Your search keyword '"quantum entanglement"' showing total 50,022 results

1. Using Kondo entanglement to induce spin correlations between disconnected quantum dots.

Author

Büsser, C. A.

Subjects

*QUANTUM entanglement, *QUANTUM dots, *QUANTUM computing, *DENSITY matrices, *RENORMALIZATION group, *CANONICAL transformations, *RENORMALIZATION (Physics), *ELECTRON spin

Abstract

We investigate the entanglement between the spins of two quantum dots that are not simultaneously connected to the same system. Quantum entanglement among localized spins is a crucial property for the advancement of quantum computing and quantum information. Generating and controlling an entangled state between quantum dots have garnered significant attention in recent years for this reason. In this study, we demonstrate that information about the spin orientation of a quantum dot can be preserved, utilizing Kondo entanglement, within a reservoir of electrons. Subsequently, this information can be transmitted to another dot after the initial dot has been decoupled from the reservoirs. We employ a double quantum dot system in a parallel geometry to establish the initial state, where each dot interacts with reservoirs of different symmetries. A specific phase in the couplings is chosen to induce antiferromagnetic spin correlation between the dots. The time evolution of the initial state is analyzed using the time-dependent density matrix renormalization group method. Our findings reveal that a partially entangled state between the dots can be achieved, even when they are not simultaneously connected. This entangled state arises transiently and dissipates in the stationary state. The stability of the state observed during the transient phase is demonstrated. To comprehend the details of these phenomena, we employ a canonical transformation of real space. [ABSTRACT FROM AUTHOR]

Published

2024

2. Simulating the operation of a quantum computer in a dissipative environment.

Author

Zhang, Shuocang, Chen, Yinjia, and Shi, Qiang

Subjects

*QUANTUM entanglement, *QUANTUM computers, *EQUATIONS of motion, *COMPUTER simulation, *QUBITS

Abstract

The operations of current quantum computers are still significantly affected by decoherence caused by interaction with the environment. In this work, we employ the non-perturbative hierarchical equations of motion (HEOM) method to simulate the operation of model quantum computers and reveal the effects of dissipation on the entangled quantum states and on the performance of well-known quantum algorithms. Multi-qubit entangled states in Shor's factorizing algorithm are first generated and propagated using the HEOM. It is found that the failure of factorization is accompanied by a loss of fidelity and mutual information. An important challenge in using the HEOM to simulate quantum computers in a dissipative environment is how to efficiently treat systems with many qubits. We propose a two-dimensional tensor network scheme for this problem and demonstrate its capability by simulating a one-dimensional random circuit model with 21 qubits. [ABSTRACT FROM AUTHOR]

Published

2024

3. Investigating the dissipation of heat and quantum information from DNA-scaffolded chromophore networks.

Author

Rolczynski, Brian S., Díaz, Sebastián A., Goldman, Ellen R., Medintz, Igor L., and Melinger, Joseph S.

Subjects

*SECOND law of thermodynamics, *EQUATIONS of motion, *DNA nanotechnology, *QUANTUM entanglement, *POPULATION dynamics, *POLYMER networks

Abstract

Scaffolded molecular networks are important building blocks in biological pigment–protein complexes, and DNA nanotechnology allows analogous systems to be designed and synthesized. System–environment interactions in these systems are responsible for important processes, such as the dissipation of heat and quantum information. This study investigates the role of nanoscale molecular parameters in tuning these vibronic system–environment dynamics. Here, genetic algorithm methods are used to obtain nanoscale parameters for a DNA-scaffolded chromophore network based on comparisons between its calculated and measured optical spectra. These parameters include the positions, orientations, and energy level characteristics within the network. This information is then used to compute the dynamics, including the vibronic population dynamics and system–environment heat currents, using the hierarchical equations of motion. The dissipation of quantum information is identified by the system's transient change in entropy, which is proportional to the heat currents according to the second law of thermodynamics. These results indicate that the dissipation of quantum information is highly dependent on the particular nanoscale characteristics of the molecular network, which is a necessary first step before gleaning the systematic optimization rules. Subsequently, the I-concurrence dynamics are calculated to understand the evolution of the vibronic system's quantum entanglement, which are found to be long-lived compared to these system–bath dissipation processes. [ABSTRACT FROM AUTHOR]

Published

2024

4. Tutorial: Nonlinear magnonics.

Author

Zheng, Shasha, Wang, Zhenyu, Wang, Yipu, Sun, Fengxiao, He, Qiongyi, Yan, Peng, and Yuan, H. Y.

Subjects

*MAGNONS, *QUANTUM entanglement, *QUBITS, *PHONONS, *INFORMATION processing

Abstract

Nonlinear magnonics studies the nonlinear interaction between magnons and other physical platforms (phonon, photon, qubit, spin texture) to generate novel magnon states for information processing. In this Tutorial, we first introduce the nonlinear interactions of magnons in pure magnetic systems and hybrid magnon–phonon and magnon–photon systems. Then, we show how these nonlinear interactions can generate exotic magnonic phenomena. In the classical regime, we will cover the parametric excitation of magnons, bistability and multistability, and magnonic frequency comb. In the quantum regime, we will discuss the single-magnon state, Schrödinger cat state, and the entanglement and quantum steering among magnons, photons, and phonons. The applications of the hybrid magnonics systems in quantum transducer and sensing will also be presented. Finally, we look at the future development direction of nonlinear magnonics. [ABSTRACT FROM AUTHOR]

Published

2023

5. Distribution of quantum gravity induced entanglement in many-body systems.

Author

Ghosal, Pratik, Ghosal, Arkaprabha, and Bandyopadhyay, Somshubhro

Subjects

*QUANTUM gravity, *QUANTUM entanglement, *GRAVITATIONAL interactions, *QUANTUM states, *GRAVITY

Abstract

Recently, it was shown that if two distant test masses, each in a spatially superposed quantum state, become entangled due to their mutual gravitational interaction, then this entanglement could serve as evidence of the quantum nature of gravity. We extend this treatment to a many-body system in a general setup and study the entanglement properties of the time-evolved state. We exactly compute the time-dependent I-concurrence for every bipartition and obtain the necessary and sufficient condition for the creation of genuine many-body entanglement. We further show that this entanglement is of generalised GHZ type when certain conditions are met. We also evaluate the amount of multipartite entanglement in the system using a set of generalised Meyer-Wallach measures. [ABSTRACT FROM AUTHOR]

Published

2024

6. Neutrino many-body correlations.

Author

Johns, Lucas

Abstract

This paper responds to suggestions that the standard approach to collective neutrino oscillations leaves out potentially important quantum many-body correlations. Arguments in favor of this idea have been based on calculations that, on close scrutiny, offer no evidence either way. Inadequacies of the usual quantum-kinetic formalism are not currently supported by the literature. [ABSTRACT FROM AUTHOR]

Published

2024

7. Quantum correlations and parameter estimation for two superconducting qubits interacting with a quantized field.

Author

Berrada, K., Abdel-Khalek, S., Algarni, M., and Eleuch, H.

Subjects

*QUANTUM correlations, *FISHER information, *QUANTUM entanglement, *QUANTUM operators, *PARAMETER estimation

Abstract

In the present manuscript, we introduce a quantum system of two superconducting qubits (S–Qs) interacting with a quantized field under the influence of the Kerr nonlinear medium and Ising interaction. We formulate the Hamiltonian of the quantum model and determine the density operator of whole quantum system as well as quantum subsystems. We examine the dynamics of the quantumness measures for subsequent times including the S–Qs entanglement, S–Qs-field entanglement and quantum Fisher information in relation to the system parameters. Finally, we display the connection among the measures of quantumness during the time evolution. [ABSTRACT FROM AUTHOR]

Published

2024

8. Quantum Correlation Enhanced with Quantum Coherent Feedback Control in a Cavity‐magnon Hybrid System.

Author

Lin, Yue‐Han, Lin, Ya‐Qin, Lin, Zhi‐Ying, Yang, Rong‐Can, and Liu, Hong‐Yu

Abstract

A scheme is proposed to enhance quantum correlation, including entanglement and steering, for two magnon modes in a cavity‐magnon hybrid system through coherent quantum feedback. The hybrid system consists of a microwave cavity and two YIG spheres, which incorporates a nonlinear flux‐driven Josephson parametric amplifier in order for the generation of two photons within the cavity simultaneously. A quantum coherent feedback loop is used for the reduction of effective dissipation. By modulating feedback parameters, optimal bipartite and tripartite entanglement, as well as quantum steering are derived. Importantly, compared with the same setup without coherent feedback, the proposed scheme significantly improves quantum correlation. Furthermore, by optimizing the feedback reflectivity and the ratio of cavity‐magnon coupling strength, the enhancement of asymmetric steering can be controlled. Notably, incorporating the feedback loop effectively increase its robustness against thermal noise, thus the scheme offer better prospect for experimental development. This study paves the way for advancements in quantum information processing and quantum entanglement within cavity‐magnonics. [ABSTRACT FROM AUTHOR]

Published

2024

9. Quantifying entanglement for unknown quantum states via artificial neural networks.

Author

Pan, Guo-Zhu, Yang, Ming, Zhou, Jian, Yuan, Hao, Miao, Chun, and Zhang, Gang

Subjects

*ARTIFICIAL neural networks, *QUANTUM entanglement, *QUANTUM states, *QUANTUM computing, *MACHINE learning

Abstract

Quantum entanglement acts as a crucial part in quantum computation and quantum information, hence quantifying unknown entanglement is an important task. Due to the fact that the amount of entanglement cannot be achieved directly by measuring any physical observables, it remains an open problem to quantify entanglement experimentally. In this work, we provide an effective way to quantify entanglement for the unknown quantum states via artificial neural networks. By choosing the expectation values of measurements as input features and the values of entanglement measures as labels, we train artificial neural network models to predict the entanglement for new quantum states accurately. Our method does not require the full information about unknown quantum states, which highlights the effectiveness and versatility of machine learning in exploring quantum entanglement. [ABSTRACT FROM AUTHOR]

Published

2024

10. An architecture for two-qubit encoding in neutral ytterbium-171 atoms.

Author

Jia, Zhubing, Huie, William, Li, Lintao, Sun, Won Kyu Calvin, Hu, Xiye, Aakash, Kogan, Healey, Karve, Abhishek, Lee, Jong Yeon, and Covey, Jacob P.

Subjects

DEGREES of freedom, QUBITS, QUANTUM entanglement, ENCODING, ATOMS

Abstract

We present an architecture for encoding two qubits within the optical "clock" transition and nuclear spin-1/2 degree of freedom of neutral ytterbium-171 atoms. Inspired by recent high-fidelity control of all pairs of states within this four-dimensional quotes space, we present a toolbox for intra-ququart (single-atom) one- and two-qubit gates, inter-ququart (two-atom) Rydberg-based two- and four-qubit gates, and quantum nondemolition (QND) readout. We then use this toolbox to demonstrate the advantages of the ququart encoding for entanglement distillation and quantum error correction which exhibit superior hardware efficiency and better performance in some cases since fewer two-atom operations are required. Finally, leveraging single-state QND readout in our ququart encoding, we present a unique approach to studying interactive circuits and to realizing a symmetry protected topological phase of a spin-1 chain with a shallow, constant-depth circuit. [ABSTRACT FROM AUTHOR]

Published

2024

11. Dynamical evolution of a five-level atom interacting with an intensity-dependent coupling regime influenced by a nonlinear Kerr-like medium.

Author

Abdel-Wahab, N. H., Zangi, S. M., Seoudy, Tamer A., and Haddadi, Saeed

Subjects

*ENERGY levels (Quantum mechanics), *QUANTUM entanglement, *KERR electro-optical effect, *QUANTUM information science, *ATOMIC structure, *QUANTUM coherence

Abstract

We present an analytical solution for a quantum system characterized by a double Λ five-level atom interacting with an intensity-dependent coupling regime, influenced by a nonlinear Kerr-like medium. We also derive the constants of motion through Heisenberg's equations. Furthermore, the dynamical evolution of the entanglement and quantum coherence between the atom and the field is discussed using linear entropy and l 1 -norm of coherence. Through a comprehensive examination of the quantum system, it is observed that both the detuning and the Kerr-like parameters exert a significant impact on the degree of entanglement and coherence. However, the impacts of detuning and the Kerr effect become less pronounced when the photon multiplicity is high. In addition, we conduct a comparison between the five-level atomic system and a four-level system, revealing that the number of energy levels has a profound impact on the behavior of entanglement and coherence. These findings highlight the importance of atomic structure and photon multiplicity in controlling and optimizing quantum processes, particularly in applications involving quantum communication and information processing. [ABSTRACT FROM AUTHOR]

Published

2024

12. A constrained multi-period portfolio optimization model based on quantum-inspired optimization.

Author

Ramaiah, Kumar and Soundarabai, P. Beaulah

Subjects

METAHEURISTIC algorithms, OPTIMIZATION algorithms, PORTFOLIO management (Investments), UNCERTAINTY (Information theory), QUANTUM entanglement

Abstract

Multi-period portfolio optimization (MPO) is one of the most important problems to be solved to help investors select optimal portfolios for investment plans. The portfolios are influenced by the risk factors in the market and it is important to select optimal portfolios that can maximize the returns with minimum risk values. Other than the risk factor, there are several other influential factors that reduce the optimality of the portfolios. Therefore, by considering all possible constraints, this study proposes a multi-constraint MPO model that selects the optimal portfolio based on the asset returns. To solve the multi-constrained problem, a novel quantum-inspired whale optimization algorithm (QWOA) is introduced in this paper. The proposed algorithm enhances the traditional optimization model to work in a multi-constrained scenario. Here, quantum entanglement is adapted to reduce the slow convergence issue of whale optimization. Apart from considering only the risk factors, this paper also considers certain higher-order moments (HOM), such as skewness, kurtosis, transaction cost, diversification, boundary and budget constraints. These factors affect the portfolios as the market is dynamic, and timely changes are always seen. Thus, optimizing the mentioned factors aids in attaining an optimal portfolio. Empirical evaluations are performed, and the results suggested that the proposed model provided beneficial outcomes as compared with other algorithms like whale optimization algorithm (WOA), gray wolf optimization (GWO), fruitfly optimization algorithm (FOA), particle swarm optimization (PSO) and fruitfly algorithm (FA). The overall net return rate of the proposed model is always above 0.85% for different values of upper bounds, and the obtained Sharpe ratio, Sortino ratio, STARR ratio, information ratio, Shannon entropy, and downside deviation values of the proposed algorithm are 5.016254, 0.89327, − 0.01987, 0.103826, 3.04452 and 0.2854. Hence, the proposed approach is highly effective for optimizing the constrained MPO. [ABSTRACT FROM AUTHOR]

Published

2024

13. Near-field strong coupling and entanglement of quantum emitters for room-temperature quantum technologies.

Author

Clarke, Daniel D. A. and Hess, Ortwin

Subjects

NANOTECHNOLOGY, QUANTUM entanglement, QUANTUM information science, NANOPHOTONICS, ENERGY consumption, PLASMONICS

Abstract

In recent years, quantum nanophotonics has forged a rich nexus of nanotechnology with photonic quantum information processing, offering remarkable prospects for advancing quantum technologies beyond their current technical limits in terms of physical compactness, energy efficiency, operation speed, temperature robustness and scalability. In this perspective, we highlight a number of recent studies that reveal the especially compelling potential of nanoplasmonic cavity quantum electrodynamics for driving quantum technologies down to nanoscale spatial and ultrafast temporal regimes, whilst elevating them to ambient temperatures. Our perspective encompasses innovative proposals for quantum plasmonic biosensing, driving ultrafast single-photon emission and achieving near-field multipartite entanglement in the strong coupling regime, with a notable emphasis on the use of industry-grade devices. We conclude with an outlook emphasizing how the bespoke characteristics and functionalities of plasmonic devices are shaping contemporary research directives in ultrafast and room-temperature quantum nanotechnologies. [ABSTRACT FROM AUTHOR]

Published

2024

14. Non-Markovian noise mitigation in quantum teleportation: enhancing fidelity and entanglement.

Author

Zhang, Haiyang, Han, Xiaoxiang, Zhang, Guoqing, Li, Lianbi, Cheng, Lin, Wang, Jun, Zhang, Yunjie, Xia, Yanwen, and Xia, Caijuan

Subjects

*QUANTUM teleportation, *QUANTUM coherence, *QUANTUM theory, *QUANTUM noise, *QUANTUM entanglement

Abstract

Maintaining quantum coherence and entanglement in the presence of environmental noise, particularly within non-Markovian contexts, represents a significant challenge for the progression of quantum information science and technology. This study offers a substantial advancement by investigating the dynamics of a two-qubit system subjected to diverse noise conditions, encompassing relaxation, dephasing, and their cumulative effects. By employing quantum-state-diffusion equations specifically crafted for non-Markovian environments, we introduce an innovative strategy to counteract the detrimental influences of environmental noise on quantum teleportation fidelity and entanglement concurrence. Our results underscore the potential for external interventions to markedly improve the resilience of quantum information processing tasks over prolonged durations, especially in settings where dephasing noise prevails. A key revelation is the intricate relationship between dephasing noise and the initial state of entanglement, which profoundly impacts the occurrence of entanglement sudden death. This research not only deepens our comprehension of quantum system dynamics under noisy circumstances but also furnishes practical directives for engineering robust quantum systems, a necessity for the development of scalable quantum technologies. [ABSTRACT FROM AUTHOR]

Published

2024

15. Creating and controlling global Greenberger-Horne-Zeilinger entanglement on quantum processors.

Author

Bao, Zehang, Xu, Shibo, Song, Zixuan, Wang, Ke, Xiang, Liang, Zhu, Zitian, Chen, Jiachen, Jin, Feitong, Zhu, Xuhao, Gao, Yu, Wu, Yaozu, Zhang, Chuanyu, Wang, Ning, Zou, Yiren, Tan, Ziqi, Zhang, Aosai, Cui, Zhengyi, Shen, Fanhao, Zhong, Jiarun, and Li, Tingting

Subjects

QUANTUM entanglement, QUANTUM theory, QUANTUM gates, DIGITAL electronics, TIME perspective

Abstract

Greenberger-Horne-Zeilinger (GHZ) states, also known as two-component Schrödinger cats, play vital roles in the foundation of quantum physics and the potential quantum applications. Enlargement in size and coherent control of GHZ states are both crucial for harnessing entanglement in advanced computational tasks with practical advantages, which unfortunately pose tremendous challenges as GHZ states are vulnerable to noise. Here we propose a general strategy for creating, preserving, and manipulating large-scale GHZ entanglement, and demonstrate a series of experiments underlined by high-fidelity digital quantum circuits. For initialization, we employ a scalable protocol to create genuinely entangled GHZ states with up to 60 qubits, almost doubling the previous size record. For protection, we take a different perspective on discrete time crystals (DTCs), originally for exploring exotic nonequilibrium quantum matters, and embed a GHZ state into the eigenstates of a tailor-made cat scar DTC to extend its lifetime. For manipulation, we switch the DTC eigenstates with in-situ quantum gates to modify the effectiveness of the GHZ protection. Our findings establish a viable path towards coherent operations on large-scale entanglement, and further highlight superconducting processors as a promising platform to explore nonequilibrium quantum matters and emerging applications. The Greenberger-Horne-Zeilinger states are multipartite entangled quantum states with strong non-local entanglement. Here the authors generate large-scale states of this type with up to 60 qubits and show that discrete time crystals can effectively protect such fragile states. [ABSTRACT FROM AUTHOR]

Published

2024

16. High-Accuracy Entanglement Detection via a Convolutional Neural Network with Noise Resistance.

Author

Sun, Qian, Song, Yanyan, Liao, Zhichuan, and Jiang, Nan

Subjects

CONVOLUTIONAL neural networks, QUANTUM states, QUANTUM entanglement, QUANTUM computing, QUANTUM information science

Abstract

Quantum entanglement detection is one of the fundamental tasks in quantum information science. Conventional methods for quantum state tomography exhibit limitations in scalability as the number of qubits increases, leading to exponential growth in the number of unknown parameters and required measurements. Consequently, the accuracy enhancement achieved by these methods is constrained. In response to this challenge, we developed a tailored convolutional neural network (CNN) model capable of effectively detecting entanglement in two-qubit quantum states, achieving an accuracy exceeding 97.5%. Notably, even in the presence of noise, this model retains its robust performance, displaying resilience against a tolerable level of noise contamination. Furthermore, the inherent generalization power of CNNs allows our model, which was initially trained on a specific spectrum of quantum states, to extend its applicability to wider states, positioning it as an outstanding tool for the further application of machine learning in the field of quantum computing, opening up new pathways for solving entanglement detection problems in quantum information. [ABSTRACT FROM AUTHOR]

Published

2024

17. Entanglement witness and nonlocality in confidence of measurement from multipartite quantum state discrimination.

Author

Ha, Donghoon and Kim, Jeong San

Subjects

*QUANTUM states, *QUANTUM entanglement, *CONFIDENCE, *WITNESSES, *DEFINITIONS

Abstract

We consider multipartite quantum state discrimination and provide a specific relation between the properties of entanglement witness and quantum nonlocality inherent in the confidence of measurement. We first provide the definition of the confidence of measurement as well as its useful properties for various types of multipartite measurement. We show that globally-maximum confidence that cannot be achieved by local operations and classical communication strongly depends on the existence of a certain type of entanglement witness. We also provide conditions for an upper bound on maximum of locally-achievable confidence. Finally, we establish a method in terms of entanglement witness to construct quantum state ensembles with nonlocal maximum confidence. [ABSTRACT FROM AUTHOR]

Published

2024

18. Three-qubit Deutsch–Jozsa in measurement-based quantum computing.

Author

Schwetz, M. and Noack, R. M.

Subjects

*QUANTUM computing, *QUANTUM entanglement, *QUBITS, *ALGORITHMS

Abstract

Measurement-based quantum computing (MBQC), an alternate paradigm for formulating quantum algorithms, can lead to potentially more flexible and efficient implementations as well as to theoretical insights on the role of entanglement in a quantum algorithm. Using the graph-theoretical ZX-calculus, we describe and apply a general scheme for reformulating quantum circuits as MBQC implementations. After illustrating the method using the two-qubit Deutsch–Jozsa algorithm, we derive a ZX graph-diagram that encodes a general MBQC implementation for the three-qubit Deutsch–Jozsa algorithm. This graph describes an 11-qubit cluster state on which single-qubit measurements are used to execute the algorithm. Particular sets of choices of the axes for the measurements can be used to implement any realization of the oracle. In addition, we derive an equivalent lattice cluster state for the algorithm. [ABSTRACT FROM AUTHOR]

Published

2024

19. Hierarchical Controlled Joint Remote Implementation of the Partially Unknown Operations of m Qudits via m High-Dimensional Entangled States.

Author

Jing, Ruiheng, Lan, Qi, and Zhou, Ping

Subjects

*QUANTUM entanglement, *QUANTUM states, *INFORMATION sharing, *COOPERATION

Abstract

We present a protocol for the hierarchical controlled joint remote implementation of the partially unknown operations of m qudits belonging to some restricted sets by using m multiparticle high-dimensional entangled states as the quantum channel. All the senders share the information of the partially unknown operations and cooperate with each other to implement the partially unknown operations on the remote receiver's quantum system. The receivers are hierarchized in accordance with their abilities to reconstruct the desired state. The agents in the upper grade need only cooperate with one of the lower-grade agents, and the agents in the lower grade need the cooperation of all the other agents. The protocol has the advantage of having high channel capacity by using a high-dimensional entangle state as the quantum channel for the hierarchial controlled joint remote implementation of partially unknown quantum operations of m qudits. [ABSTRACT FROM AUTHOR]

Published

2024

20. The Non-Anthropocentric Other in Film: Towards a Spectral Ethics of Film.

Author

Reeh-Peters, Christine

Subjects

*QUANTUM entanglement, *CRITICAL thinking, *OTHER (Philosophy), *ETHICS, *POSTHUMANISM, *REALISM

Abstract

This article aims to add a further perspective to the discussion of the relationship between film and ethics. This perspective is important in today's context, as the omnipresence of digital and mobile audiovisual images in everyday life increasingly determines our thinking and behaviour. However, there is a lack of appropriate critical reflection and ethical understanding of these images and their ontology. This article proposes a machine ethics of film from a film-philosophical perspective. Such an ethics draws on critical posthumanism, namely on Karen Barad's "ethics of mattering", which explicitly relates to Emmanuel Levinas' philosophy of the Other and their death. Thereby, special attention is given to the ontological nexus of film and death, as well as to the idea of film's spectrality (drawing on, e.g., Derrida, Barthes, and Leutrat), a context that is discussed along with Barad's diffractive view on quantum entanglement. Following from the author's earlier approaches to Barad's agential realism in the context of film-philosophy and certain Heidegger-based arguments set out in earlier writings about film and death, this article introduces the figure of what is called the "machinic spectre of film". From here, the outline of a possible spectral ethics of film is considered by giving reasons for the exploration of further questions. [ABSTRACT FROM AUTHOR]

Published

2024

21. A study on thermal quantum resources and probabilistic teleportation in spin-1/2 Heisenberg XYZ+DM+KSEA model under variable Zeeman splitting.

Author

Ali, Asad, Al-Kuwari, Saif, Rahim, M. T., Ghominejad, Mehrdad, Ali, Hazrat, and Haddadi, Saeed

Subjects

*QUANTUM coherence, *HEISENBERG model, *QUANTUM entanglement, *QUANTUM information science, *INFORMATION & communication technologies

Abstract

We investigate the behavior of various measures of quantum coherence and quantum correlation in the spin-1/2 Heisenberg XYZ model with added Dzyaloshinsky-Moriya (DM) and Kaplan–Shekhtman–Entin-Wohlman–Aharony (KSEA) interactions at a thermal regime described by a Gibbs density operator. We aim to understand the restricted hierarchical classification of different quantum resources, where Bell nonlocality ⊆ quantum steering ⊆ quantum entanglement ⊆ quantum discord ⊆ quantum coherence. This hierarchy highlights the increasingly stringent conditions required as we move from quantum coherence to more specific quantum phenomena. In order to enhance quantum coherence, quantum correlation, and fidelity of teleportation, our analysis encompasses the effects of independently provided sinusoidal magnetic field control as well as DM and KSEA interactions on the considered system. The results reveal that enhancing the entanglement or quantum correlation of the channel does not always guarantee successful teleportation or even an improvement in teleportation fidelity. Thus, the relationship between teleportation fidelity and the channel's underlying quantum properties is intricate. Our study provides valuable insights into the complex interplay of quantum coherence and correlation hierarchy, offering potential applications for quantum communication and information processing technologies. [ABSTRACT FROM AUTHOR]

Published

2024

22. The Simplified Quantum Circuits for Implementing Quantum Teleportation.

Author

Zhang, Wen‐Xiu, Song, Guo‐Zhu, and Wei, Hai‐Rui

Subjects

*QUANTUM teleportation, *QUANTUM entanglement, *QUANTUM information science

Abstract

It is crucial to design quantum circuits as small as possible and as shallow as possible for quantum information processing tasks. Quantum circuits are designed with simplified gate‐count, cost, and depth for implementing quantum teleportation among various entangled channels. Here, the gate‐count/cost/depth of the Greenberger‐Horne‐Zeilinger‐based quantum teleportation is reduced from 10/6/8 to 9/4/6, the two‐qubit‐cluster‐based quantum teleportation is reduced from 9/4/5 to 6/3/5, the three‐qubit‐cluster‐based quantum teleportation is reduced from 12/6/7 to 8/4/5, the Brown‐based quantum teleportation is reduced from 25/15/17 to 18/8/7, the Borras‐based quantum teleportation is reduced from 36/25/20 to 15/8/11, and the entanglement‐swapping‐based quantum teleportation is reduced from 13/8/8 to 10/5/5. Note that, no feed‐forward recover operation is required in the simplified schemes. Moreover, the experimentally demonstrations on IBM quantum computer indicate that the simplified and compressed schemes can be realized with good fidelity. [ABSTRACT FROM AUTHOR]

Published

2024

23. Heralded and Complete Interconversion Between W State and Knill–Laflamme–Milburn State via State‐Selective Reflection with Robust Fidelity.

Author

Ren, Xue‐Mei, Guo, Jing, and Du, Fang‐Fang

Subjects

*QUANTUM entanglement, *INFORMATION technology, *PHOTON detectors, *QUANTUM communication, *QUANTUM gates

Abstract

The interconversion of different types of entangled states not only can realize the information transmission but also play a significant role in quantum information technologies, including increasing scalability and computational power, and reducing error rates. Here, two protocols for achieving a complete interconversion between W state and Knill–Laflamme–Milburn state assisted by the quantum dot (QD)‐cavity systems and common quantum control gates are proposed. In particular, the protocols employ a heralded approach strategically designed to predict potential failures and facilitate seamless interaction between the QD‐cavity system and photons with the help of a single photon detectors, enhancing experimental accessibility. Through extensive analyzes and evaluations of two protocols, the proposed two protocols achieve remarkable utilization rates of photons (i.e., unit in principle) and achieve near‐unit fidelities and high efficiencies in principle. [ABSTRACT FROM AUTHOR]

Published

2024

24. Influence of Fractional and Decay Parameters on the SU(1,1) Quantum System Interaction with Three‐Level Atom.

Author

Obada, A.‐S. F., Abu‐Shady, M., Khalil, E. M., and Habeba, H. F.

Subjects

*FRACTIONAL differential equations, *DIFFERENTIAL equations, *LIE algebras, *QUANTUM entanglement, *ENTROPY

Abstract

Through the generalized fractional derivative, it is studied how the decay term and the fractional parameter affect the quantum system, specifically the interaction between the SU(1,1) algebraic system and a three‐level atom. By transforming the differential equations into fractional differential equations, general fractional solutions are obtained. The influence of decay and fractional parameter on phenomena such as revival and collapse, entropy squeezing, purity, and concurrence are investigated. The results demonstrate how both decay and fractal parameter affect periods of collapse and revival. It is worth noting that the decay parameter shortens the collapse periods, while an increase in the fractional parameter leads to longer collapse periods. The decay parameter also reduces the degree of entanglement between the different components of the quantum system, while increasing the fractional parameter enhances the entanglement within the quantum system. Hence, it can be concluded that the fractional parameter plays a crucial role in the observed effects on the studied properties. [ABSTRACT FROM AUTHOR]

Published

2024

25. Operator dynamics and entanglement in space-time dual Hadamard lattices.

Author

Claeys, Pieter W and Lamacraft, Austen

Subjects

*QUANTUM theory, *QUANTUM entanglement, *HADAMARD matrices, *ISING model, *PARTITION functions

Abstract

Many-body quantum dynamics defined on a spatial lattice and in discrete time—either as stroboscopic Floquet systems or quantum circuits—has been an active area of research for several years. Being discrete in space and time, a natural question arises: when can such a model be viewed as evolving unitarily in space as well as in time? Models with this property, which sometimes goes by the name space-time duality, have been shown to have a number of interesting features related to entanglement growth and correlations. One natural way in which the property arises in the context of (brickwork) quantum circuits is by choosing dual unitary gates: two site operators that are unitary in both the space and time directions. We introduce a class of models with q states per site, defined on the square lattice by a complex partition function and paremeterized in terms of q × q Hadamard matrices, that have the property of space-time duality. These may interpreted as particular dual unitary circuits or stroboscopically evolving systems, and generalize the well studied self-dual kicked Ising model. We explore the operator dynamics in the case of Clifford circuits, making connections to Clifford cellular automata (Schlingemann et al 2008 J. Math. Phys. 49 112104) and in the q → ∞ limit to the classical spatiotemporal cat model of many body chaos (Gutkin et al 2021 Nonlinearity 34 2800). We establish integrability and the corresponding conserved charges for a large subfamily and show how the long-range entanglement protocol discussed in the recent paper (Lotkov et al 2022 Phys. Rev. B 105 144306) can be reinterpreted in purely graphical terms and directly applied here. [ABSTRACT FROM AUTHOR]

Published

2024

26. A privacy preserving quantum authentication scheme for secure data sharing in wireless body area networks.

Author

Prajapat, Sunil, Kumar, Pankaj, and Kumar, Sandeep

Subjects

*QUANTUM cryptography, *QUANTUM entanglement, *INTELLIGENT sensors, *MEDICAL personnel, *INTERNET of things, *BODY area networks

Abstract

The wireless body area network (WBAN) has emerged as a promising networking paradigm thanks to embedded systems, integrated circuit technologies, and wireless communications advancements. WBAN has the ability to send real-time biomedical data to remote medical personnel for clinical diagnostics through intelligent medical sensors in or around the patient's body. Moreover, WBANs have played an increasingly important role in modern medical systems over the past decade as part of the Internet of Things (IoT). In addition to their conveniences, WBANs present us with the data confidentiality challenge and protecting patient's privacy. The system requires a robust security mechanism to protect against threats because of the massive production of delay-sensitive data. This article presents a quantum key distribution (QKD) protocol-based authentication scheme for secure communication within WBAN infrastructure to prevent attacks and provide services free of security risks. To the best of our knowledge, we proposed a privacy preserving quantum authentication scheme for secure data sharing in WBANs to enhance security by encrypting medical data and safeguarding patients identities. Simulations conducted using Mathematica evaluate the proposed quantum authentication protocol both theoretically and practically, showing strong encryption performance against recent schemes. Results include computational cost of 6.832 ms, communication costs of 588 bits, and energy consumption of 432.98 μ J indicating the proposed quantum authentication protocol model exhibits superior reliability, feasibility, and efficiency in safeguarding WBAN data during transmission and storage. [ABSTRACT FROM AUTHOR]

Published

2024

27. Entanglement dynamics in κ-deformed spacetime.

Author

Liu, Xiaobao, Tian, Zehua, and Jing, Jiliang

Abstract

We treat two identical and mutually independent two-level atoms that are coupled to a quantum field as an open quantum system. The master equation that governs their evolution is derived by tracing over the degree of freedom of the field. With this, we compare the entanglement dynamics of the two atoms moving with different trajectories in κ-deformed and Minkowski spacetimes. Notably, when the environment-induced interatomic interaction does not exist, the entanglement dynamics of two static atoms in κ-deformed spacetime are reduced to that in Minkowski spacetime in the case that the spacetime deformation parameter κ is sufficiently large as theoretically predicted. However, if the atoms undergo relativistic motion, regardless of whether inertial or non-inertial, their entanglement dynamics in κ-deformed spacetime behave differently from that in Minkowski spacetime even when κ is large. We investigate various types of entanglement behavior, such as decay and generation, and discuss how different relativistic motions, such as uniform motion in a straight line and circular motion, amplify the differences in the entanglement dynamics between the κ-deformed and Minkowski spacetime cases. In addition, when the environment-induced interatomic interaction is considered, we find that it may also enhance the differences in the entanglement dynamics between these two spacetimes. Thus, in principle, one can tell whether she/he is in κ-deformed or Minkowski spacetime by checking the entanglement behavior between two atoms in certain circumstances. [ABSTRACT FROM AUTHOR]

Published

2024

28. The characteristic polynomial in calculation of exponential and elementary functions in Clifford algebras.

Author

Acus, Arturas and Dargys, Adolfas

Subjects

*FUNCTION algebras, *QUANTUM entanglement, *CLIFFORD algebras, *ORTHONORMAL basis, *EXPONENTIAL functions

Abstract

Formulas to calculate multivector exponentials in a basis‐free representation and orthonormal basis are presented for an arbitrary Clifford geometric algebra Clp,q$$ C{l}_{p,q} $$. The formulas are based on the analysis of roots of characteristic polynomial of a multivector. Elaborate examples how to use the formulas in practice are presented. The results are generalized to arbitrary functions of multivector and may be useful in the quantum circuits or in the problems ofanalysis of evolution of the entangled quantum states. [ABSTRACT FROM AUTHOR]

Published

2024

29. Protocol for certifying entanglement in surface spin systems using a scanning tunneling microscope.

Author

Broekhoven, Rik, Lee, Curie, Phark, Soo-hyon, Otte, Sander, and Wolf, Christoph

Subjects

SCANNING tunneling microscopy, ELECTRON paramagnetic resonance, SCANNING electron microscopes, QUANTUM entanglement, SCANNING systems

Abstract

Certifying quantum entanglement is a critical step toward realizing quantum-coherent applications. In this work, we show that entanglement of spins can be unambiguously evidenced in a scanning tunneling microscope with electron spin resonance by exploiting the fact that entangled states undergo a free time evolution with a distinct characteristic time constant that clearly distinguishes it from the time evolution of non-entangled states. By implementing a phase control scheme, the phase of this time evolution can be mapped back onto the population of one entangled spin, which can then be read out reliably using a weakly coupled sensor spin in the junction of the scanning tunneling microscope. We demonstrate through open quantum system simulations with currently available spin coherence times of T2 ≈ 300 ns, that a signal directly correlated with the degree of entanglement can be measured at temperatures of 100–400 mK accessible in sub-Kelvin scanning tunneling microscopes. [ABSTRACT FROM AUTHOR]

Published

2024

30. Optical Probe of Magnetic Ordering Structure and Spin‐Entangled Excitons in Mn‐Substituted NiPS3.

Author

Lee, Je‐Ho, Lee, Seungyeol, Choi, Youngsu, Gries, Lukas, Klingeler, Rüdiger, Raju, Kalaivanan, Ulaganathan, Rajesh Kumar, Sankar, Raman, Seong, Maeng‐Je, and Choi, Kwang‐Yong

Subjects

*MAGNETIC structure, *MAGNETIC measurements, *MAGNETIC fields, *MAGNETIC moments, *QUANTUM entanglement

Abstract

In van der Waals magnets, the interplay between magneto‐excitonic coupling and optical phenomena opens avenues for directly probing magnetic ordering structures, manipulating excitonic properties through magnetic fields, and exploring quantum entanglement between electronic and magnetic states. Notably, NiPS3 stands out for its capacity to host spin‐entangled excitons, where the excitonic states are intricately tied with the material's spin configuration. Herein, it is experimentally showcased that the spin‐entangled excitons can be utilized for detecting the magnetic easy axis in Ni1‐xMnxPS3 (x = 0–0.1). The end members of this series exhibit distinct magnetic ordering patterns and easy axes: zigzag ordering with magnetic moments aligned along the a‐axis for NiPS3 versus Néel ordering with the out‐of‐plane easy axis for MnPS3. By combining angle‐resolved exciton photoluminescence with magnetic susceptibility measurements, it is observed that the magnetic easy axis rotates away from the local spin chain direction with increasing Mn content. Moreover, through a comprehensive thermal and substitution study, it is demonstrated that the energy and lifetime of spin‐entangled excitons are governed by two spin‐flip processes and are drastically influenced by disparate electronic states. These findings not only provide optical means to map out magnetic ordering structures but also offer insights into decoherence processes in spin‐exciton entangled states. [ABSTRACT FROM AUTHOR]

Published

2024

31. Optical Probe of Magnetic Ordering Structure and Spin‐Entangled Excitons in Mn‐Substituted NiPS3.

Author

Lee, Je‐Ho, Lee, Seungyeol, Choi, Youngsu, Gries, Lukas, Klingeler, Rüdiger, Raju, Kalaivanan, Ulaganathan, Rajesh Kumar, Sankar, Raman, Seong, Maeng‐Je, and Choi, Kwang‐Yong

Subjects

MAGNETIC structure, MAGNETIC measurements, MAGNETIC fields, MAGNETIC moments, QUANTUM entanglement

Abstract

In van der Waals magnets, the interplay between magneto‐excitonic coupling and optical phenomena opens avenues for directly probing magnetic ordering structures, manipulating excitonic properties through magnetic fields, and exploring quantum entanglement between electronic and magnetic states. Notably, NiPS3 stands out for its capacity to host spin‐entangled excitons, where the excitonic states are intricately tied with the material's spin configuration. Herein, it is experimentally showcased that the spin‐entangled excitons can be utilized for detecting the magnetic easy axis in Ni1‐xMnxPS3 (x = 0–0.1). The end members of this series exhibit distinct magnetic ordering patterns and easy axes: zigzag ordering with magnetic moments aligned along the a‐axis for NiPS3 versus Néel ordering with the out‐of‐plane easy axis for MnPS3. By combining angle‐resolved exciton photoluminescence with magnetic susceptibility measurements, it is observed that the magnetic easy axis rotates away from the local spin chain direction with increasing Mn content. Moreover, through a comprehensive thermal and substitution study, it is demonstrated that the energy and lifetime of spin‐entangled excitons are governed by two spin‐flip processes and are drastically influenced by disparate electronic states. These findings not only provide optical means to map out magnetic ordering structures but also offer insights into decoherence processes in spin‐exciton entangled states. [ABSTRACT FROM AUTHOR]

Published

2024

32. Detecting the dimensionality of genuine multiparticle entanglement.

Author

Cobucci, Gabriele and Tavakoli, Armin

Subjects

*QUANTUM entanglement, *QUBITS, *NOISE

Abstract

Complex forms of quantum entanglement can arise in two qualitatively different ways: either between many qubits or between two particles with higher-than-qubit dimension. While both the many-qubit frontier and the high-dimension frontier are well established, state-of-the-art quantum technology is becoming increasingly able to create and manipulate entangled states that simultaneously feature many particles and high dimension. Here, we investigate generic states that can be considered both genuinely high-dimensional and genuine multiparticle entangled. We consider a natural quantity that characterizes this key property. To detect it, we develop three different classes of criteria. These enable us both to probe the ultimate noise tolerance of this form of entanglement and to make detection schemes using sparse or even minimal measurement resources. The approach provides a simple way of benchmarking entanglement dimensionality in the multiparticle regime and general, platform-independent, detection methods that readily apply to experimental use. [ABSTRACT FROM AUTHOR]

Published

2024

33. Characterization of non-Markovianity with maximal extractable qubit-reservoir entanglement.

Author

Han, Pei-Rong, Wu, Fan, Huang, Xin-Jie, Wu, Huai-Zhi, Yi, Wei, Wen, Jianming, Yang, Zhen-Biao, and Zheng, Shi-Biao

Subjects

*QUANTUM computing, *QUANTUM entanglement, *QUBITS, *COMPUTER simulation, *METROLOGY

Abstract

Understanding the dynamical behavior of a qubit in a reservoir is critical to applications in quantum technological protocols, ranging from quantum computation to quantum metrology. The effect of the reservoir depends on the reservoir's spectral structure as well as on the qubit-reservoir coupling strength. We here propose a measure for quantifying the non-Markovian effect of a reservoir with a Lorentzian spectrum, based on the maximum qubit-reservoir quantum entanglement that can be extracted. Numerical simulation shows that this entanglement exhibits a monotonous behavior in response to the variation of the coupling strength. We confirm the validity of this measure with an experiment where a superconducting qubit is controllably coupled to a lossy resonator, which acts as a reservoir for the qubit. The experimental results illustrate that the maximal extractable entanglement is progressively increased with the strengthening of non-Markovianity. [ABSTRACT FROM AUTHOR]

Published

2024

34. Geometric methods in quantum information and entanglement variational principle.

Author

Iannotti, Daniele and Hamma, Alioscia

Subjects

*QUANTUM information theory, *QUANTUM entanglement, *QUANTUM computing, *QUANTUM theory, *QUANTUM mechanics

Abstract

Geometrical methods in quantum information are very promising for both providing technical tools and intuition into difficult control or optimization problems. Moreover, they are of fundamental importance in connecting pure geometrical theories, like GR, to quantum mechanics, like in the AdS/CFT correspondence. In this paper, we first make a survey of the most important settings in which geometrical methods have proven useful to quantum information theory. Then we lay down a geometric theory of entanglement by a principle of action, discussing a simple example with two qubits and consequences for a quantum theory of space-time. [ABSTRACT FROM AUTHOR]

Published

2024

35. Demonstration of quantum network protocols over a 14-km urban fiber link.

Author

Kucera, Stephan, Haen, Christian, Arenskötter, Elena, Bauer, Tobias, Meiers, Jonas, Schäfer, Marlon, Boland, Ross, Yahyapour, Milad, Lessing, Maurice, Holzwarth, Ronald, Becher, Christoph, and Eschner, Jürgen

Subjects

QUANTUM teleportation, QUANTUM entanglement, FREQUENCY changers, PHOTON pairs, QUANTUM states

Abstract

We report on the implementation of quantum entanglement distribution and quantum state teleportation over a 14.4 km urban dark-fiber link, which is partially underground, partially overhead, and patched in several stations. We characterize the link for its use as a quantum channel and realize its active polarization stabilization. Using a type-II cavity-enhanced SPDC photon pair source, a 40Ca+ single-ion quantum memory, and quantum frequency conversion to the telecom C-band, we demonstrate photon-photon entanglement, ion-photon entanglement, and teleportation of a qubit state from the ion onto a remote telecom photon, all realized over the urban fiber link. [ABSTRACT FROM AUTHOR]

Published

2024

36. High-Q cavity interface for color centers in thin film diamond.

Author

Ding, Sophie W., Haas, Michael, Guo, Xinghan, Kuruma, Kazuhiro, Jin, Chang, Li, Zixi, Awschalom, David D., Delegan, Nazar, Heremans, F. Joseph, High, Alexander A., and Loncar, Marko

Subjects

DIAMOND thin films, INFORMATION technology, PHOTONIC crystals, QUALITY factor, QUANTUM entanglement, QUANTUM computers

Abstract

Quantum information technology offers the potential to realize unprecedented computational resources via secure channels distributing entanglement between quantum computers. Diamond, as a host to optically-accessible spin qubits, is a leading platform to realize quantum memory nodes needed to extend such quantum links. Photonic crystal (PhC) cavities enhance light-matter interaction and are essential for an efficient interface between spins and photons that are used to store and communicate quantum information respectively. Here, we demonstrate one- and two-dimensional PhC cavities fabricated in thin-film diamonds, featuring quality factors (Q) of 1.8 × 105 and 1.6 × 105, respectively, the highest Qs for visible PhC cavities realized in any material. Importantly, our fabrication process is simple and high-yield, based on conventional planar fabrication techniques, in contrast to the previous with complex undercut processes. We also demonstrate fiber-coupled 1D PhC cavities with high photon extraction efficiency, and optical coupling between a single SiV center and such a cavity at 4 K achieving a Purcell factor of 18. The demonstrated photonic platform may fundamentally improve the performance and scalability of quantum nodes and expedite the development of related technologies. Improving the performance and scalability of quantum nodes is of paramount importance to expedite the development of quantum technologies. Here the authors demonstrate fiber-coupled 1D PhC cavities with high photon extraction efficiency, and optical coupling between a single SiV center and such a cavity. [ABSTRACT FROM AUTHOR]

Published

2024

37. Optical vortex ladder via Sisyphus pumping of Pseudospin.

Author

Lei, Sihong, Xia, Shiqi, Song, Daohong, Xu, Jingjun, Buljan, Hrvoje, and Chen, Zhigang

Subjects

OPTICAL vortices, ANGULAR momentum (Mechanics), GEOMETRIC quantum phases, QUANTUM entanglement, EXCITATION spectrum

Abstract

Robust high-order optical vortices are much in demand for applications in optical manipulation, optical communications, quantum entanglement and quantum computing. However, in numerous experimental settings, a controlled generation of optical vortices with arbitrary orbital angular momentum remains a challenge. Here, we present a concept of "optical vortex ladder" for the stepwise generation of optical vortices through Sisyphus pumping of pseudospin modes in photonic graphene. The ladder is applicable in various lattices with Dirac-like structures. Instead of conical diffraction and incomplete pseudospin conversion under conventional Gaussian beam excitations, the vortices produced in the ladder arise from non-trivial topology and feature diffraction-free Bessel profiles, thanks to the refined excitation of the ring spectrum around the Dirac cones. By employing a periodic "kick" to the photonic graphene, effectively inducing the Sisyphus pumping, the ladder enables tunable generation of optical vortices of any order even when the initial excitation does not involve any orbital angular momentum. The optical vortex ladder stands out as an intriguing non-Hermitian dynamical system, and, among other possibilities, opens a pathway for applications of topological singularities in beam shaping and wavefront engineering. Controlled generation of OAM modes holds promise for applications in classical and quantum communication networks. Here the authors develop an optical vortex ladder in which an input beam transforms into vortices mediated by the Berry phase winding around topological singularities at the Dirac points. [ABSTRACT FROM AUTHOR]

Published

2024

38. Fully controllable time-bin entangled states distributed over 100-km single-mode fibers.

Author

Kim, Jinwoo, Park, Jiho, Kim, Hong-Seok, Kim, Guhwan, Kim, Jin Tae, Park, Jaegyu, Moon, Kiwon, Kwak, Seung-Chan, Kim, Min-su, and Ju, Jung Jin

Subjects

QUANTUM entanglement, BELL'S theorem, QUANTUM states, SINGLE-mode optical fibers, PHOTON pairs, QUANTUM cryptography, QUANTUM networks (Optics)

Abstract

Quantum networks that can perform user-defined protocols beyond quantum key distribution will require fully controllable entangled quantum states. To expand the available space of generated time-bin entangled states, we demonstrate a time-bin entangled photon source that produces qubit states | ψ 〉 = α | 00 〉 + β | 11 〉 with fully controllable phase and amplitudes. Eight different two-photon states have been selected and prepared from arbitrary states on the reduced two-qubit Bloch sphere. The photon pairs encoded in the time-bin scheme were generated at 2.4 MHz with a visibility of V = 0.9475 ± 0.0016 , with a violation of the CHSH Bell's inequality by 197 standard deviations. After entanglement distribution over 100 km of single-mode fibers, we obtained a visibility of V = 0.9541 ± 0.0113 with a violation of the CHSH Bell's inequality by 6 standard deviations. The prepared states had an average fidelity of 0.9540 ± 0.0016 at the source and an average fidelity of 0.9353 − 0.0209 + 0.0100 after entanglement distribution, which shows that the quantum states generated by our time-bin entangled photon source can be fully controlled potentially to a level applicable to long-distance advanced quantum network systems. [ABSTRACT FROM AUTHOR]

Published

2024

39. Entangled Photon‐Magnon Bundle Emission.

Author

Bin, Qian, Qiu, Qing‐Yang, Wu, Ying, and Lü, Xin‐You

Subjects

*DEGREES of freedom, *HYBRID systems, *QUANTUM states, *QUANTUM entanglement, *QUANTUM electrodynamics

Abstract

Multiquanta correlation between n$n$ quanta of a completely different nature is an important resource for hybrid quantum information processing since it allows quantum states of matters to be manipulated by other degrees of freedom. Here, a method is proposed to realize the hybrid bundle emission of strongly correlated single photons and magnons. The optically driven multiquanta resonance leads to the super‐Rabi oscillation between the vacuum state and photon‐magnon state, which, combined with system dissipations, generates photon‐magnon bundle emission. Interestingly, accompanied by this bundle emission, the photon‐magnon entanglement and fully inseparable photon‐magnon‐qubit tripartite entanglement are achieved. This allows the proposed hybrid system to serve as a quantum emitter of entangled photon‐magnon bundle, which is useful for building hybrid quantum network and the engineering of new types of quantum devices. [ABSTRACT FROM AUTHOR]

Published

2024

40. Entanglement Dynamics of a Two-Qutrits System Coupled to a Spin Chain.

Author

Moosavi Khansari, S. M. and Hasanvand, F. Kazemi

Subjects

*QUANTUM phase transitions, *SPIN crossover, *SYSTEM dynamics, *QUANTUM entanglement

Abstract

In this paper, we investigate the entanglement dynamics of a two qutrits system interacting with a spin environment. Using negativity as the entanglement measure, we study the entanglement dynamics of the system. The calculations show that in cases where the entanglement decays quickly, the environment will have a quantum phase transition. [ABSTRACT FROM AUTHOR]

Published

2024

41. Entanglement in Lifshitz fermion theories.

Author

Vasli, Mohammad Javad, Babaei Velni, Komeil, Mohammadi Mozaffar, M. Reza, and Mollabashi, Ali

Subjects

*LATTICE field theory, *QUANTUM field theory, *QUANTUM entanglement, *QUANTUM theory, *CONFORMAL field theory

Abstract

We study the static entanglement structure in (1+1)-dimensional free Dirac-fermion theory with Lifshitz symmetry and arbitrary integer dynamical critical exponent. This model is different from the one introduced in [Hartmann et al., SciPost Phys.11 (2021) 031] due to a proper treatment of the square Laplace operator. Dirac fermion Lifshitz theory is local as opposed to its scalar counterpart which strongly affects its entanglement structure. We show that there is quantum entanglement across arbitrary subregions in various pure (including the vacuum) and mixed states of this theory for arbitrary integer values of the dynamical critical exponent. Our numerical investigations show that quantum entanglement in this theory is tightly bounded from above. Such a bound and other physical properties of quantum entanglement are carefully explained from the correlation structure in these theories. A generalization to (2+1)-dimensions where the entanglement structure is seriously different is addressed. [ABSTRACT FROM AUTHOR]

Published

2024

42. Secure sharing of one-sided quantum randomness using entangled coherent states.

Author

Rostom, Aiham and Il'ichov, Leonid

Subjects

*QUANTUM entanglement, *COHERENT states, *QUANTUM communication, *COMMUNICATION policy, *ACCESS to information

Abstract

In quantum key distribution, secret randomness is extracted quantum-mechanically from two-sided local random choices of measurement bases. Subsequently, the public announcement of basis information is necessary to perform a security check and establish the key. Recent studies have demonstrated that, provided the basis information is accessible, even adversaries with limited computational power can readily compromise the key through side-channel attacks. In this paper, we propose a quantum key distribution scheme using entangled coherent states. The present scheme is based on the secure exchange of one-sided quantum randomness, thus obviating the necessity for basis-information announcement. This effectively closes the security loophole associated with access to basis information during side-channel attacks. The security of the present protocol has been verified against both local and global quantum attacks. Furthermore, the impact of high photon loss and an authentication scheme has been discussed. [ABSTRACT FROM AUTHOR]

Published

2024

43. Emerging quantum ridges and dynamic patterns in diverse field landscapes.

Author

Rahman, Atta ur and Qiao, Cong-Feng

Subjects

*EXCITED state energies, *QUANTUM theory, *QUANTUM entanglement, *GROUND state energy, *EXCITED states

Abstract

We address the influence of magnetic fields with varying shapes and characters on the dynamics of open quantum systems. A configuration comprising magnetic pulses, thermal effects, gravity, and a non-locally correlated channel is studied. In a quantum magnetic system, we demonstrate how exponential and periodic magnetic pulses promote the formation of quantum and classical ridges against different ground and excited state energies. In particular, the detailed feasibility of the joint application of exponential and periodic magnetic pulses with correlated channels for the dynamics of quantum features and the associated experimental design for our studied theoretical model is elaborated. Finally, we find that the periodic magnetic functions are more powerful to induce non-Markovianity compared to the quantum channels, while the Markovian ones generate more stable and higher-entangled states. For the periodic magnetic fields, strong quantum entanglement ridges are witnessed against the very low ground and excited state amplitudes in the system. [ABSTRACT FROM AUTHOR]

Published

2024

44. Hybrid multi-directional quantum communication protocol.

Author

Sisodia, Mitali, Mandal, Manoj Kumar, and Choudhury, Binayak S.

Subjects

*QUANTUM teleportation, *QUANTUM entanglement, *QUANTUM communication, *NOISE control, *DEGREES of freedom

Abstract

The way a new type of state called a hybrid state, which contains more than one degree of freedom, is used in many practical applications of quantum communication tasks with lesser amount of resources. Similarly, our aim is here to perform multi-quantum communication tasks in a protocol to approach quantum information in multi-purpose and multi-directional. We propose a hybrid multi-directional six-party scheme of implementing quantum teleportation and joint remote state preparation under the supervision of a controller via a multi-qubit entangled state as a quantum channel with 100 % success probability. Moreover, we analytically derive the average fidelities of this hybrid scheme under the amplitude-damping and the phase-damping noise. [ABSTRACT FROM AUTHOR]

Published

2024

45. Entanglement-enhanced quantum metrology: From standard quantum limit to Heisenberg limit.

Author

Huang, Jiahao, Zhuang, Min, and Lee, Chaohong

Subjects

*QUANTUM entanglement, *QUANTUM states, *PHYSICAL constants, *ION traps, *METROLOGY

Abstract

Entanglement-enhanced quantum metrology explores the utilization of quantum entanglement to enhance measurement precision. When particles in a probe are prepared into a suitable quantum entangled state, they may collectively accumulate information about the physical quantity to be measured, leading to an improvement in measurement precision beyond the standard quantum limit and approaching the Heisenberg limit. The rapid advancement of techniques for quantum manipulation and detection has enabled the generation, manipulation, and detection of multi-particle entangled states in synthetic quantum systems such as cold atoms and trapped ions. This article aims to review and illustrate the fundamental principles and experimental progresses that demonstrate multi-particle entanglement for quantum metrology, as well as discuss the potential applications of entanglement-enhanced quantum sensors. [ABSTRACT FROM AUTHOR]

Published

2024

46. Resonant Coulomb interaction of excitonic and charge qubits on quantum dots.

Author

Tsukanov, A. V.

Subjects

*QUANTUM computing, *QUANTUM dots, *QUANTUM entanglement, *QUBITS, *CONCORD

Abstract

The paper considers an algorithm for entangling the states of an exciton qubit on a single quantum dot and a charge qubit on a double quantum dot. The possibility of performing a conditional two-qubit CNOT operation using laser transitions and the Förster effect is analyzed. Estimates of the system parameters are given for which this operation is implemented with a probability close to unity. [ABSTRACT FROM AUTHOR]

Published

2024

47. Robustness of Entanglement for Dicke-W and Greenberger-Horne-Zeilinger Mixed States.

Author

Zhu, Ling-Hui, Zhu, Zhen, Lv, Guo-Lin, Ye, Chong-Qiang, and Chen, Xiao-Yu

Subjects

*QUANTUM entanglement, *QUANTUM states, *QUANTUM mechanics, *PROBABILITY theory, *WITNESSES

Abstract

Quantum entanglement is a fundamental characteristic of quantum mechanics, and understanding the robustness of entanglement across different mixed states is crucial for comprehending the entanglement properties of general quantum states. In this paper, the robustness of entanglement of Dicke–W and Greenberger–Horne–Zeilinger (GHZ) mixed states under different mixing ratios is calculated using the entanglement witness method. The robustnesses of entanglement of Dicke–W and GHZ mixed states are different when the probability ratio of Dicke to W is greater than 3 2 and less than 3 2 . For the probability of Dicke and W states greater than or equal to 3 2 , we study the robustness of entanglement of Dicke and GHZ mixed states and analyze and calculate their upper and lower bounds. For the probability of Dicke and W states less than 3 2 , we take the equal probability ratio of Dicke and W states as an example and calculate and analyze the upper and lower bounds of their robustness of entanglement in detail. [ABSTRACT FROM AUTHOR]

Published

2024

48. Quantum State Combinatorics.

Author

Scholes, Gregory D.

Subjects

*QUANTUM states, *QUANTUM entanglement, *RANDOM graphs, *COMBINATORICS

Abstract

This paper concerns the analysis of large quantum states. It is a notoriously difficult problem to quantify separability of quantum states, and for large quantum states, it is unfeasible. Here we posit that when quantum states are large, we can deduce reasonable expectations for the complex structure of non-classical multipartite correlations with surprisingly little information about the state. We show, with pegagogical examples, how known results from combinatorics can be used to reveal the expected structure of various correlations hidden in the ensemble described by a state. [ABSTRACT FROM AUTHOR]

Published

2024

49. Generalized uncertainty principle for entangled states of two identical particles.

Author

Lemos Filho, K. C., Dilem, B. B., Francisco, R. O., Fabris, J. C., and Nogueira, J. A.

Subjects

*QUANTUM entanglement, *PARADOX

Abstract

In this work we determine the consequences of the quantum entanglement of a system of two identical particles when a generalized uncertainty principle (GUP) is considered. GUPs are usually associated with the existence of a minimal length. We focus on the main GUPs (KMM, ADV, Pedram and Nouicer) and then we determine the minimal uncertainties in position induced by those modified GUPs. Our results point out that the minimal uncertainty is reduced by half of its usual value independently of the GUP employed. This implies that the minimal length is also reduced by half. On the other hand, it is generally expected that the minimal length must not depend on physical system. We overcome this apparent paradox by realizing that the entangled system is composed by two particles so that an effective parameter related to the minimal length must be employed. [ABSTRACT FROM AUTHOR]

Published

2024

50. Improving the Stationary Entanglement of a Laguerre–Gaussian Cavity Mode with a Rotating Mirror via Nonlinear Cross-Kerr Interactions and Parametric Interactions.

Author

Lai, Guilin, Huang, Sumei, Deng, Li, and Chen, Aixi

Subjects

*OPTICAL parametric amplifiers, *QUANTUM entanglement, *NONLINEAR systems, *MIRRORS, *LASERS

Abstract

Quantum entanglement is essential in performing many quantum information tasks. Here, we theoretically investigate the stationary entanglement between a Laguerre–Gaussian (LG) cavity field and a rotating end mirror in an LG-cavity optorotational system with a nonlinear cross-Kerr (CK) interaction and a degenerate optical parametric amplifier (OPA). We calculate the logarithmic negativity of the system to quantify the stationary entanglement. We examine the influence of various system parameters such as the cavity detuning, the strength of the nonlinear CK interaction, the parametric gain and phase of the OPA, the power of the input Gaussian laser, the topological charge of the LG-cavity field, the mass of the rotating end mirror, and the ambient temperature on the stationary entanglement. Under the combined effect of the nonlinear CK interaction and the OPA, we find that the stationary entanglement can be substantially enhanced at lower Gaussian laser powers, smaller topological charges of the LG-cavity field, and larger masses of the rotating end mirror. We show that the combination of the nonlinear CK interaction and the OPA can make the stationary entanglement more robust against the ambient temperature. [ABSTRACT FROM AUTHOR]

Published

2024