Your search keyword '"Entanglement generation"' showing total 203 results

1. Shortcut to multipartite entanglement generation: A graph approach to boson subtractions

Author

Chin, Seungbeom, Kim, Yong-Su, and Karczewski, Marcin

Published

2024

2. Entanglement generation in a quantum network at distance-independent rate

Author

Patil, Ashlesha, Pant, Mihir, Englund, Dirk, Towsley, Don, and Guha, Saikat

Published

2022

3. Effective routing design for remote entanglement generation on quantum networks

Author

Li, Changhao, Li, Tianyi, Liu, Yi-Xiang, and Cappellaro, Paola

Published

2021

4. High-performance quantum entanglement generation via cascaded second-order nonlinear processes

Author

Zichang Zhang, Chenzhi Yuan, Si Shen, Hao Yu, Ruiming Zhang, Heqing Wang, Hao Li, You Wang, Guangwei Deng, Zhiming Wang, Lixing You, Zhen Wang, Haizhi Song, Guangcan Guo, and Qiang Zhou

Subjects

Physics, QC1-999, Electronic computers. Computer science, QA75.5-76.95

Abstract

Abstract In this paper, we demonstrate the generation of high-performance entangled photon-pairs in different degrees of freedom from a single piece of fiber pigtailed periodically poled LiNbO3 (PPLN) waveguide. We utilize cascaded second-order nonlinear optical processes, i.e., second-harmonic generation (SHG) and spontaneous parametric downconversion (SPDC), to generate photon-pairs. Previously, the performance of the photon-pairs is contaminated by Raman noise photons. Here by fiber-integrating the PPLN waveguide with noise-rejecting filters, we obtain a coincidence-to-accidental ratio (CAR) higher than 52,600 with photon-pair generation and detection rate of 52.36 kHz and 3.51 kHz, respectively. Energy-time, frequency-bin, and time-bin entanglement is prepared by coherently superposing correlated two-photon states in these degrees of freedom, respectively. The energy-time entangled two-photon states achieve the maximum value of CHSH-Bell inequality of S = 2.71 ± 0.02 with two-photon interference visibility of 95.74 ± 0.86%. The frequency-bin entangled two-photon states achieve fidelity of 97.56 ± 1.79% with a spatial quantum beating visibility of 96.85 ± 2.46%. The time-bin entangled two-photon states achieve the maximum value of CHSH-Bell inequality of S = 2.60 ± 0.04 and quantum tomographic fidelity of 89.07 ± 4.35%. Our results provide a potential candidate for the quantum light source in quantum photonics.

Published

2021

5. Deterministic bidirectional communication and remote entanglement generation between superconducting qubits

Author

Leung, N., Lu, Y., Chakram, S., Naik, R. K., Earnest, N., Ma, R., Jacobs, K., Cleland, A. N., and Schuster, D. I.

Published

2019

6. High-performance quantum entanglement generation via cascaded second-order nonlinear processes

Author

Zhang, Zichang, primary, Yuan, Chenzhi, additional, Shen, Si, additional, Yu, Hao, additional, Zhang, Ruiming, additional, Wang, Heqing, additional, Li, Hao, additional, Wang, You, additional, Deng, Guangwei, additional, Wang, Zhiming, additional, You, Lixing, additional, Wang, Zhen, additional, Song, Haizhi, additional, Guo, Guangcan, additional, and Zhou, Qiang, additional

Published

2021

7. Long-range data transmission in a fault-tolerant quantum bus architecture.

Author

Choe, Shin Ho and König, Robert

Subjects

QUANTUM computing, QUBITS, DATA transmission systems, NOISE, SAWLOGS

Abstract

We propose a fault-tolerant scheme for generating long-range entanglement at the ends of a rectangular array of qubits of length R with a square cross-section of m = O ( log 2 R) qubits. It is realized by a constant-depth circuit producing a constant-fidelity Bell-pair (independent of R) for local stochastic noise of strength below an experimentally realistic threshold. The scheme can be viewed as a quantum bus in a quantum computing architecture where qubits are arranged on a rectangular 3D grid, and all operations are between neighboring qubits. Alternatively, it can be seen as a quantum repeater protocol along a line, with neighboring repeaters placed at a short distance to allow constant-fidelity nearest-neighbor operations. To show our protocol uses a number of qubits close to optimal, we show that any noise-resilient distance-R entanglement generation scheme realized by a constant-depth circuit needs at least m = Ω (log R) qubits per repeater. [ABSTRACT FROM AUTHOR]

Published

2024

8. High-fidelity four-photon GHZ states on chip.

Author

Pont, Mathias, Corrielli, Giacomo, Fyrillas, Andreas, Agresti, Iris, Carvacho, Gonzalo, Maring, Nicolas, Emeriau, Pierre-Emmanuel, Ceccarelli, Francesco, Albiero, Ricardo, Dias Ferreira, Paulo Henrique, Somaschi, Niccolo, Senellart, Jean, Sagnes, Isabelle, Morassi, Martina, Lemaître, Aristide, Senellart, Pascale, Sciarrino, Fabio, Liscidini, Marco, Belabas, Nadia, and Osellame, Roberto

Subjects

DENSITY matrices, QUANTUM communication, QUANTUM states, STANDARD deviations, QUANTUM dots, TOMOGRAPHY, SCALABILITY

Abstract

Mutually entangled multi-photon states are at the heart of all-optical quantum technologies. While impressive progresses have been reported in the generation of such quantum light states using free space apparatus, high-fidelity high-rate on-chip entanglement generation is crucial for future scalability. In this work, we use a bright quantum-dot based single-photon source to demonstrate the high fidelity generation of 4-photon Greenberg-Horne-Zeilinger (GHZ) states with a low-loss reconfigurable glass photonic circuit. We reconstruct the density matrix of the generated states using full quantum-state tomography reaching an experimental fidelity to the target state of F GHZ 4 = (86.0 ± 0.4) % , and a purity of P GHZ 4 = (76.3 ± 0.6) % . The entanglement of the generated states is certified with a semi device-independent approach through the violation of a Bell-like inequality by more than 39 standard deviations. Finally, we carry out a four-partite quantum secret sharing protocol on-chip where a regulator shares with three interlocutors a sifted key with up to 1978 bits, achieving a qubit-error rate of 10.87%. These results establish that the quantum-dot technology combined with glass photonic circuitry offers a viable path for entanglement generation and distribution. [ABSTRACT FROM AUTHOR]

Published

2024

9. Requirements for a processing-node quantum repeater on a real-world fiber grid.

Author

Avis, Guus, Ferreira da Silva, Francisco, Coopmans, Tim, Dahlberg, Axel, Jirovská, Hana, Maier, David, Rabbie, Julian, Torres-Knoop, Ariana, and Wehner, Stephanie

Subjects

QUANTUM computing, ION traps, GENETIC algorithms, CITIES & towns, PROBLEM solving

Abstract

We numerically study the distribution of entanglement between the Dutch cities of Delft and Eindhoven realized with a processing-node quantum repeater and determine minimal hardware requirements for verifiable blind quantum computation using color centers and trapped ions. Our results are obtained considering restrictions imposed by a real-world fiber grid and using detailed hardware-specific models. By comparing our results to those we would obtain in idealized settings, we show that simplifications lead to a distorted picture of hardware demands, particularly on memory coherence and photon collection. We develop general machinery suitable for studying arbitrary processing-node repeater chains using NetSquid, a discrete-event simulator for quantum networks. This enables us to include time-dependent noise models and simulate repeater protocols with cut-offs, including the required classical control communication. We find minimal hardware requirements by solving an optimization problem using genetic algorithms on a high-performance-computing cluster. Our work provides guidance for further experimental progress, and showcases limitations of studying quantum-repeater requirements in idealized situations. [ABSTRACT FROM AUTHOR]

Published

2023

10. Spatially correlated classical and quantum noise in driven qubits.

Author

Zou, Ji, Bosco, Stefano, and Loss, Daniel

Subjects

QUANTUM noise, QUBITS, PINK noise, NOISE, LOW temperatures, HIGH temperatures

Abstract

Correlated noise across multiple qubits poses a significant challenge for achieving scalable and fault-tolerant quantum processors. Despite recent experimental efforts to quantify this noise in various qubit architectures, a comprehensive understanding of its role in qubit dynamics remains elusive. Here, we present an analytical study of the dynamics of driven qubits under spatially correlated noise, including both Markovian and non-Markovian noise. Surprisingly, we find that by operating the qubit system at low temperatures, where correlated quantum noise plays an important role, significant long-lived entanglement between qubits can be generated. Importantly, this generation process can be controlled on-demand by turning the qubit driving on and off. On the other hand, we demonstrate that by operating the system at a higher temperature, the crosstalk between qubits induced by the correlated noise is unexpectedly suppressed. We finally reveal the impact of spatio-temporally correlated 1/f noise on the decoherence rate, and how its temporal correlations restore lost entanglement. Our findings provide critical insights into not only suppressing crosstalk between qubits caused by correlated noise but also in effectively leveraging such noise as a beneficial resource for controlled entanglement generation. [ABSTRACT FROM AUTHOR]

Published

2024

11. Deterministic photon source interfaced with a programmable silicon-nitride integrated circuit.

Author

Wang, Ying, Faurby, Carlos F. D., Ruf, Fabian, Sund, Patrik I., Nielsen, Kasper, Volet, Nicolas, Heck, Martijn J. R., Bart, Nikolai, Wieck, Andreas D., Ludwig, Arne, Midolo, Leonardo, Paesani, Stefano, and Lodahl, Peter

Subjects

INTEGRATED circuits, PHOTONS, QUANTUM dots

Abstract

We develop a quantum photonic platform that interconnects a high-quality quantum dot single-photon source and a low-loss photonic integrated circuit made in silicon nitride. The platform is characterized and programmed to demonstrate various multiphoton applications, including bosonic suppression laws and photonic entanglement generation. The results show a promising technological route forward to scale-up photonic quantum hardware. [ABSTRACT FROM AUTHOR]

Published

2023

12. Quantum networks with neutral atom processing nodes.

Author

Covey, Jacob P., Weinfurter, Harald, and Bernien, Hannes

Subjects

QUANTUM information science, QUANTUM computing, SENSOR networks, QUANTUM communication, MESH networks, QUANTUM computers

Abstract

Quantum networks providing shared entanglement over a mesh of quantum nodes will revolutionize the field of quantum information science by offering novel applications in quantum computation, enhanced precision in networks of sensors and clocks, and efficient quantum communication over large distances. Recent experimental progress with individual neutral atoms demonstrates a high potential for implementing the crucial components of such networks. We highlight latest developments and near-term prospects on how arrays of individually controlled neutral atoms are suited for both efficient remote entanglement generation and large-scale quantum information processing, thereby providing the necessary features for sharing high-fidelity and error-corrected multi-qubit entangled states between the nodes. We describe both the functionality requirements and several examples for advanced, large-scale quantum networks composed of neutral atom processing nodes. [ABSTRACT FROM AUTHOR]

Published

2023

13. High-efficiency microwave-optical quantum transduction based on a cavity electro-optic superconducting system with long coherence time.

Author

Wang, Changqing, Gonin, Ivan, Grassellino, Anna, Kazakov, Sergey, Romanenko, Alexander, Yakovlev, Vyacheslav P., and Zorzetti, Silvia

Subjects

ELECTRO-optical effects, GENETIC transduction, OPTICAL resonators, OPTICAL losses, MICROWAVES, PHOTONS

Abstract

Frequency conversion between microwave and optical photons is a key enabling technology to create links between superconducting quantum processors and to realize distributed quantum networks. We propose a microwave-optical transduction platform based on long-coherence time superconducting radio-frequency (SRF) cavities coupled to electro-optic optical cavities to mitigate the loss mechanisms that limit the attainment of high conversion efficiency. We optimize the microwave-optical field overlap and optical coupling losses in the design while achieving long microwave and optical photon lifetime at milli-Kelvin temperatures. This represents a significant enhancement of the transduction efficiency up to 50% under incoming pump power of 140 μW, which allows the conversion of few-photon quantum signals. Furthermore, this scheme exhibits high resolution for optically reading out the dispersive shift induced by a superconducting transmon qubit coupled to the SRF cavity. We also show that low microwave losses enhance the fidelity of heralded entanglement generation between two remote quantum systems. Finally, high precision in quantum sensing can be reached below the standard quantum limit. [ABSTRACT FROM AUTHOR]

Published

2022

14. Experimental demonstration of entanglement delivery using a quantum network stack.

Author

Pompili, M., Delle Donne, C., te Raa, I., van der Vecht, B., Skrzypczyk, M., Ferreira, G., de Kluijver, L., Stolk, A. J., Hermans, S. L. N., Pawełczak, P., Kozlowski, W., Hanson, R., and Wehner, S.

Subjects

QUANTUM communication, TELECOMMUNICATION systems, ROBUST control, PHYSICS experiments, QUANTUM theory, DELIVERY of goods, QUANTUM computers

Abstract

Scaling current quantum communication demonstrations to a large-scale quantum network will require not only advancements in quantum hardware capabilities, but also robust control of such devices to bridge the gap in user demand. Moreover, the abstraction of tasks and services offered by the quantum network should enable platform-independent applications to be executed without the knowledge of the underlying physical implementation. Here we experimentally demonstrate, using remote solid-state quantum network nodes, a link layer, and a physical layer protocol for entanglement-based quantum networks. The link layer abstracts the physical-layer entanglement attempts into a robust, platform-independent entanglement delivery service. The system is used to run full state tomography of the delivered entangled states, as well as preparation of a remote qubit state on a server by its client. Our results mark a clear transition from physics experiments to quantum communication systems, which will enable the development and testing of components of future quantum networks. [ABSTRACT FROM AUTHOR]

Published

2022

15. A scheme to create and verify scalable entanglement in optical lattice.

Author

Zhou, You, Xiao, Bo, Li, Meng-Da, Zhao, Qi, Yuan, Zhen-Sheng, Ma, Xiongfeng, and Pan, Jian-Wei

Subjects

OPTICAL lattices, QUANTUM information science, OPTICAL information processing

Abstract

To achieve scalable quantum information processing, great efforts have been devoted to the creation of large-scale entangled states in various physical systems. Ultracold atom in optical lattice is considered as one of the promising platforms due to its feasible initialization and parallel manipulation. In this work, we propose an efficient scheme to generate and characterize global entanglement in the optical lattice. With only two-layer quantum circuits, the generation utilizes two-qubit entangling gates based on the superexchange interaction in double wells. The parallelism of these operations enables the generation to be fast and scalable. To verify the entanglement of this non-stabilizer state, we mainly design three complementary detection protocols which are less resource-consuming compared to the full tomography. In particular, one just needs two homogenous local measurement settings to identify the entanglement property. Our entanglement generation and verification protocols provide the foundation for the further quantum information processing in optical lattice. [ABSTRACT FROM AUTHOR]

Published

2022

16. Demonstration of long-range correlations via susceptibility measurements in a one-dimensional superconducting Josephson spin chain.

Author

Tennant, D. M., Dai, X., Martinez, A. J., Trappen, R., Melanson, D., Yurtalan, M. A., Tang, Y., Bedkihal, S., Yang, R., Novikov, S., Grover, J. A., Disseler, S. M., Basham, J. I., Das, R., Kim, D. K., Melville, A. J., Niedzielski, B. M., Weber, S. J., Yoder, J. L., and Kerman, A. J.

Subjects

QUANTUM annealing, QUANTUM states, SUPERCONDUCTING circuits, QUBITS

Abstract

Spin chains have long been considered an effective medium for long-range interactions, entanglement generation, and quantum state transfer. In this work, we explore the properties of a spin chain implemented with superconducting flux circuits, designed to act as a connectivity medium between two superconducting qubits. The susceptibility of the chain is probed and shown to support long-range, cross-chain correlations. In addition, interactions between the two end qubits, mediated by the coupler chain, are demonstrated. This work has direct applicability in near term quantum annealing processors as a means of generating long-range, coherent coupling between qubits. [ABSTRACT FROM AUTHOR]

Published

2022

17. Designing quantum networks using preexisting infrastructure.

Author

Rabbie, Julian, Chakraborty, Kaushik, Avis, Guus, and Wehner, Stephanie

Subjects

LINEAR programming, QUANTUM communication, OPTICAL fibers, QUANTUM states, ROBUST control

Abstract

We consider the problem of deploying a quantum network on an existing fiber infrastructure, where quantum repeaters and end nodes can only be housed at specific locations. We propose a method based on integer linear programming (ILP) to place the minimal number of repeaters on such an existing network topology, such that requirements on end-to-end entanglement-generation rate and fidelity between any pair of end-nodes are satisfied. While ILPs are generally difficult to solve, we show that our method performs well in practice for networks of up to 100 nodes. We illustrate the behavior of our method both on randomly-generated network topologies, as well as on a real-world fiber topology deployed in the Netherlands. [ABSTRACT FROM AUTHOR]

Published

2022

18. Multipartite entanglement of billions of motional atoms heralded by single photon.

Author

Li, Hang, Dou, Jian-Peng, Pang, Xiao-Ling, Zhang, Chao-Ni, Yan, Zeng-Quan, Yang, Tian-Huai, Gao, Jun, Li, Jia-Ming, and Jin, Xian-Min

Abstract

Quantum theory does not prevent entanglement from being created and observed in macroscopic physical systems, in reality however, the accessible scale of entanglement is still very limited due to decoherence effects. Recently, entanglement has been observed among atoms from thousands to millions levels in extremely low-temperature and well isolated systems. Here, we create multipartite entanglement of billions of motional atoms in a quantum memory at room temperature and certify the genuine entanglement via M-separability witness associated with photon statistics. The information contained in a single photon is found strongly correlated with the excitation shared by the motional atoms, which intrinsically address the large system and therefore stimulate the multipartite entanglement. Remarkably, our heralded and quantum memory built-in entanglement generation allows us to directly observe the dynamic evolution of entanglement depth and further to reveal the effects of decoherence. Our results verify the existence of genuine multipartite entanglement among billions of motional atoms at ambient conditions, significantly extending the boundary of the accessible scale of entanglement. [ABSTRACT FROM AUTHOR]

Published

2021

19. Entanglement formation in continuous-variable random quantum networks.

Author

Zhang, Bingzhi and Zhuang, Quntao

Abstract

Entanglement is not only important for understanding the fundamental properties of many-body systems, but also the crucial resource enabling quantum advantages in practical information processing tasks. Although previous works on quantum networks focus on discrete-variable systems, light—as the only traveling carrier of quantum information in a network—is bosonic and thus requires a continuous-variable description. We extend the study to continuous-variable quantum networks. By mapping the ensemble-averaged entanglement dynamics on an arbitrary network to a random-walk process on a graph, we are able to exactly solve the entanglement dynamics. We identify squeezing as the source of entanglement generation, which triggers a diffusive spread of entanglement with a "parabolic light cone". A surprising linear superposition law in the entanglement growth is predicted by the theory and numerically verified, despite the nonlinear nature of the entanglement dynamics. The equilibrium entanglement distribution (Page curves) is exactly solved and has various shapes depending on the average squeezing density and strength. [ABSTRACT FROM AUTHOR]

Published

2021

20. Multipartite entanglement analysis from random correlations.

Author

Knips, Lukas, Dziewior, Jan, Kłobus, Waldemar, Laskowski, Wiesław, Paterek, Tomasz, Shadbolt, Peter J., Weinfurter, Harald, and Meinecke, Jasmin D. A.

Abstract

Quantum entanglement is usually revealed via a well aligned, carefully chosen set of measurements. Yet, under a number of experimental conditions, for example in communication within multiparty quantum networks, noise along the channels or fluctuating orientations of reference frames may ruin the quality of the distributed states. Here, we show that even for strong fluctuations one can still gain detailed information about the state and its entanglement using random measurements. Correlations between all or subsets of the measurement outcomes and especially their distributions provide information about the entanglement structure of a state. We analytically derive an entanglement criterion for two-qubit states and provide strong numerical evidence for witnessing genuine multipartite entanglement of three and four qubits. Our methods take the purity of the states into account and are based on only the second moments of measured correlations. Extended features of this theory are demonstrated experimentally with four photonic qubits. As long as the rate of entanglement generation is sufficiently high compared to the speed of the fluctuations, this method overcomes any type and strength of localized unitary noise. [ABSTRACT FROM AUTHOR]

Published

2020

21. Robust entanglement preparation against noise by controlling spatial indistinguishability.

Author

Nosrati, Farzam, Castellini, Alessia, Compagno, Giuseppe, and Lo Franco, Rosario

Abstract

Initialization of composite quantum systems into highly entangled states is usually a must to enable their use for quantum technologies. However, unavoidable noise in the preparation stage makes the system state mixed, hindering this goal. Here, we address this problem in the context of identical particle systems within the operational framework of spatially localized operations and classical communication (sLOCC). We define the entanglement of formation for an arbitrary state of two identical qubits. We then introduce an entropic measure of spatial indistinguishability as an information resource. Thanks to these tools we find that spatial indistinguishability, even partial, can be a property shielding nonlocal entanglement from preparation noise, independently of the exact shape of spatial wave functions. These results prove quantum indistinguishability is an inherent control for noise-free entanglement generation. [ABSTRACT FROM AUTHOR]

Published

2020

22. Optimal entanglement distribution policies in homogeneous repeater chains with cutoffs.

Author

Iñesta, Álvaro G., Vardoyan, Gayane, Scavuzzo, Lara, and Wehner, Stephanie

Subjects

MARKOV processes, ACCOUNTING policies

Abstract

We study the limits of bipartite entanglement distribution using a chain of quantum repeaters that have quantum memories. To generate end-to-end entanglement, each node can attempt the generation of an entangled link with a neighbor, or perform an entanglement swapping measurement. A maximum storage time, known as cutoff, is enforced on the memories to ensure high-quality entanglement. Nodes follow a policy that determines when to perform each operation. Global-knowledge policies take into account all the information about the entanglement already produced. Here, we find global-knowledge policies that minimize the expected time to produce end-to-end entanglement. Our methods are based on Markov decision processes and value and policy iteration. We compare optimal policies to a policy in which nodes only use local information. We find that the advantage in expected delivery time provided by an optimal global-knowledge policy increases with increasing number of nodes and decreasing probability of successful swapping. [ABSTRACT FROM AUTHOR]

Published

2023

23. Dephasing enabled fast charging of quantum batteries.

Author

Shastri, Rahul, Jiang, Chao, Xu, Guo-Hua, Prasanna Venkatesh, B., and Watanabe, Gentaro

Subjects

HARMONIC oscillators, ENERGY transfer, OSCILLATIONS, STORAGE batteries, FREEZING

Abstract

We propose and analyze a universal method to obtain fast charging of a quantum battery by a driven charger system using controlled, pure dephasing of the charger. While the battery displays coherent underdamped oscillations of energy for weak charger dephasing, the quantum Zeno freezing of the charger energy at high dephasing suppresses the rate of transfer of energy to the battery. Choosing an optimum dephasing rate between the regimes leads to a fast charging of the battery. We illustrate our results with the charger and battery modeled by either two-level systems or harmonic oscillators. Apart from the fast charging, the dephasing also renders the charging performance more robust to detuning between the charger, drive, and battery frequencies for the two-level systems case. [ABSTRACT FROM AUTHOR]

Published

2025

24. Long-range data transmission in a fault-tolerant quantum bus architecture

Author

Shin Ho Choe and Robert König

Subjects

Physics, QC1-999, Electronic computers. Computer science, QA75.5-76.95

Abstract

Abstract We propose a fault-tolerant scheme for generating long-range entanglement at the ends of a rectangular array of qubits of length R with a square cross-section of $$m=O({\log }^{2}R)$$ m = O ( log 2 R ) qubits. It is realized by a constant-depth circuit producing a constant-fidelity Bell-pair (independent of R) for local stochastic noise of strength below an experimentally realistic threshold. The scheme can be viewed as a quantum bus in a quantum computing architecture where qubits are arranged on a rectangular 3D grid, and all operations are between neighboring qubits. Alternatively, it can be seen as a quantum repeater protocol along a line, with neighboring repeaters placed at a short distance to allow constant-fidelity nearest-neighbor operations. To show our protocol uses a number of qubits close to optimal, we show that any noise-resilient distance-R entanglement generation scheme realized by a constant-depth circuit needs at least $$m=\Omega (\log R)$$ m = Ω ( log R ) qubits per repeater.

Published

2024

25. A quantum router architecture for high-fidelity entanglement flows in quantum networks.

Author

Lee, Yuan, Bersin, Eric, Dahlberg, Axel, Wehner, Stephanie, and Englund, Dirk

Subjects

QUANTUM entanglement, INFORMATION networks, NETWORK routers, MULTIPLEXING

Abstract

The past decade has seen tremendous progress in experimentally realizing the building blocks of quantum repeaters. Repeater architectures with multiplexed quantum memories have been proposed to increase entanglement distribution rates, but an open challenge is to maintain entanglement fidelity over long-distance links. Here, we address this with a quantum router architecture comprising many quantum memories connected in a photonic switchboard to broker entanglement flows across quantum networks. We compute the rate and fidelity of entanglement distribution under this architecture using an event-based simulator, finding that the router improves the entanglement fidelity as multiplexing depth increases without a significant drop in the entanglement distribution rate. Specifically, the router permits channel-loss-invariant fidelity, i.e. the same fidelity achievable with lossless links. Furthermore, this scheme automatically prioritizes entanglement flows across the full network without requiring global network information. The proposed architecture uses present-day photonic technology, opening a path to near-term deployable multi-node quantum networks. [ABSTRACT FROM AUTHOR]

Published

2022

26. Cavity-assisted resonance fluorescence from a nitrogen-vacancy center in diamond.

Author

Yurgens, Viktoria, Fontana, Yannik, Corazza, Andrea, Shields, Brendan J., Maletinsky, Patrick, and Warburton, Richard J.

Subjects

PHOTON emission, PHOTONS, FLUORESCENCE, RESONANCE, DIAMONDS

Abstract

The nitrogen-vacancy center in diamond is an attractive resource for the generation of remote entangled states owing to its optically addressable and long-lived electronic spin. However, its low native fraction of coherent photon emission, ~3%, undermines the achievable spin-photon entanglement rates. Here, we couple a nitrogen-vacancy center with a narrow extrinsically-broadened linewidth (159 MHz), hosted in a micron-thin membrane, to an open microcavity. The resulting Purcell factor of ~1.8 increases the zero-phonon line fraction to over 44%. Operation in the Purcell regime, together with an efficient collection of the zero-phonon-line photons, allows resonance fluorescence to be detected for the first time without any temporal filtering. We achieve a >10 signal-to-laser background ratio. This selective enhancement of the center's zero-phonon transitions could increase spin-spin entanglement success probabilities beyond an order of magnitude compared to state-of-the-art implementations, and enable powerful quantum optics techniques such as wave-packet shaping or all-optical spin manipulation. [ABSTRACT FROM AUTHOR]

Published

2024

27. Qubit teleportation between a memory-compatible photonic time-bin qubit and a solid-state quantum network node.

Author

Iuliano, Mariagrazia, Slater, Marie-Christine, Stolk, Arian J., Weaver, Matthew J., Chakraborty, Tanmoy, Loukiantchenko, Elsie, do Amaral, Gustavo C., Alfasi, Nir, Sholkina, Mariya O., Tittel, Wolfgang, and Hanson, Ronald

Subjects

QUANTUM teleportation, QUANTUM interference, FREQUENCY changers, QUBITS, TELEPORTATION

Abstract

We report on a quantum interface linking a diamond NV center quantum network node and 795nm photonic time-bin qubits compatible with Thulium and Rubidium quantum memories. The interface makes use of two-stage low-noise quantum frequency conversion and waveform shaping to match temporal and spectral photon profiles. Two-photon quantum interference shows high indistinguishability between converted 795nm photons and the native NV center photons. We use the interface to demonstrate quantum teleportation including real-time feedforward from an unbiased set of 795nm photonic qubit input states to the NV center spin qubit, achieving a teleportation fidelity well above the classical bound. This proof-of-concept experiment shows the feasibility of interconnecting different quantum network hardware. [ABSTRACT FROM AUTHOR]

Published

2024

28. 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

29. Secure and robust randomness with sequential quantum measurements.

Author

Padovan, Matteo, Foletto, Giulio, Coccia, Lorenzo, Avesani, Marco, Villoresi, Paolo, and Vallone, Giuseppe

Subjects

QUANTUM correlations, QUANTUM measurement, QUANTUM states, QUBITS, NUMERICAL analysis

Abstract

Quantum correlations between measurements of separated observers are crucial for applications like randomness generation and key distribution. Although device-independent security can be certified with minimal assumptions, current protocols have limited performance. Here, we exploit sequential measurements, defined with a precise temporal order, to enhance performance by reusing quantum states. We provide a geometric perspective and a general mathematical framework, analytically proving a Tsirelson-like boundary for sequential quantum correlations, which represents a trade-off in nonlocality shared by sequential users. This boundary is advantageous for secure quantum randomness generation, certifying maximum bits per state with one remote and two sequential parties, even if one sequential user shares no nonlocality. Our simple qubit protocol reaches this boundary, and numerical analysis shows improved robustness under realistic noise. A photonic implementation confirms feasibility and robustness. This study advances the understanding of sequential quantum correlations and offers insights for efficient device-independent protocols. [ABSTRACT FROM AUTHOR]

Published

2024

30. Large-scale simulations of Floquet physics on near-term quantum computers.

Author

Eckstein, Timo, Mansuroglu, Refik, Czarnik, Piotr, Zhu, Jian-Xin, Hartmann, Michael J., Cincio, Lukasz, Sornborger, Andrew T., and Holmes, Zoë

Subjects

QUANTUM computers, ION traps, TWO-dimensional models, QUANTUM theory, MAGNETISM

Abstract

Periodically driven quantum systems exhibit a diverse set of phenomena but are more challenging to simulate than their equilibrium counterparts. Here, we introduce the Quantum High-Frequency Floquet Simulation (QHiFFS) algorithm as a method to simulate fast-driven quantum systems on quantum hardware. Central to QHiFFS is the concept of a kick operator which transforms the system into a basis where the dynamics is governed by a time-independent effective Hamiltonian. This allows prior methods for time-independent simulation to be lifted to simulate Floquet systems. We use the periodically driven biaxial next-nearest neighbor Ising (BNNNI) model, a natural test bed for quantum frustrated magnetism and criticality, as a case study to illustrate our algorithm. We implemented a 20-qubit simulation of the driven two-dimensional BNNNI model on Quantinuum's trapped ion quantum computer. Our error analysis shows that QHiFFS exhibits not only a cubic advantage in driving frequency ω but also a linear advantage in simulation time t compared to Trotterization. [ABSTRACT FROM AUTHOR]

Published

2024

31. Calibration-independent bound on the unitarity of a quantum channel with application to a frequency converter.

Author

Bock, Matthias, Sekatski, Pavel, Bancal, Jean-Daniel, Kucera, Stephan, Bauer, Tobias, Sangouard, Nicolas, Becher, Christoph, and Eschner, Jürgen

Subjects

FREQUENCY changers, HILBERT space, QUBITS, INDEPENDENT sets, BELL'S theorem, TELECOMMUNICATION, CALIBRATION

Abstract

We report on a method to certify a unitary operation with the help of source and measurement apparatuses whose calibration throughout the certification process needs not be trusted. As in the device-independent paradigm our certification method relies on a Bell test and requires no assumption on the underlying Hilbert space dimension, but it removes the need for high detection efficiencies by including the single additional assumption that non-detected events are independent of the measurement settings. The relevance of the proposed method is demonstrated experimentally by bounding the unitarity of a quantum frequency converter. The experiment starts with the heralded creation of a maximally entangled two-qubit state between a single 40Ca+ ion and a 854 nm photon. Entanglement preserving frequency conversion to the telecom band is then realized with a non-linear waveguide embedded in a Sagnac interferometer. The resulting ion-telecom photon entangled state is assessed by means of a Bell-CHSH test from which the quality of the frequency conversion is quantified. We demonstrate frequency conversion with an average certified fidelity of ≥84% and an efficiency ≥3.1 × 10−6 at a confidence level of 99%. This ensures the suitability of the converter for integration in quantum networks from a trustful characterization procedure. [ABSTRACT FROM AUTHOR]

Published

2024

32. Electro-optic entanglement source for microwave to telecom quantum state transfer.

Author

Rueda, Alfredo, Hease, William, Barzanjeh, Shabir, and Fink, Johannes M.

Abstract

We propose an efficient microwave-photonic modulator as a resource for stationary entangled microwave-optical fields and develop the theory for deterministic entanglement generation and quantum state transfer in multi-resonant electro-optic systems. The device is based on a single crystal whispering gallery mode resonator integrated into a 3D-microwave cavity. The specific design relies on a new combination of thin-film technology and conventional machining that is optimized for the lowest dissipation rates in the microwave, optical, and mechanical domains. We extract important device properties from finite-element simulations and predict continuous variable entanglement generation rates on the order of a Mebit/s for optical pump powers of only a few tens of microwatts. We compare the quantum state transfer fidelities of coherent, squeezed, and non-Gaussian cat states for both teleportation and direct conversion protocols under realistic conditions. Combining the unique capabilities of circuit quantum electrodynamics with the resilience of fiber optic communication could facilitate long-distance solid-state qubit networks, new methods for quantum signal synthesis, quantum key distribution, and quantum enhanced detection, as well as more power-efficient classical sensing and modulation. [ABSTRACT FROM AUTHOR]

Published

2019

33. Scalable spin–photon entanglement by time-to-polarization conversion.

Author

Vasconcelos, Rui, Reisenbauer, Sarah, Salter, Cameron, Wachter, Georg, Wirtitsch, Daniel, Schmiedmayer, Jörg, Walther, Philip, and Trupke, Michael

Abstract

The realization of quantum networks and quantum computers relies on the scalable generation of entanglement, for which spin-photon interfaces are strong candidates. Current proposals to produce entangled-photon states with such platforms place stringent requirements on the physical properties of the photon emitters, limiting the range and performance of suitable physical systems. We propose a scalable protocol, which significantly reduces the constraints on the emitter. We use only a single optical transition and an asymmetric polarizing interferometer. This device converts the entanglement from the experimentally robust time basis via a path degree of freedom into a polarization basis, where quantum logic operations can be performed. The fundamental unit of the proposed protocol is realized experimentally in this work, using a nitrogen-vacancy center in diamond. This classically assisted protocol greatly widens the set of physical systems suited for scalable entangled-photon generation and enables performance enhancement of existing platforms. [ABSTRACT FROM AUTHOR]

Published

2020

34. Deterministic photon source interfaced with a programmable silicon-nitride integrated circuit

Author

Ying Wang, Carlos F. D. Faurby, Fabian Ruf, Patrik I. Sund, Kasper Nielsen, Nicolas Volet, Martijn J. R. Heck, Nikolai Bart, Andreas D. Wieck, Arne Ludwig, Leonardo Midolo, Stefano Paesani, and Peter Lodahl

Subjects

Physics, QC1-999, Electronic computers. Computer science, QA75.5-76.95

Abstract

Abstract We develop a quantum photonic platform that interconnects a high-quality quantum dot single-photon source and a low-loss photonic integrated circuit made in silicon nitride. The platform is characterized and programmed to demonstrate various multiphoton applications, including bosonic suppression laws and photonic entanglement generation. The results show a promising technological route forward to scale-up photonic quantum hardware.

Published

2023

35. Quantum networks with neutral atom processing nodes

Author

Jacob P. Covey, Harald Weinfurter, and Hannes Bernien

Subjects

Physics, QC1-999, Electronic computers. Computer science, QA75.5-76.95

Abstract

Abstract Quantum networks providing shared entanglement over a mesh of quantum nodes will revolutionize the field of quantum information science by offering novel applications in quantum computation, enhanced precision in networks of sensors and clocks, and efficient quantum communication over large distances. Recent experimental progress with individual neutral atoms demonstrates a high potential for implementing the crucial components of such networks. We highlight latest developments and near-term prospects on how arrays of individually controlled neutral atoms are suited for both efficient remote entanglement generation and large-scale quantum information processing, thereby providing the necessary features for sharing high-fidelity and error-corrected multi-qubit entangled states between the nodes. We describe both the functionality requirements and several examples for advanced, large-scale quantum networks composed of neutral atom processing nodes.

Published

2023

36. Quantum storage of 1650 modes of single photons at telecom wavelength.

Author

Wei, Shi-Hai, Jing, Bo, Zhang, Xue-Ying, Liao, Jin-Yu, Li, Hao, You, Li-Xing, Wang, Zhen, Wang, You, Deng, Guang-Wei, Song, Hai-Zhi, Oblak, Daniel, Guo, Guang-Can, and Zhou, Qiang

Subjects

TELECOMMUNICATION, COINCIDENCE circuits, PHOTONS, OPTICAL communications, WAVELENGTHS

Abstract

To advance the full potential of quantum networks one should be able to distribute quantum resources over long distances at appreciable rates. As a consequence, all components in such networks need to have large multimode capacity to manipulate photonic quantum states. Towards this end, a photonic quantum memory with a large multimode capacity, especially one operating at telecom wavelength, remains an important challenge. Here we optimize the preparation of atomic frequency combs and demonstrate a spectro-temporally multiplexed quantum memory in a 10-m-long cryogenically cooled erbium doped silica fibre. Our multiplexing storage has five spectral channels - each 10 GHz wide with 5 GHz separation - with up to 330 temporal modes in each, thus resulting in a simultaneous storage of 1,650 modes of heralded single photons with a 1000-fold increasing in coincidence detection rate with respect to single mode storage. Our results could pave the way for high speed quantum networks compatible with the infrastructure of fibre optical communication. [ABSTRACT FROM AUTHOR]

Published

2024

37. Resource-efficient simulation of noisy quantum circuits and application to network-enabled QRAM optimization.

Author

Bugalho, Luís, Cruzeiro, Emmanuel Zambrini, Chen, Kevin C., Dai, Wenhan, Englund, Dirk, and Omar, Yasser

Subjects

QUANTUM communication, RANDOM access memory, INTEGRATED circuits, QUANTUM computers, QUBITS

Abstract

Giovannetti, Lloyd, and Maccone (2008) proposed a quantum random access memory (QRAM) architecture to retrieve arbitrary superpositions of N (quantum) memory cells via quantum switches and O (log (N)) address qubits. Toward physical QRAM implementations, Chen et al. (2021) recently showed that QRAM maps natively onto optically connected quantum networks with O (log (N)) overhead and built-in error detection. However, modeling QRAM on large networks has been stymied by exponentially rising classical compute requirements. Here, we address this bottleneck by: (1) introducing a resource-efficient method for simulating large-scale noisy entanglement, allowing us to evaluate hundreds and even thousands of qubits under various noise channels; and (2) analyzing Chen et al.'s network-based QRAM as an application at the scale of quantum data centers or near-term quantum internet; and (3) introducing a modified network-based QRAM architecture to improve quantum fidelity and access rate. We conclude that network-based QRAM could be built with existing or near-term technologies leveraging photonic integrated circuits and atomic or atom-like quantum memories. [ABSTRACT FROM AUTHOR]

Published

2023

38. Deterministic Bell state measurement with a single quantum memory.

Author

Kamimaki, Akira, Wakamatsu, Keidai, Mikata, Kosuke, Sekiguchi, Yuhei, and Kosaka, Hideo

Subjects

QUANTUM measurement, QUANTUM computers, ELECTRON spin, QUBITS, MAGNETIC fields, CARBON isotopes

Abstract

Entanglements serve as a resource for any quantum information system and are deterministically generated or swapped by a joint measurement called complete Bell state measurement (BSM). The determinism arises from a quantum nondemolition measurement of two coupled qubits with the help of readout ancilla, which inevitably requires extra physical qubits. We here demonstrate a deterministic and complete BSM with only a nitrogen atom in a nitrogen-vacancy (NV) center in diamond as a quantum memory without relying on any carbon isotopes, which are the extra qubits, by exploiting electron‒nitrogen (14N) double qutrits at a zero magnetic field. The degenerate logical qubits within the subspace of qutrits on the electron and nitrogen spins are holonomically controlled by arbitrarily polarized microwave and radiofrequency pulses via zero-field-split states as the ancilla, thus enabling the complete BSM deterministically. Since the system works under an isotope-free and field-free environment, the demonstration paves the way to realize high-fidelity quantum repeaters for long-haul quantum networks and quantum interfaces for large-scale distributed quantum computers. [ABSTRACT FROM AUTHOR]

Published

2023

39. High-efficiency microwave-optical quantum transduction based on a cavity electro-optic superconducting system with long coherence time

Author

Changqing Wang, Ivan Gonin, Anna Grassellino, Sergey Kazakov, Alexander Romanenko, Vyacheslav P. Yakovlev, and Silvia Zorzetti

Subjects

Physics, QC1-999, Electronic computers. Computer science, QA75.5-76.95

Abstract

Abstract Frequency conversion between microwave and optical photons is a key enabling technology to create links between superconducting quantum processors and to realize distributed quantum networks. We propose a microwave-optical transduction platform based on long-coherence time superconducting radio-frequency (SRF) cavities coupled to electro-optic optical cavities to mitigate the loss mechanisms that limit the attainment of high conversion efficiency. We optimize the microwave-optical field overlap and optical coupling losses in the design while achieving long microwave and optical photon lifetime at milli-Kelvin temperatures. This represents a significant enhancement of the transduction efficiency up to 50% under incoming pump power of 140 μW, which allows the conversion of few-photon quantum signals. Furthermore, this scheme exhibits high resolution for optically reading out the dispersive shift induced by a superconducting transmon qubit coupled to the SRF cavity. We also show that low microwave losses enhance the fidelity of heralded entanglement generation between two remote quantum systems. Finally, high precision in quantum sensing can be reached below the standard quantum limit.

Published

2022

40. Dressed-state control of effective dipolar interaction between strongly-coupled solid-state spins.

Author

Lee, Junghyun, Tatsuta, Mamiko, Xu, Andrew, Bauch, Erik, Ku, Mark J. H., and Walsworth, Ronald L.

Subjects

SPECTROMETRY, DIAMONDS

Abstract

Strong interactions between defect spins in many-body solid-state quantum systems are a crucial resource for exploring non-classical states. However, they face the key challenge of controlling interactions between the defect spins, since they are spatially fixed inside the host lattice. In this work, we present a dressed state approach to control the effective dipolar coupling between solid-state spins and demonstrate this scheme experimentally using two strongly-coupled nitrogen vacancy (NV) centers in diamond. Through Ramsey spectroscopy on the sensor spin, we detect the change of the effective dipolar field generated by the control spin prepared in different dressed states. To observe the change of interaction dynamics, we deploy spin-lock-based polarization transfer measurements between the two NV spins in different dressed states. This scheme allows us to control the distribution of interaction strengths in strongly interacting spin systems, which can be a valuable tool for generating multi-spin correlated states for quantum-enhanced sensing. [ABSTRACT FROM AUTHOR]

Published

2023

41. On-chip parallel processing of quantum frequency comb.

Author

Zhang, Liang, Cui, Chaohan, Yan, Jianchang, Guo, Yanan, Wang, Junxi, and Fan, Linran

Subjects

PARAMETRIC downconversion, QUANTUM information science, QUANTUM interference, DEGREES of freedom, PARALLEL processing

Abstract

The frequency degree of freedom of optical photons has been recently explored for efficient quantum information processing. Significant reduction in hardware resources and enhancement of quantum functions can be expected by leveraging the large number of frequency modes. Here, we develope an integrated photonic platform for the generation and parallel processing of quantum frequency combs (QFCs). Cavity-enhanced parametric down-conversion with Sagnac configuration is implemented to generate QFCs with identical spectral distributions. On-chip quantum interference of different frequency modes is simultaneously realized with the same photonic circuit. High interference visibility is maintained across all frequency modes with the identical circuit setting. This enables the on-chip reconfiguration of QFCs. By deterministically separating QFCs without spectral filtering, we further demonstrate high-dimensional Hong-Ou-Mandel effect. Our work provides the critical step for the efficient implementation of quantum information processing with integrated photonics using the frequency degree of freedom. [ABSTRACT FROM AUTHOR]

Published

2023

42. Realizing all-to-all couplings among detachable quantum modules using a microwave quantum state router.

Author

Zhou, Chao, Lu, Pinlei, Praquin, Matthieu, Chien, Tzu-Chiao, Kaufman, Ryan, Cao, Xi, Xia, Mingkang, Mong, Roger S. K., Pfaff, Wolfgang, Pekker, David, and Hatridge, Michael

Subjects

QUANTUM states, MICROWAVES, QUANTUM computers, JOSEPHSON junctions, QUBITS

Abstract

One of the primary challenges in realizing large-scale quantum processors is the realization of qubit couplings that balance interaction strength, connectivity, and mode confinement. Moreover, it is very desirable for the device elements to be detachable, allowing components to be built, tested, and replaced independently. In this work, we present a microwave quantum state router, centered on parametrically driven, Josephson-junction based three-wave mixing, that realizes all-to-all couplings among four detachable quantum modules. We demonstrate coherent exchange among all four communication modes, with an average full-iSWAP time of 764 ns and average inferred inter-module exchange fidelity of 0.969, limited by mode coherence. We also demonstrate photon transfer and pairwise entanglement between module qubits, and parallel operation of simultaneous iSWAP exchange across the router. Our router-module architecture serves as a prototype of modular quantum computer that has great potential for enabling flexible, demountable, large-scale quantum networks of superconducting qubits and cavities. [ABSTRACT FROM AUTHOR]

Published

2023

43. On-chip spin-photon entanglement based on photon-scattering of a quantum dot.

Author

Chan, Ming Lai, Tiranov, Alexey, Appel, Martin Hayhurst, Wang, Ying, Midolo, Leonardo, Scholz, Sven, Wieck, Andreas D., Ludwig, Arne, Sørensen, Anders Søndberg, and Lodahl, Peter

Subjects

QUANTUM logic, QUANTUM dots, QUANTUM computing, PHOTON pairs, PHOTONS

Abstract

The realization of on-chip quantum interfaces between flying photons and solid-state spins is a key building block for quantum-information processors, enabling, e.g., distributed quantum computing, where remote quantum registers are interconnected by flying photons. Self-assembled quantum dots integrated into nanostructures are one of the most promising systems for such an endeavor thanks to their near-unity photon-emitter coupling and fast spontaneous emission rate. Here we demonstrate high-fidelity on-chip entanglement between an incoming photon and a stationary quantum-dot hole spin qubit. The entanglement is induced by sequential scattering of the time-bin encoded photon interleaved with active spin control within a microsecond, two orders of magnitude faster than those achieved in other solid-state platforms. Conditioning on the detection of a reflected photon renders the entanglement fidelity immune to the spectral wandering of the emitter. These results represent a major step towards realizing a quantum node capable of interchanging information with flying photons and on-chip quantum logic, as required for quantum networks and quantum repeaters. [ABSTRACT FROM AUTHOR]

Published

2023

44. Programmable photonic integrated meshes for modular generation of optical entanglement links.

Author

Dong, Mark, Zimmermann, Matthew, Heim, David, Choi, Hyeongrak, Clark, Genevieve, Leenheer, Andrew J., Palm, Kevin J., Witte, Alex, Dominguez, Daniel, Gilbert, Gerald, Eichenfield, Matt, and Englund, Dirk

Subjects

QUANTUM entanglement, QUANTUM computing, QUANTUM states, SILICON nitride, OPTICAL switching

Abstract

Large-scale generation of quantum entanglement between individually controllable qubits is at the core of quantum computing, communications, and sensing. Modular architectures of remotely-connected quantum technologies have been proposed for a variety of physical qubits, with demonstrations reported in atomic and all-photonic systems. However, an open challenge in these architectures lies in constructing high-speed and high-fidelity reconfigurable photonic networks for optically-heralded entanglement among target qubits. Here we introduce a programmable photonic integrated circuit (PIC), realized in a piezo-actuated silicon nitride (SiN)-in-oxide CMOS-compatible process, that implements an N × N Mach–Zehnder mesh (MZM) capable of high-speed execution of linear optical transformations. The visible-spectrum photonic integrated mesh is programmed to generate optical connectivity on up to N = 8 inputs for a range of optically-heralded entanglement protocols. In particular, we experimentally demonstrated optical connections between 16 independent pairwise mode couplings through the MZM, with optical transformation fidelities averaging 0.991 ± 0.0063. The PIC's reconfigurable optical connectivity suffices for the production of 8-qubit resource states as building blocks of larger topological cluster states for quantum computing. Our programmable PIC platform enables the fast and scalable optical switching technology necessary for network-based quantum information processors. [ABSTRACT FROM AUTHOR]

Published

2023

45. Synthesizing efficient circuits for Hamiltonian simulation.

Author

Mukhopadhyay, Priyanka, Wiebe, Nathan, and Zhang, Hong Tao

Subjects

POLYNOMIAL time algorithms, HAMILTONIAN graph theory, HAMILTONIAN systems

Abstract

We provide an approach for compiling quantum simulation circuits that appear in Trotter, qDRIFT and multi-product formulas to Clifford and non-Clifford operations that can reduce the number of non-Clifford operations. The total number of gates, especially CNOT, reduce in many cases. We show that it is possible to implement an exponentiated sum of commuting Paulis with at most m (controlled)-rotation gates, where m is the number of distinct non-zero eigenvalues (ignoring sign). Thus we can collect mutually commuting Hamiltonian terms into groups satisfying one of several symmetries identified in this work. This allows an inexpensive simulation of the entire group of terms. We further show that the cost can in some cases be reduced by partially allocating Hamiltonian terms to several groups and provide a polynomial time classical algorithm that can greedily allocate the terms to appropriate groupings. [ABSTRACT FROM AUTHOR]

Published

2023

46. A scheme to create and verify scalable entanglement in optical lattice

Author

You Zhou, Bo Xiao, Meng-Da Li, Qi Zhao, Zhen-Sheng Yuan, Xiongfeng Ma, and Jian-Wei Pan

Subjects

Physics, QC1-999, Electronic computers. Computer science, QA75.5-76.95

Abstract

Abstract To achieve scalable quantum information processing, great efforts have been devoted to the creation of large-scale entangled states in various physical systems. Ultracold atom in optical lattice is considered as one of the promising platforms due to its feasible initialization and parallel manipulation. In this work, we propose an efficient scheme to generate and characterize global entanglement in the optical lattice. With only two-layer quantum circuits, the generation utilizes two-qubit entangling gates based on the superexchange interaction in double wells. The parallelism of these operations enables the generation to be fast and scalable. To verify the entanglement of this non-stabilizer state, we mainly design three complementary detection protocols which are less resource-consuming compared to the full tomography. In particular, one just needs two homogenous local measurement settings to identify the entanglement property. Our entanglement generation and verification protocols provide the foundation for the further quantum information processing in optical lattice.

Published

2022

47. Demonstration of long-range correlations via susceptibility measurements in a one-dimensional superconducting Josephson spin chain

Author

D. M. Tennant, X. Dai, A. J. Martinez, R. Trappen, D. Melanson, M. A. Yurtalan, Y. Tang, S. Bedkihal, R. Yang, S. Novikov, J. A. Grover, S. M. Disseler, J. I. Basham, R. Das, D. K. Kim, A. J. Melville, B. M. Niedzielski, S. J. Weber, J. L. Yoder, A. J. Kerman, E. Mozgunov, D. A. Lidar, and A. Lupascu

Subjects

Physics, QC1-999, Electronic computers. Computer science, QA75.5-76.95

Abstract

Abstract Spin chains have long been considered an effective medium for long-range interactions, entanglement generation, and quantum state transfer. In this work, we explore the properties of a spin chain implemented with superconducting flux circuits, designed to act as a connectivity medium between two superconducting qubits. The susceptibility of the chain is probed and shown to support long-range, cross-chain correlations. In addition, interactions between the two end qubits, mediated by the coupler chain, are demonstrated. This work has direct applicability in near term quantum annealing processors as a means of generating long-range, coherent coupling between qubits.

Published

2022

48. Routing entanglement in the quantum internet.

Author

Pant, Mihir, Krovi, Hari, Towsley, Don, Tassiulas, Leandros, Jiang, Liang, Basu, Prithwish, Englund, Dirk, and Guha, Saikat

Abstract

Remote quantum entanglement can enable numerous applications including distributed quantum computation, secure communication, and precision sensing. We consider how a quantum network—nodes equipped with limited quantum processing capabilities connected via lossy optical links—can distribute high-rate entanglement simultaneously between multiple pairs of users. We develop protocols for such quantum "repeater" nodes, which enable a pair of users to achieve large gains in entanglement rates over using a linear chain of quantum repeaters, by exploiting the diversity of multiple paths in the network. Additionally, we develop repeater protocols that enable multiple user pairs to generate entanglement simultaneously at rates that can far exceed what is possible with repeaters time sharing among assisting individual entanglement flows. Our results suggest that the early-stage development of quantum memories with short coherence times and implementations of probabilistic Bell-state measurements can have a much more profound impact on quantum networks than may be apparent from analyzing linear repeater chains. This framework should spur the development of a general quantum network theory, bringing together quantum memory physics, quantum information theory, quantum error correction, and computer network theory. Quantum internet: all roads lead to entanglement distribution The best way to generate entanglement between two distant users in a quantum network is to look at many paths at the same time. Saikat Guha from University of Arizona led a team of American researchers which discovered an improved way to tackle the task of entanglement distribution. What they found is that, even in the case of only two users, having a network of links and using a multi-path strategy instead of a simple sequence of segments gives a large advantage in terms of achievable distance. The problem of generating entanglement (the notorious 'spooky' quantum correlations) between distant locations is not only a matter of fundamental science, but it would allow to empower the Internet with a set of quantum-enhanced capabilities such as intrinsically-secure communication. [ABSTRACT FROM AUTHOR]

Published

2019

49. A benchmarking procedure for quantum networks.

Author

Helsen, Jonas and Wehner, Stephanie

Subjects

BENCHMARKING (Management), QUANTUM communication, STATISTICS

Abstract

We propose network benchmarking: a procedure to efficiently benchmark the quality of a quantum network link connecting quantum processors in a quantum network. This procedure is based on the standard randomized benchmarking protocol and provides an estimate for the fidelity of a quantum network link. We provide statistical analysis of the protocol as well as a simulated implementation inspired by nitrogen-vacancy center systems using Netsquid, a special purpose simulator for noisy quantum networks. [ABSTRACT FROM AUTHOR]

Published

2023

50. Advances in device-independent quantum key distribution.

Author

Zapatero, Víctor, van Leent, Tim, Arnon-Friedman, Rotem, Liu, Wen-Zhao, Zhang, Qiang, Weinfurter, Harald, and Curty, Marcos

Subjects

QUANTUM measurement, INFORMATION-theoretic security, QUANTUM mechanics, BELL'S theorem, COMPUTER hacking

Abstract

Device-independent quantum key distribution (DI-QKD) provides the gold standard for secure key exchange. Not only does it allow for information-theoretic security based on quantum mechanics, but it also relaxes the need to physically model the devices, thereby fundamentally ruling out many quantum hacking threats to which non-DI QKD systems are vulnerable. In practice though, DI-QKD is very challenging. It relies on the loophole-free violation of a Bell inequality, a task that requires high quality entanglement to be distributed between distant parties and close to perfect quantum measurements, which is hardly achievable with current technology. Notwithstanding, recent theoretical and experimental efforts have led to proof-of-principle DI-QKD implementations. In this article, we review the state-of-the-art of DI-QKD by highlighting its main theoretical and experimental achievements, discussing recent proof-of-principle demonstrations, and emphasizing the existing challenges in the field. [ABSTRACT FROM AUTHOR]

Published

2023