan, Liu, Zheng-Hao, Sun, Kai, Xu, Jin-Shi, Li, Chuan-Feng, Guo, Guang-Can, Morandotti, Roberto, Compagno, Giuseppe, and Franco, Rosario Lo

Subjects

Quantum Physics

Abstract

The symmetrization postulate in quantum mechanics is formally reflected in the appearance of an exchange phase ruling the symmetry of identical particle global states under particle swapping. Many indirect measurements of this fundamental phase have been reported so far, while a direct observation has been only recently achieved for photons. Here we propose a general scheme capable to directly measure the exchange phase of any type of particles (bosons, fermions, anyons), exploiting the operational framework of spatially localized operations and classical communication. We experimentally implement it in an all-optical platform providing proof-of-principle for different simulated exchange phases. As a byproduct, we supply a direct measurement of the real bosonic exchange phase of photons. Also, we analyze the performance of the proposed scheme when mixtures of particles of different nature are injected. Our results confirm the symmetrization tenet and provide a tool to explore it in various scenarios., Comment: 8 pages, 6 figures. Acknowledgements added

Published

2022

12. Remote entanglement distribution in a quantum network via multinode indistinguishability of photons

Author

Wang, Yan, Hao, Ze-Yan, Liu, Zheng-Hao, Sun, Kai, Xu, Jin-Shi, Li, Chuan-Feng, Guo, Guang-Can, Castellini, Alessia, Bellomo, Bruno, Compagno, Giuseppe, and Franco, Rosario Lo

Subjects

Quantum Physics

Abstract

Quantum networking relies on entanglement distribution between distant nodes, typically realized by swapping procedures. However, entanglement swapping is a demanding task in practice, mainly because of limited effectiveness of entangled photon sources and Bell-state measurements necessary to realize the process. Here we experimentally activate a remote distribution of two-photon polarization entanglement superseding the need for initial entangled pairs and traditional Bell-state measurements. This alternative procedure is accomplished thanks to the controlled spatial indistinguishability of four independent photons in three separated nodes of the network, which enables us to perform localized product-state measurements in the central node acting as a trigger. This experiment proves that the inherent indistinguishability of identical particles supplies new standards for feasible quantum communication in multinode photonic quantum networks., Comment: 5+5 pages, 3+3 figures, one table. Updated version

Published

2021

13. Demonstrating shareability of multipartite Einstein-Podolsky-Rosen steering

Author

Hao, Ze-Yan, Sun, Kai, Wang, Yan, Liu, Zheng-Hao, Yang, Mu, Xu, Jin-Shi, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Quantum Physics

Abstract

Einstein-Podolsky-Rosen (EPR) steering, a category of quantum nonlocal correlations describing the ability of one observer to influence another party's state via local measurements, is different from both entanglement and Bell nonlocality by possessing an asymmetric property. For multipartite EPR steering, the monogamous situation, where two observers cannot simultaneously steer the state of the third party, has been investigated rigorously both in theory and experiment. In contrast to the monogamous situation, the shareability of EPR steering in reduced subsystems allows the state of one party to be steered by two or more observers and thus reveals more configurations of multipartite EPR steering. However, the experimental implementation of such a kind of shareability has still been absent until now. Here, in an optical experiment, we provide a proof-of-principle demonstration of the shareability of EPR steering without the constraint of monogamy in a three-qubit system. Moreover, based on the reduced bipartite EPR steering detection results, we verify the genuine three-qubit entanglement results. This work provides a complementary viewpoint for understanding multipartite EPR steering and has potential applications in many quantum information protocols, such as multipartite entanglement detection, quantum cryptography, and the construction of quantum networks., Comment: 7 pages, 3 figures

Published

2021

14. Experimental quantum phase discrimination enhanced by controllable indistinguishability-based coherence

Author

Sun, Kai, Liu, Zheng-Hao, Wang, Yan, Hao, Ze-Yan, Xu, Xiao-Ye, Xu, Jin-Shi, Li, Chuan-Feng, Guo, Guang-Can, Castellini, Alessia, Lami, Ludovico, Winter, Andreas, Adesso, Gerardo, Compagno, Giuseppe, and Franco, Rosario Lo

Subjects

Quantum Physics

Abstract

Quantum coherence, a basic feature of quantum mechanics residing in superpositions of quantum states, is a resource for quantum information processing. Coherence emerges in a fundamentally different way for nonidentical and identical particles, in that for the latter a unique contribution exists linked to indistinguishability which cannot occur for nonidentical particles. We experimentally demonstrate by an optical setup this additional contribution to quantum coherence, showing that its amount directly depends on the degree of indistinguishability and exploiting it to run a quantum phase discrimination protocol. Furthermore, the designed setup allows for simulating Fermionic particles with photons, thus assessing the role of particle statistics (Bosons or Fermions) in coherence generation and utilization. Our experiment proves that independent indistinguishable particles can supply a controllable resource of coherence for quantum metrology., Comment: 6 pages, 4 figures

Published

2021

15. Optical demonstration of quantum fault-tolerant threshold

Author

Sun, Kai, Xu, Jin-Shi, Xu, Xiao-Ye, Han, Yong-Jian, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Quantum Physics

Abstract

A major challenge in practical quantum computation is the ineludible errors caused by the interaction of quantum systems with their environment. Fault-tolerant schemes, in which logical qubits are encoded by several physical qubits, enable correct output of logical qubits under the presence of errors. However, strict requirements to encode qubits and operators render the implementation of a full fault-tolerant computation challenging even for the achievable noisy intermediate-scale quantum technology. Here, we experimentally demonstrate the existence of the threshold in a special fault-tolerant protocol. Four physical qubits are implemented using 16 optical spatial modes, in which 8 modes are used to encode two logical qubits. The experimental results clearly show that the probability of correct output in the circuit, formed with fault-tolerant gates, is higher than that in the corresponding non-encoded circuit when the error rate is below the threshold. In contrast, when the error rate is above the threshold, no advantage is observed in the fault-tolerant implementation. The developed high-accuracy optical system may provide a reliable platform to investigate error propagation in more complex circuits with fault-tolerant gates., Comment: 12 pages, 14 figures, submitted to the journal on 27 July

Published

2020

16. Photonic implementation of quantum information masking

Author

Liu, Zheng-Hao, Liang, Xiao-Bin, Sun, Kai, Li, Qiang, Meng, Yu, Yang, Mu, Li, Bo, Chen, Jing-Ling, Xu, Jin-Shi, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Quantum Physics

Abstract

Masking of quantum information spreads it over nonlocal correlations and hides it from the subsystems. It is known that no operation can simultaneously mask all pure states [Phys. Rev. Lett. 120, 230501 (2018)], so in what sense is quantum information masking useful? Here, we extend the definition of quantum information masking to general mixed states, and show that the resource of maskable quantum states are far more abundant than the no-go theorem seemingly suggests. Geometrically, the simultaneously maskable states lays on hyperdisks in the state hypersphere, and strictly contain the broadcastable states. We devise a photonic quantum information masking machine using time-correlated photons to experimentally investigate the properties of qubit masking, and demonstrate the transfer of quantum information into bipartite correlations and its faithful retrieval. The versatile masking machine has decent extensibility, and may be applicable to quantum secret sharing and fault-tolerant quantum communication. Our results provide some insights on the comprehension and potential application of quantum information masking., Comment: 5+11 pages, 4+5 figures. To appear in PRL

Published

2020

17. Topological contextuality and anyonic statistics of photonic-encoded parafermions

Author

Liu, Zheng-Hao, Sun, Kai, Pachos, Jiannis K., Yang, Mu, Meng, Yu, Liao, Yu-Wei, Li, Qiang, Wang, Jun-Feng, Luo, Ze-Yu, He, Yi-Fei, Huang, Dong-Yu, Ding, Guang-Rui, Xu, Jin-Shi, Han, Yong-Jian, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

Quasiparticle poisoning, expected to arise during the measurement of Majorana zero mode state, poses a fundamental problem towards the realization of Majorana-based quantum computation. Parafermions, a natural generalization of Majorana fermions, can encode topological qudits immune to quasiparticle poisoning. While parafermions are expected to emerge in superconducting fractional quantum Hall systems, they are not yet attainable with current technology. To bypass this problem, we employ a photonic quantum simulator to experimentally demonstrate the key components of parafermion-based universal quantum computation. Our contributions in this article are twofold. First, by manipulating the photonic states, we realize Clifford operator Berry phases that correspond to braiding statistics of parafermions. Second, we investigate the quantum contextuality in a topological system for the first time by demonstrating the contextuality of parafermion encoded qudit states. Importantly, we find that the topologically-encoded contextuality opens the way to magic state distillation, while both the contextuality and the braiding-induced Clifford gates are resilient against local noise. By introducing contextuality, our photonic quantum simulation provides the first step towards a physically robust methodology for realizing topological quantum computation., Comment: 11+6 pages, 5+2 figures, 1+2 tables, presentation extended and improved, analysis and results the same, to appear in PRX Quantum

Published

2020

18. Verification of Group Non-membership by Shallow Quantum Circuits

Author

Sun, Kai, Zhang, Zi-Jian, Meng, Fei, Cheng, Bin, Cao, Zhu, Xu, Jin-Shi, Yung, Man-Hong, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Quantum Physics, Physics - Optics

Abstract

Decision problems are the problems whose answer is either YES or NO. As the quantum analogue of $\mathsf{NP}$ (nondeterministic polynomial time), the class $\mathsf{QMA}$ (quantum Merlin-Arthur) contains the decision problems whose YES instance can be verified efficiently with a quantum computer. The problem of deciding the group non-membership (GNM) of a group element is known to be in $\mathsf{QMA}$. Previous works on the verification of GNM required a quantum circuit with $O(n^5)$ group oracle calls. Here we propose an efficient way to verify GNM problems, reducing the circuit depth to $O(1)$ and the number of qubits by half. We further experimentally demonstrate the scheme, in which two-element subgroups in a four-element group are employed for the verification task. A significant completeness-soundness gap is observed in the experiment., Comment: 21 pages, 5 figures

Published

2020

19. Linear Optical Approach to Supersymmetric Dynamics

Author

Zhan, Yong-Tao, Xu, Xiao-Ye, Wang, Qin-Qin, Pan, Wei-Wei, Jan, Munsif, Chang, Fu-Ming, Sun, Kai, Xu, Jin-Shi, Han, Yong-Jian, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Quantum Physics

Abstract

The concept of supersymmetry developed in particle physics has been applied to various fields of modern physics. In quantum mechanics, the supersymmetric systems refer to the systems involving two supersymmetric partner Hamiltonians, whose energy levels are degeneracy except one of the systems has an extra ground state possibly, and the eigenstates of the partner systems can be mapped onto each other. Recently, an interferometric scheme has been proposed to show this relationship in ultracold atoms [Phys. Rev.A 96, 043624 (2017)]. Here this approach is generalized to linear optics for observing the supersymmetric dynamics with photons. The time evolution operator is simulated approximately via Suzuki-Trotter expansion with considering the realization of the kinetic and potential terms separately. The former is realized through the diffraction nature of light and the later is implemented using phase plate. Additionally, we propose an interferometric approach which can be implemented perfectly using amplitude alternator to realize the non-unitary operator. The numerical results show that our scheme is universal and can be realized with current technologies., Comment: 7 pages

Published

2020

20. Room temperature coherent manipulation of single-spin qubits in silicon carbide with a high readout contrast

Author

Li, Qiang, Wang, Jun-Feng, Yan, Fei-Fei, Zhou, Ji-Yang, Wang, Han-Feng, Liu, He, Guo, Li-Ping, Zhou, Xiong, Gali, Adam, Liu, Zheng-Hao, Wang, Zu-Qing, Sun, Kai, Guo, Guo-Ping, Tang, Jian-Shun, Li, Hao, You, Li-Xing, Xu, Jin-Shi, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Quantum Physics

Abstract

Spin defects in silicon carbide (SiC) with mature wafer-scale fabrication and micro/nano-processing technologies have recently drawn considerable attention. Although room temperature single-spin manipulation of colour centres in SiC has been demonstrated, the typically detected contrast is less than 2%, and the photon count rate is also low. Here, we present the coherent manipulation of single divacancy spins in 4H-SiC with a high readout contrast (-30%) and a high photon count rate (150 kilo counts per second) under ambient conditions, which are competitive with the nitrogen-vacancy (NV) centres in diamond. Coupling between a single defect spin and a nearby nuclear spin is also observed. We further provide a theoretical explanation for the high readout contrast by analysing the defect levels and decay paths. Since the high readout contrast is of utmost importance in many applications of quantum technologies, this work might open a new territory for SiC-based quantum devices with many advanced properties of the host material., Comment: 10 pages, 5 figures

Published

2020

21. Dynamical crossover in the transient quench dynamics of short-range transverse field Ising models

Author

Dağ, Ceren B. and Sun, Kai

Subjects

Quantum Physics, Condensed Matter - Statistical Mechanics

Abstract

Dynamical detection of quantum phases and phase transitions (QPT) in quenched systems with experimentally convenient initial states is a topic of interest from both theoretical and experimental perspectives. Quenched from polarized states, longitudinal magnetization decays exponentially to zero in time for the short-range transverse-field Ising model (TFIM) and hence, has a featureless steady state regime, which prevents it from exhibiting dynamical phase transitions of type-I. In this paper, we ask whether the transient regimes of such non-equilibrium processes probed by single-site observables, that is magnetization per site, could encode information about the underlying QPT. The decay rates of time-dependent and single-site observables exhibit a dynamical crossover that separates two dynamical regions, ordered and disordered, both of which have distinct nonequilibrium responses. We construct a dynamical order parameterlike quantity that exhibits a scaling law at the vicinity of the crossover. Our results reveal that scaling law exponent in short times at the close vicinity of the dynamical crossover is significantly different than the one predicted by analytical theory for long times. When integrability is strongly broken, the crossover boundary turns into a region that separates two other dynamical regions that act like dynamically-ordered and -disordered regimes., Comment: 14 Pages, 15 Figures

Published

2020

22. Experimental control of remote spatial indistinguishability of photons to realize entanglement and teleportation

Author

Sun, Kai, Wang, Yan, Liu, Zheng-Hao, Xu, Xiao-Ye, Xu, Jin-Shi, Li, Chuan-Feng, Guo, Guang-Can, Castellini, Alessia, Nosrati, Farzam, Compagno, Giuseppe, and Franco, Rosario Lo

Subjects

Quantum Physics

Abstract

Remote spatial indistinguishability of identical subsystems as a direct controllable quantum resource at distant sites has not been yet experimentally proven. We design a setup capable to tune the spatial indistinguishability of two photons by independently adjusting their spatial distribution in two distant regions, which leads to polarization entanglement starting from uncorrelated photons. The amount of entanglement uniquely depends on the degree of remote spatial indistinguishability, quantified by an entropic measure $\mathcal{I}$, which enables teleportation with fidelities above the classical threshold. This experiment realizes a basic nonlocal entangling gate by the inherent nature of identical quantum subsystems., Comment: 6+5 pages, 4+10 figures. Paper submitted to the journal on October 7th, 2019

Published

2020

23. Direct measurement of a nonlocal entangled quantum state

Author

Pan, Wei-Wei, Xu, Xiao-Ye, Kedem, Yaron, Wang, Qin-Qin, Chen, Zhe, Jan, Munsif, Sun, Kai, Xu, Jin-Shi, Han, Yong-Jian, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Quantum Physics

Abstract

Entanglement and wave function description are two of the core concepts that make quantum mechanics such a unique theory. A method to directly measure the wave function, using Weak Values, was demonstrated by Lundeen et al., Nature \textbf{474}, 188(2011). However, it is not applicable to a scenario of two disjoint systems, where nonlocal entanglement can be a crucial element since that requires obtaining the Weak Values of nonlocal observables. Here, for the first time, we propose a method to directly measure a nonlocal wave function of a bipartite system, using Modular Values. The method is experimentally implemented for a photon pair in a hyper-entangled state, i.e. entangled both in polarization and momentum degrees of freedom., Comment: 13 pages, 4 figures

Published

2019

24. Topologically induced prescrambling and dynamical detection of topological phase transitions at infinite temperature

Author

Dağ, Ceren B., Duan, L. -M., and Sun, Kai

Subjects

Quantum Physics, Condensed Matter - Statistical Mechanics

Abstract

We report a numerical observation where the infinite-temperature out-of-time-order correlators (OTOCs) directly probe quantum phase transitions at zero temperature, in contrast to common intuition where low energy quantum effects are washed away by strong thermal fluctuations at high temperature. By comparing numerical simulations with exact analytic results, we determine that this phenomenon has a topological origin and is highly generic, as long as the underlying system can be mapped to a 1D Majorana chain. Using the Majorana basis, we show that the infinite-temperature OTOCs probe zero-temperature quantum phases via detecting the presence of Majorana zero modes at the ends of the chain that is associated with 1D $Z_2$ topological order. Hence, we show that strong zero modes also affect OTOCs and scrambling dynamics. Our results demonstrate an intriguing interplay between information scrambling and topological order, which leads to a new phenomenon in the scrambling of generic nonintegrable models: topological order induced prescrambling, paralleling the notion of prethermalization of two-time correlators, that defines a time-scale for the restricted scrambling of topologically-protected quantum information., Comment: Journal publication version: presentation improved, typos fixed, 18 pages with 9+12 figures

Published

2019

25. Measurements of nonlocal variables and demonstration of the failure of the product rule for a pre- and postselected pair of photons

Author

Xu, Xiao-Ye, Pan, Wei-Wei, Wang, Qin-Qin, Dziewior, Jan, Knips, Lukas, Kedem, Yaron, Sun, Kai, Xu, Jin-Shi, Han, Yong-Jian, Li, Chuan-Feng, Guo, Guang-Can, and Vaidman, Lev

Subjects

Quantum Physics

Abstract

We report the first implementation of the von Neumann instantaneous measurements of nonlocal variables which becomes possible due to technological achievements in creating hyperentangled photons. Tests of reliability and of the nondemolition property of the measurements have been performed with high precision showing the suitability of the scheme as a basic ingredient of numerous quantum information protocols. The method allows to demonstrate for the first time with strong measurements a special feature of pre- and postselected quantum systems: the failure of the product rule. It has been verified experimentally that for a particular pre- and postselected pair of particles a single measurement on particle $A$ yields with certainty $\sigma_x^A=-1$, a single measurement on particle $B$ yields with certainty $\sigma_y^B=-1$, and a single nonlocal measurement on particles $A$ and $B$ yields with certainty $\sigma_x^A \sigma_y^B=-1$., Comment: 6 pages, 5 figures, to be published in PRL

Published

2019

26. Detection of quantum phases via out-of-time-order correlators

Author

Dağ, Ceren B., Sun, Kai, and Duan, L. -M.

Subjects

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

Abstract

We elucidate the relation between out-of-time-order correlators (OTOCs) and quantum phase transitions via analytically studying the OTOC dynamics in a degenerate spectrum. Our method points to key ingredients to dynamically detect quantum phases via out-of-time-order correlators for a wide range of quantum phase transitions and explains the existing numerical results in the literature. We apply our method to a critical model, XXZ model that numerically confirms our predictions., Comment: Presentation improved

Published

2019

27. General Hardy-Type Paradox Based on Bell inequality and its Experimental Test

Author

Yang, Mu, Meng, Hui-Xian, Zhou, Jie, Xu, Zhen-Peng, Xiao, Ya, Sun, Kai, Chen, Jing-Ling, Xu, Jin-Shi, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Quantum Physics

Abstract

Local realistic models cannot completely describe all predictions of quantum mechanics. This is known as Bell's theorem that can be revealed either by violations of Bell inequality, or all-versus-nothing proof of nonlocality. Hardy's paradox is an important all-versus-nothing proof and is considered as "the simplest form of Bell's theorem". In this work, we theoretically build the general framework of Hardy-type paradox based on Bell inequality. Previous Hardy's paradoxes have been found to be special cases within the framework. Stronger Hardy-type paradox has been found even for the two-qubit two-setting case, and the corresponding successful probability is about four times larger than the original one, thus providing a more friendly test for experiment. We also find that GHZ paradox can be viewed as a perfect Hardy-type paradox. Meanwhile, we experimentally test the stronger Hardy-type paradoxes in a two-qubit system. Within the experimental errors, the experimental results coincide with the theoretical predictions., Comment: 5 Pages, 3 Figures. SI: 15 Pages, 5 Figures

Published

2018

28. Measuring the winding number in a large-scale chiral quantum walk

Author

Xu, Xiao-Ye, Wang, Qin-Qin, Pan, Wei-Wei, Sun, Kai, Xu, Jin-Shi, Chen, Geng, Tang, Jian-Shun, Gong, Ming, Han, Yong-Jian, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Quantum Physics

Abstract

We report the experimental measurement of the winding number in an unitary chiral quantum walk. Fundamentally, the spin-orbit coupling in discrete time quantum walks is implemented via birefringent crystal collinearly cut based on time-multiplexing scheme. Our protocol is compact and avoids extra loss, making it suitable for realizing genuine single-photon quantum walks at a large-scale. By adopting heralded single-photon as the walker and with a high time resolution technology in single-photon detection, we carry out a 50-step Hadamard discrete-time quantum walk with high fidelity up to 0.948$\pm$0.007. Particularly, we can reconstruct the complete wave-function of the walker that starts the walk in a single lattice site through local tomography of each site. Through a Fourier transform, the wave-function in quasi-momentum space can be obtained. With this ability, we propose and report a method to reconstruct the eigenvectors of the system Hamiltonian in quasi-momentum space and directly read out the winding numbers in different topological phases (trivial and non-trivial) in the presence of chiral symmetry. By introducing nonequivalent time-frames, we show that the whole topological phases in periodically driven system can also be characterized by two different winding numbers. Our method can also be extended to the high winding number situation., Comment: 26 pages, 8 figures

Published

2018

29. Dynamic-Disorder-Induced Enhancement of Entanglement in Photonic Quantum Walks

Author

Wang, Qin-Qin, Xu, Xiao-Ye, Pan, Wei-Wei, Sun, Kai, Xu, Jin-Shi, Chen, Geng, Han, Yong-Jian, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Quantum Physics

Abstract

Entanglement generation in discrete time quantum walks is deemed to be another key property beyond the transport behaviors. The latter has been widely used in investigating the localization or topology in quantum walks. However, there are few experiments involving the former for the challenges in full reconstruction of the final wave function. Here, we report an experiment demonstrating the enhancement of the entanglement in quantum walks using dynamic disorder. Through reconstructing the local spinor state for each site, von Neumann entropy can be obtained and used to quantify the coin-position entanglement. We find that the enhanced entanglement in the dynamically disordered quantum walks is independent of the initial state, which is different from the entanglement generation in the Hadamard quantum walks. Our results are inspirational for achieving quantum computing based on quantum walks., Comment: 18 pages, 6 figures. arXiv admin note: text overlap with arXiv:1808.09278

Published

2018

30. Measuring a Dynamical Topological Order Parameter in Quantum Walks

Author

Xu, Xiao-Ye, Wang, Qin-Qin, Heyl, Markus, Budich, Jan Carl, Pan, Wei-Wei, Chen, Zhe, Jan, Munsif, Sun, Kai, Xu, Jin-Shi, Han, Yong-Jian, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Quantum Physics

Abstract

Quantum processes of inherent dynamical nature, such as quantum walks (QWs), defy a description in terms of an equilibrium statistical physics ensemble. Up to now, it has remained a key challenge to identify general principles behind the underlying unitary quantum dynamics. Here, we show and experimentally observe that split-step QWs admit a characterization in terms of a dynamical topological order parameter (DTOP). This integer-quantized DTOP measures, at a given time, the winding of the geometric phase accumulated by the wave-function during the QW. We observe distinct dynamical regimes in our experimentally realized QWs each of which can be attributed to a qualitatively different temporal behavior of the DTOP. Upon identifying an equivalent many-body problem, we reveal an intriguing connection between the nonanalytic changes of the DTOP in QWs and the occurrence of dynamical quantum phase transitions.

Published

2018

31. Demonstration of Einstein-Podolsky-Rosen Steering with Enhanced Subchannel Discrimination

Author

Sun, Kai, Ye, Xiang-Jun, Xiao, Ya, Xu, Xiao-Ye, Wu, Yu-Chun, Xu, Jin-Shi, Chen, Jing-Ling, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Quantum Physics, Physics - Optics

Abstract

Einstein-Podolsky-Rosen (EPR) steering describes a quantum nonlocal phenomenon in which one party can nonlocally affect the other's state through local measurements. It reveals an additional concept of quantum nonlocality, which stands between quantum entanglement and Bell nonlocality. Recently, a quantum information task named as subchannel discrimination (SD) provides a necessary and sufficient characterization of EPR steering. The success probability of SD using steerable states is higher than using any unsteerable states, even when they are entangled. However, the detailed construction of such subchannels and the experimental realization of the corresponding task are still technologically challenging. In this work, we designed a feasible collection of subchannels for a quantum channel and experimentally demonstrated the corresponding SD task where the probabilities of correct discrimination are clearly enhanced by exploiting steerable states. Our results provide a concrete example to operationally demonstrate EPR steering and shine a new light on the potential application of EPR steering., Comment: 16 pages, 8 figures, appendix included

Published

2018

32. Demonstration of MultiSetting One-Way Einstein-Podolsky-Rosen Steering in Two-Qubit Systems

Author

Xiao, Ya, Ye, Xiang-Jun, Sun, Kai, Xu, Jin-Shi, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Quantum Physics

Abstract

Einstein-Podolsky-Rosen (EPR) steering describes the ability of one party to remotely affect another's state through local measurements. One of the most distinguishable properties of EPR steering is its asymmetric aspect. Steering can work in one direction but fail in the opposite direction. This type of one-way steering, which is different from the symmetry concepts of entanglement and Bell nonlocality, has garnered much interest. However, an experimental demonstration of genuine EPR steering in the simplest scenario, i.e., one that employs two-qubit systems, is still lacking. In this work, we experimentally demonstrate one-way EPR steering with multimeasurement settings for a class of two-qubit states, which are still one-way steerable even with infinite settings. The steerability is quantified by the steering radius, which represents a necessary and sufficient steering criterion. The demonstrated one-way steering in the simplest bipartite quantum system is of fundamental interest and may provide potential applications in one-way quantum information tasks., Comment: 5 pages, 4 figures

Published

2017

33. Photonic implementation of Majorana-based Berry phases

Author

Xu, Jin-Shi, Sun, Kai, Pachos, Jiannis K., Han, Yong-Jian, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Quantum Physics, Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory

Abstract

Geometric phases, generated by cyclic evolutions of quantum systems, offer an inspiring playground for advancing fundamental physics and technologies, alike. Intriguingly, the exotic statistics of anyons realised in physical systems can be interpreted as a topological version of geometric phases. However, non-Abelian statistics has not yet been demonstrated in the laboratory. Here we employ an all optical quantum system that simulates the statistical evolution of Majorana fermions. As a result we experimentally realise non-Abelian Berry phases with the topological characteristic that they are invariant under continues deformations of their control parameters. We implement a universal set of Majorana inspired gates by performing topological and non-topological evolutions and investigate their resilience against perturbative errors. Our photonic experiment, while it is not scalable, it suggests the intriguing possibility of experimentally simulating Majorana statistics with scalable technologies., Comment: 8 pages, 4 figures

Published

2017

34. Probe knots and Hopf insulators with ultracold atoms

Author

Deng, Dong-Ling, Wang, Sheng-Tao, Sun, Kai, and Duan, L. -M.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons, Mathematical Physics, Quantum Physics

Abstract

Knots and links are fascinating and intricate topological objects. Their influence spans from DNA and molecular chemistry to vortices in superfluid helium, defects in liquid crystals and cosmic strings in the early universe. Here, we find that knotted structures also exist in a peculiar class of three-dimensional topological insulators---the Hopf insulators. In particular, we demonstrate that the momentum-space spin textures of Hopf insulators are twisted in a nontrivial way, which implies the presence of various knot and link structures. We further illustrate that the knots and nontrivial spin textures can be probed via standard time-of-flight images in cold atoms as preimage contours of spin orientations in stereographic coordinates. The extracted Hopf invariants, knots, and links are validated to be robust to typical experimental imperfections. Our work establishes the existence of knotted structures in Hopf insulators, which may have potential applications in spintronics and quantum information processing., Comment: 7 pages, 3 figures and 2 pages of supplemental information

Published

2016

35. Experimental demonstration of the Einstein-Podolsky-Rosen steering game based on the All-Versus-Nothing proof

Author

Sun, Kai, Xu, Jin-Shi, Ye, Xiang-Jun, Wu, Yu-Chun, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Quantum Physics

Abstract

Einstein-Podolsky-Rosen (EPR) steering, a generalization of the original concept of "steering" proposed by Schr\"{o}dinger, describes the ability of one system to nonlocally affect another system's states through local measurements. Some experimental efforts to test EPR steering in terms of inequalities have been made, which usually require many measurement settings. Analogy to the "All-Versus-Nothing" (AVN) proof of Bell's theorem without inequalities, testing steerability without inequalities would be more strong and require less resource. Moreover, the practical meaning of steering implies that it should also be possible to store the state information on the side to be steered, a result that has not yet been experimentally demonstrated. Using a recent AVN criterion for two qubit entangled states, we experimentally implement a practical steering game using quantum memory. Further more, we develop a theoretical method to deal with the noise and finite measurement statistics within the AVN framework and apply it to analyze the experimental data. Our results clearly show the facilitation of the AVN criterion for testing steerability and provide a particularly strong perspective for understanding EPR steering., Comment: 5 pages, 4 figures + 6 pages supplementary

Published

2015

36. Experimental quantification of asymmetric Einstein-Podolsky-Rosen steering

Author

Sun, Kai, Ye, Xiang-Jun, Xu, Jin-Shi, Xu, Xiao-Ye, Tang, Jian-Shun, Wu, Yu-Chun, Chen, Jing-Ling, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Quantum Physics

Abstract

Einstein-Podolsky-Rosen (EPR) steering describes the ability of one observer to nonlocally "steer" the other observer's state through local measurements. It exhibits a unique asymmetric property, i.e., the steerability of one observer to steer the other's state could be different from each other, which can even lead to a one-way EPR steering, i.e., only one observer obtains the steerability in the two-observer case. This property is inherently different from the symmetric concepts of entanglement and Bell nonlocality and has been attracted increasing interests. Here, we experimentally demonstrate the asymmetric EPR steering for a class of two-qubit states in the case of two measurement settings. We propose a practical method to quantify the steerability. We then provide a necessary and sufficient condition for EPR steering and clearly show the case of one-way EPR steering. Our work provides a new insight on the fundamental asymmetry of quantum nonlocality and would find potential application in asymmetric quantum information processing., Comment: 12 pages, 12 figures

Published

2015

37. Simulating the exchange of Majorana zero modes with a photonic system

Author

Xu, Jin-Shi, Sun, Kai, Han, Yong-Jian, Li, Chuan-Feng, Pachos, Jiannis K., and Guo, Guang-Can

Subjects

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

Abstract

The realization of Majorana zero modes is in the centre of intense theoretical and experimental investigations. Unfortunately, their exchange that can reveal their exotic statistics needs manipulations that are still beyond our experimental capabilities. Here we take an alternative approach. Through the Jordan-Wigner transformation, the Kitaev's chain supporting two Majorana zero modes is mapped to the spin-1/2 chain. We experimentally simulated the spin system and its evolution with a photonic quantum simulator. This allows us to probe the geometric phase, which corresponds to the exchange of two Majorana zero modes positioned at the ends of a three-site chain. Finally, we demonstrate the immunity of quantum information encoded in the Majorana zero modes against local errors through the simulator. Our photonic simulator opens the way for the efficient realization and manipulation of Majorana zero modes in complex architectures., Comment: main text (10 pages, 4 figures) and detailed supplementary information

Published

2014

38. An experimental proposal to observe non-abelian statistics of Majorana-Shockley fermions in an optical lattice

Author

Deng, Dong-Ling, Wang, Sheng-Tao, Sun, Kai, and Duan, Lu-Ming

Subjects

Quantum Physics, Condensed Matter - Quantum Gases, Condensed Matter - Superconductivity

Abstract

We propose an experimental scheme to observe non-abelian statistics with cold atoms in a two dimensional optical lattice. We show that the Majorana-Schockley modes associated with line defects obey non-abelian statistics and can be created, braided, and fused, all through adiabatic shift of the local chemical potentials. The detection of the topological qubit is transformed to local measurement of the atom number on a single lattice site. We demonstrate the robustness of the braiding operation by incorporating noise and experiential imperfections in numerical simulations, and show that the requirement fits well with the current experimental technology., Comment: 6 pages

Published

2014

39. Phase estimation with weak measurement using a white light source

Author

Xu, Xiao-Ye, Kedem, Yaron, Sun, Kai, Vaidman, Lev, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Quantum Physics

Abstract

We report results of a high precision phase estimation based on a weak measurements scheme using commercial light-emitting diode. The method is based on a measurement of the imaginary part of the weak value of a polarization operator. The imaginary part of the weak value appeared due to the measurement interaction itself. The sensitivity of our method is equivalent to resolving light pulses of order of attosecond and it is robust against chromatic dispersion., Comment: 4 pages, 4 figures, accepted to PRL

Published

2013

40. Topological Zero-Energy Modes in Gapless Commensurate Aubry-Andr\'e-Harper Models

Author

Ganeshan, Sriram, Sun, Kai, and Sarma, S. Das

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

The Aubry-Andr\'e or Harper (AAH) model has been the subject of extensive theoretical research in the context of quantum localization. Recently, it was shown that one-dimensional quasicrystals described by the incommensurate AAH model has a nontrivial topology. In this Letter, we show that the commensurate off-diagonal AAH model is topologically nontrivial in the gapless regime and supports zero-energy edge modes. Unlike the incommensurate case, the nontrivial topology in the off-diagonal AAH model is attributed to the topological properties of the one-dimensional Majorana chain. We discuss the feasibility of experimental observability of our predicted topological phase in the commensurate AAH model., Comment: 5 pages + 1 page supplementary material

Published

2013

41. Quantitative verification of the Kibble-Zurek mechanism in quantum non-equilibrium dynamics

Author

Xu, Xiao-Ye, Han, Yong-Jian, Sun, Kai, Xu, Jin-Shi, Tang, Jian-Shun, Li, Chuan-Feng, and Guo, Guang-Can

Subjects

Quantum Physics

Abstract

The Kibble-Zurek mechanism (KZM) captures the key physics in the non-equilibrium dynamics of second-order phase transitions, and accurately predict the density of the topological defects formed in this process. However, despite much effort, the veracity of the central prediction of KZM, i.e., the scaling of the density production and the transit rate, is still an open question. Here, we performed an experiment, based on a nine-stage optical interferometer with an overall fidelity up to 0.975$\pm$0.008, that directly supports the central prediction of KZM in quantum non-equilibrium dynamics. In addition, our work has significantly upgraded the number of stages of the optical interferometer to nine with a high fidelity, this technique can also help to push forward the linear optical quantum simulation and computation.

Published

2013

42. Topological flat band models with arbitrary Chern numbers

Author

Yang, Shuo, Gu, Zheng-Cheng, Sun, Kai, and Sarma, S. Das

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Quantum Gases, Quantum Physics

Abstract

We report the theoretical discovery of a systematic scheme to produce topological flat bands (TFBs) with arbitrary Chern numbers. We find that generically a multi-orbital high Chern number TFB model can be constructed by considering multi-layer Chern number C=1 TFB models with enhanced translational symmetry. A series of models are presented as examples, including a two-band model on a triangular lattice with a Chern number C=3 and an $N$-band square lattice model with $C=N$ for an arbitrary integer $N$. In all these models, the flatness ratio for the TFBs is larger than 30 and increases with increasing Chern number. In the presence of appropriate inter-particle interactions, these models are likely to lead to the formation of novel Abelian and Non-Abelian fractional Chern insulators. As a simple example, we test the C=2 model with hardcore bosons at 1/3 filling and an intriguing fractional quantum Hall state is observed., Comment: 8 pages, 7 figures

Published

2012

43. Composite pulses for robust universal control of singlet-triplet qubits

Author

Wang, Xin, Bishop, Lev S., Kestner, J. P., Barnes, Edwin, Sun, Kai, and Sarma, S. Das

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

Precise qubit manipulation is fundamental to quantum computing, yet experimental systems generally have stray coupling between the qubit and the environment, which hinders the necessary high-precision control. We report here the first theoretical progress in correcting an important class of errors stemming from fluctuations in the magnetic field gradient, in the context of the singlet-triplet spin qubit in a semiconductor double quantum dot. These errors are not amenable to correction via control techniques developed in other contexts, since here the experimenter has precise control only over the rotation rate about the z-axis of the Bloch sphere, and this rate is furthermore restricted to be positive and bounded. Despite these strong constraints, we construct simple electrical pulse sequences that, for small gradients, carry out z-axis rotations while canceling errors up to the sixth order in gradient fluctuations, and for large gradients, carry out arbitrary rotations while canceling the leading order error., Comment: 8 pages, 4 figures + supplementary materials

Published

2012

44. Nested Quantum Error Correction Codes

Author

Wang, Zhuo, Sun, Kai, Fan, Hen, and Vedral, Vlatko

Subjects

Quantum Physics

Abstract

The theory of quantum error correction was established more than a decade ago as the primary tool for fighting decoherence in quantum information processing. Although great progress has already been made in this field, limited methods are available in constructing new quantum error correction codes from old codes. Here we exhibit a simple and general method to construct new quantum error correction codes by nesting certain quantum codes together. The problem of finding long quantum error correction codes is reduced to that of searching several short length quantum codes with certain properties. Our method works for all length and all distance codes, and is quite efficient to construct optimal or near optimal codes. Two main known methods in constructing new codes from old codes in quantum error-correction theory, the concatenating and pasting, can be understood in the framework of nested quantum error correction codes., Comment: 13 pages

Published

2009

45. Biaxial nematic phases in ultracold dipolar Fermi gases

Author

Fregoso, Benjamin M., Sun, Kai, Fradkin, Eduardo, and Lev, Benjamin L.

Subjects

Condensed Matter - Other Condensed Matter, Quantum Physics

Abstract

Ultracold dipolar Fermi gases represent relatively unexplored, strongly correlated systems arising from long-range and anisotropic interactions. We demonstrate the possibility of a spontaneous symmetry breaking biaxial phase in these systems, which may be realized in, e.g., gases of ultracold polar molecules or strongly magnetic atoms. This biaxial nematic phase is manifest in a spontaneous distortion of the Fermi surface perpendicular to the axis of polarization. We describe these dipolar interaction induced phases using Landau Fermi liquid theory., Comment: 4 pages, 1 figure; clarifying comments added to text

Published

2009

46. Polariton-driven $\mathcal{PT}$ Reentry and Anisotropic Exceptional Points in $\mathcal{PT}$-symmetric Ternary System

Author

Lee, Chulwon, Zhang, Kai, Miao, Jinyan, Sun, Kai, and Deng, Hui

Subjects

Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph), Optics (physics.optics), Physics - Optics

Abstract

Multi-mode parity-time symmetric non-Hermitian systems feature rich phenomena that promise better photonic technologies, but they are often difficult to understand and implement. Here we show that a three-mode polaritonic system forms a minimal model with reentrant parity-time exact phase. The analytical solution of its phase diagram indicates the reentrant phase is accompanied by several special features of multi-mode systems, including higher-order and anisotropic exceptional points, and near-zero-gain parity-time broken phase. Exciton coupling further facilitates tuning of the system to access the special features for enhanced sensing and efficient polariton devices., 10 pages, 5 figures

Published

2023