Your search keyword '"Entanglement generation"' showing total 162 results

1. Synthetic five-wave mixing in an integrated microcavity for visible-telecom entanglement generation

Author

Wang, Jia-Qi, Yang, Yuan-Hao, Li, Ming, Zhou, Haiqi, Xu, Xin-Biao, Zhang, Ji-Zhe, Dong, Chun-Hua, Guo, Guang-Can, and Zou, C.-L.

Published

2022

2. Fast delivery of heralded atom-photon quantum correlation over 12 km fiber through multiplexing enhancement.

Author

Zhang, Sheng, Shi, Jixuan, Liang, Yibo, Sun, Yuedong, Wu, Yukai, Duan, Luming, and Pu, Yunfei

Subjects

QUANTUM correlations, QUANTUM information science, QUANTUM entanglement, DECOHERENCE (Quantum mechanics), MULTIPLEXING

Abstract

Distributing quantum entanglement between distant parties is a significant but difficult task in quantum information science, as it can enable numerous applications but suffers from exponential decay in the quantum channel. Quantum repeaters are one of the most promising approaches towards this goal. In a quantum repeater protocol, it is essential that the entanglement generation speed within each elementary link is faster than the memory decoherence rate, and this stringent requirement has not been implemented over a fiber of metropolitan scale so far. As a step towards this challenging goal, in this work we experimentally realize multiplexing-enhanced generation of heralded atom-photon quantum correlation over a 12 km fiber. We successively generate 280 pairs of atom-photon quantum correlations with a train of photonic time-bin pulses filling the long fiber, and read out the excited memory modes on demand with either fixed or variable storage time after successful heralding. With the multiplexing enhancement, the heralding rate of atom-photon correlation can reach 1.95 kHz, and the ratio between the quantum correlation generation rate to memory decoherence rate can be improved to 0.46 for a fiber length of 12 km. This work therefore constitutes an important step towards the realization of a large-scale quantum repeater network. Successfully implementing a quantum repeater would require an entanglement generation rate higher than the memory decoherence rate, but current implementations with atomic memories are still far from this goal. Here, the authors narrow this gap by exploiting spatial and time-bin multiplexing in an atomic DLCZ memory, and sending the frequency-converted signal photon through 12 km of telecom fiber. [ABSTRACT FROM AUTHOR]

Published

2024

3. Realization of a crosstalk-avoided quantum network node using dual-type qubits of the same ion species.

Author

Feng, L., Huang, Y.-Y., Wu, Y.-K., Guo, W.-X., Ma, J.-Y., Yang, H.-X., Zhang, L., Wang, Y., Huang, C.-X., Zhang, C., Yao, L., Qi, B.-X., Pu, Y.-F., Zhou, Z.-C., and Duan, L.-M.

Subjects

QUBITS, HYPERFINE structure, IONS, SPECIES, PHOTONS

Abstract

Generating ion-photon entanglement is a crucial step for scalable trapped-ion quantum networks. To avoid the crosstalk on memory qubits carrying quantum information, it is common to use a different ion species for ion-photon entanglement generation such that the scattered photons are far off-resonant for the memory qubits. However, such a dual-species scheme can be subject to inefficient sympathetic cooling due to the mass mismatch of the ions. Here we demonstrate a trapped-ion quantum network node in the dual-type qubit scheme where two types of qubits are encoded in the S and F hyperfine structure levels of 171Yb+ ions. We generate ion photon entanglement for the S-qubit in a typical timescale of hundreds of milliseconds, and verify its small crosstalk on a nearby F-qubit with coherence time above seconds. Our work demonstrates an enabling function of the dual-type qubit scheme for scalable quantum networks. In ion-photon quantum network platforms, usually memory qubits and communication qubits are encoded in ions of different species. Here, instead, the authors show how to realise ion-photon entanglement within the same-species-dual-encoding scheme. [ABSTRACT FROM AUTHOR]

Published

2024

4. Coherent optical control of a superconducting microwave cavity via electro-optical dynamical back-action.

Author

Qiu, Liu, Sahu, Rishabh, Hease, William, Arnold, Georg, and Fink, Johannes M.

Subjects

OPTICAL control, CAVITY resonators, SUPERCONDUCTING resonators, ELECTROMAGNETIC waves, MICROWAVE circuits, SUPERCONDUCTING circuits

Abstract

Recent quantum technologies have established precise quantum control of various microscopic systems using electromagnetic waves. Interfaces based on cryogenic cavity electro-optic systems are particularly promising, due to the direct interaction between microwave and optical fields in the quantum regime. Quantum optical control of superconducting microwave circuits has been precluded so far due to the weak electro-optical coupling as well as quasi-particles induced by the pump laser. Here we report the coherent control of a superconducting microwave cavity using laser pulses in a multimode electro-optical device at millikelvin temperature with near-unity cooperativity. Both the stationary and instantaneous responses of the microwave and optical modes comply with the coherent electro-optical interaction, and reveal only minuscule amount of excess back-action with an unanticipated time delay. Our demonstration enables wide ranges of applications beyond quantum transductions, from squeezing and quantum non-demolition measurements of microwave fields, to entanglement generation and hybrid quantum networks. Electro-optical interfaces are promising for quantum networks of superconducting circuits. Here the authors demonstrate a coherent optical control of a superconducting microwave resonator in the unity cooperativity regime of cavity electro-optics. [ABSTRACT FROM AUTHOR]

Published

2023

5. Field programmable spin arrays for scalable quantum repeaters.

Author

Wang, Hanfeng, Trusheim, Matthew E., Kim, Laura, Raniwala, Hamza, and Englund, Dirk R.

Subjects

ELECTRIC fields, BASES (Architecture), ELECTRIC drives, POWER density, QUBITS, MICROWAVE plasmas, QUANTUM gates

Abstract

The large scale control over thousands of quantum emitters desired by quantum network technology is limited by the power consumption and cross-talk inherent in current microwave techniques. Here we propose a quantum repeater architecture based on densely-packed diamond color centers (CCs) in a programmable electrode array, with quantum gates driven by electric or strain fields. This 'field programmable spin array' (FPSA) enables high-speed spin control of individual CCs with low cross-talk and power dissipation. Integrated in a slow-light waveguide for efficient optical coupling, the FPSA serves as a quantum interface for optically-mediated entanglement. We evaluate the performance of the FPSA architecture in comparison to a routing-tree design and show an increased entanglement generation rate scaling into the thousand-qubit regime. Our results enable high fidelity control of dense quantum emitter arrays for scalable networking. Applications of solid-state qubits in large-scale quantum networks are limited by power and density constraints associated with microwave driving. Here the authors propose a programmable architecture based on diamond color centers driven by electric or strain fields for reduced cross-talk and power consumption. [ABSTRACT FROM AUTHOR]

Published

2023

6. Dissipative Landau-Zener tunneling in the crossover regime from weak to strong environment coupling.

Author

Dai, X., Trappen, R., Chen, H., Melanson, D., Yurtalan, M. A., Tennant, D. M., Martinez, A. J., Tang, Y., Mozgunov, E., Gibson, J., Grover, J. A., Disseler, S. M., Basham, J. I., Novikov, S., Das, R., Melville, A. J., Niedzielski, B. M., Hirjibehedin, C. F., Serniak, K., and Weber, S. J.

Subjects

QUANTUM annealing, PARTICLES (Nuclear physics), PHENOMENOLOGICAL theory (Physics), PHYSICAL sciences, QUBITS

Abstract

Landau-Zener tunneling, which describes the transition in a two-level system during a sweep through an anti-crossing, is a model applicable to a wide range of physical phenomena. Realistic quantum systems are affected by dissipation due to coupling to their environments. An important aspect of understanding such open quantum systems is the relative energy scales of the system itself and the system-environment coupling, which distinguishes the weak- and strong-coupling regimes. Using a tunable superconducting flux qubit, we observe the crossover from weak to strong coupling to the environment in Landau-Zener tunneling. Our results confirm previous theoretical studies of dissipative Landau-Zener tunneling in the weak and strong coupling limits. We devise a spin bath model that effectively captures the crossover regime. This work is relevant for understanding the role of dissipation in quantum annealing, where the system is expected to go through a cascade of Landau-Zener transitions before reaching the target state. Landau-Zener transitions near an avoided level crossing are a broadly relevant concept in quantum systems. Here the authors use a superconducting flux qubit to shed new light on the role of the environment in Landau-Zener tunneling by observing a crossover between weak and strong coupling. [ABSTRACT FROM AUTHOR]

Published

2025

7. A thin film lithium niobate near-infrared platform for multiplexing quantum nodes.

Author

Assumpcao, Daniel, Renaud, Dylan, Baradari, Aida, Zeng, Beibei, De-Eknamkul, Chawina, Xin, C. J., Shams-Ansari, Amirhassan, Barton, David, Machielse, Bartholomeus, and Loncar, Marko

Subjects

LITHIUM niobate, PHYSICAL sciences, CIRCUIT complexity, PHOTONICS, QUBITS, QUANTUM networks (Optics)

Abstract

Practical quantum networks will require multi-qubit quantum nodes. This in turn will increase the complexity of the photonic circuits needed to control each qubit and require strategies to multiplex memories. Integrated photonics operating at visible to near-infrared (VNIR) wavelength range can provide solutions to these needs. In this work, we realize a VNIR thin-film lithium niobate (TFLN) integrated photonics platform with the key components to meet these requirements, including low-loss couplers (<1 dB/facet), switches (>20 dB extinction), and high-bandwidth electro-optic modulators (>50 GHz). With these devices, we demonstrate high-efficiency and CW-compatible frequency shifting (>50% efficiency at 15 GHz), as well as simultaneous laser amplitude and frequency control. Finally, we highlight an architecture for multiplexing quantum memories and outline how this platform can enable a 2-order of magnitude improvement in entanglement rates over single memory nodes. Our results demonstrate that TFLN can meet the necessary performance and scalability benchmarks to enable large-scale quantum nodes. This work demonstrates the necessary building blocks to realize large-scale multiplexed quantum networking nodes in a visible thin-film lithium niobate integrated photonics platform. [ABSTRACT FROM AUTHOR]

Published

2024

8. Deterministic multi-phonon entanglement between two mechanical resonators on separate substrates

Author

Ming-Han Chou, Hong Qiao, Haoxiong Yan, Gustav Andersson, Christopher R. Conner, Joel Grebel, Yash J. Joshi, Jacob M. Miller, Rhys G. Povey, Xuntao Wu, and Andrew N. Cleland

Subjects

Science

Abstract

Abstract Mechanical systems have emerged as a compelling platform for applications in quantum information, leveraging advances in the control of phonons, the quanta of mechanical vibrations. Experiments have demonstrated the control and measurement of phonon states in mechanical resonators, and while dual-resonator entanglement has been demonstrated, more complex entangled states remain a challenge. Here, we demonstrate rapid multi-phonon entanglement generation and subsequent tomographic analysis, using a scalable platform comprising two surface acoustic wave resonators on separate substrates, each connected to a superconducting qubit. We synthesize a mechanical Bell state with a fidelity of $${{{{\mathcal{F}}}}}=0.872\pm 0.002$$ F = 0.872 ± 0.002 , and a multi-phonon entangled N = 2 N00N state with a fidelity of $${{{{\mathcal{F}}}}}=0.748\pm 0.008$$ F = 0.748 ± 0.008 . The compact, modular, and scalable platform we demonstrate will enable further advances in the quantum control of complex mechanical systems.

Published

2025

9. Measuring topological invariants for higher-order exceptional points in quantum three-mode systems.

Author

Han, Pei-Rong, Ning, Wen, Huang, Xin-Jie, Zheng, Ri-Hua, Yang, Shou-Bang, Wu, Fan, Yang, Zhen-Biao, Su, Qi-Ping, Yang, Chui-Ping, and Zheng, Shi-Biao

Subjects

TOPOLOGICAL property, QUANTUM correlations, QUANTUM states, QUBITS, DISPLAY systems

Abstract

Owing to the presence of exceptional points (EPs), non-Hermitian (NH) systems can display intriguing topological phenomena without Hermitian analogs. However, experimental characterizations of exceptional topological invariants have been restricted to second-order EPs (EP2s) in classical or semiclassical systems. We here propose an NH multi-mode system with higher-order EPs, each of which is underlain by a multifold-degenerate multipartite entangled eigenstate. We implement the NH model by controllably coupling a Josephson-junction-based electronic mode to two microwave resonators. We experimentally quantify the topological invariant for an EP3, by mapping out the complex eigenspectra of the tripartite system along a loop surrounding this EP3 in the parameter space. The nonclassicality of the realized topology is manifested by the observed quantum correlations in the corresponding eigenstates. Our results extend research of exceptional topology to fully quantum-mechanical models with multipartite entangled eigenstates. Exceptional topology associated with higher-order exceptional points has not been completely characterised in quantum systems. Here, the authors fill this gap performing full quantum state tomography in a system composed of a superconducting qubit coupled to two cavities, one lossless and one lossy, featuring third-order exceptional points. [ABSTRACT FROM AUTHOR]

Published

2024

10. Optimal Floquet state engineering for large scale atom interferometers.

Author

Rodzinka, T., Dionis, E., Calmels, L., Beldjoudi, S., Béguin, A., Guéry-Odelin, D., Allard, B., Sugny, D., and Gauguet, A.

Subjects

QUANTUM theory, ATOMIC beams, BEAM splitters, OPTICAL lattices, MOMENTUM transfer

Abstract

The effective control of atomic coherence with cold atoms has made atom interferometry an essential tool for quantum sensors and precision measurements. The performance of these interferometers is closely related to the operation of large wave packet separations. We present here a novel approach for atomic beam splitters based on the stroboscopic stabilization of quantum states in an accelerated optical lattice. The corresponding Floquet state is generated by optimal control protocols. In this way, we demonstrate an unprecedented Large Momentum Transfer (LMT) interferometer, with a momentum separation of 600 photon recoils (600 ℏk) between its two arms. Each LMT beam splitter is realized in a remarkably short time (2 ms) and is highly robust against the initial velocity dispersion of the wave packet and lattice depth fluctuations. Our study shows that Floquet engineering is a promising tool for exploring new frontiers in quantum physics at large scales, with applications in quantum sensing and testing fundamental physics. Large-scale atom interferometers enable precise measurements of fundamental constants and novel sensors. This study uses Floquet formalism to create an optimal transported state, resulting in an efficient large-momentum-transfer interferometer, advancing largescale interferometers. [ABSTRACT FROM AUTHOR]

Published

2024

11. Room-temperature waveguide integrated quantum register in a semiconductor photonic platform.

Author

Hu, Haibo, Zhou, Yu, Yi, Ailun, Bao, Tongyuan, Liu, Chengying, Luo, Qi, Zhang, Yao, Wang, Zi, Li, Qiang, Lu, Dawei, Liu, Zhengtong, Xiao, Shumin, Ou, Xin, and Song, Qinghai

Subjects

NUCLEAR spin, ELECTRON spin, INTEGRATED circuits, SEMICONDUCTORS

Abstract

Quantum photonic integrated circuits are reshaping quantum networks and sensing by providing compact, efficient platforms for practical quantum applications. Despite continuous breakthroughs, integrating entangled registers into photonic devices on a CMOS-compatible platform presents significant challenges. Herein, we present single electron-nuclear spin entanglement and its integration into a silicon-carbide-on-insulator (SiCOI) waveguide. We demonstrate the successful generation of single divacancy electron spins and near-unity spin initialization of single 13C nuclear spins. Both single nuclear and electron spin can be coherently controlled and a maximally entangled state with a fidelity of 0.89 has been prepared under ambient conditions. Based on the nanoscale positioning techniques, the entangled quantum register has been further integrated into SiC photonic waveguides for the first time. We find that the intrinsic optical and spin characteristics of the register are well preserved and the fidelity of the entangled state remains as high as 0.88. Our findings highlight the promising prospects of the SiCOI platform as a compelling candidate for future scalable quantum photonic applications. Silicon-carbide-on-insulator is a promising platform for scalable quantum photonic circuits. Here the authors demonstrate the integration of a single electron-nuclear spin register into silicon-carbide-on-insulator waveguides, which is an important step toward CMOS-compatible quantum photonic devices. [ABSTRACT FROM AUTHOR]

Published

2024

12. Distillable entanglement under dually non-entangling operations.

Author

Lami, Ludovico and Regula, Bartosz

Subjects

QUANTUM states, QUANTUM theory, PROBLEM solving, DISTILLATION, WINTER

Abstract

Computing the exact rate at which entanglement can be distilled from noisy quantum states is one of the longest-standing questions in quantum information. We give an exact solution for entanglement distillation under the set of dually non-entangling (DNE) operations—a relaxation of the typically considered local operations and classical communication, comprising all channels which preserve the sets of separable states and measurements. We show that the DNE distillable entanglement coincides with a modified version of the regularised relative entropy of entanglement in which the arguments are measured with a separable measurement. Ours is only the second known regularised formula for the distillable entanglement under any class of free operations in entanglement theory, after that given by Devetak and Winter for (one-way) local operations and classical communication. An immediate consequence of our finding is that, under DNE, entanglement can be distilled from any entangled state. As our second main result, we construct a general upper bound on the DNE distillable entanglement, using which we prove that the separably measured relative entropy of entanglement can be strictly smaller than the regularisation of the standard relative entropy of entanglement, solving an open problem posed by Li and Winter. Finally, we study also the reverse task of entanglement dilution and show that the restriction to DNE operations does not change the entanglement cost when compared with the larger class of non-entangling operations. This implies a strong form of irreversiblility of entanglement theory under DNE operations: even when asymptotically vanishing amounts of entanglement may be generated, entangled states cannot be converted reversibly. Computing how much entanglement can be extracted from imperfect quantum states is a long-standing problem in quantum resource theory. Here, Lami and Regula move away from the usual case in which the operations considered free to implement are local operations and classical communication, and find instead a solution for the case of dually non-entangling operations. [ABSTRACT FROM AUTHOR]

Published

2024

13. Individually addressed entangling gates in a two-dimensional ion crystal.

Author

Hou, Y.-H., Yi, Y.-J., Wu, Y.-K., Chen, Y.-Y., Zhang, L., Wang, Y., Xu, Y.-L., Zhang, C., Mei, Q.-X., Yang, H.-X., Ma, J.-Y., Guo, S.-A., Ye, J., Qi, B.-X., Zhou, Z.-C., Hou, P.-Y., and Duan, L.-M.

Subjects

ION traps, ION pairs, QUANTUM gates, QUANTUM computing, QUANTUM information science

Abstract

Two-dimensional (2D) ion crystals may represent a promising path to scale up qubit numbers for ion trap quantum information processing. However, to realize universal quantum computing in this system, individually addressed high-fidelity two-qubit entangling gates still remain challenging due to the inevitable micromotion of ions in a 2D crystal as well as the technical difficulty in 2D addressing. Here we demonstrate two-qubit entangling gates between any ion pairs in a 2D crystal of four ions. We use symmetrically placed crossed acousto-optic deflectors (AODs) to drive Raman transitions and achieve an addressing crosstalk error below 0.1%. We design and demonstrate a gate sequence by alternatingly addressing two target ions, making it compatible with any single-ion addressing techniques without crosstalk from multiple addressing beams. We further examine the gate performance versus the micromotion amplitude of the ions and show that its effect can be compensated by a recalibration of the laser intensity without degrading the gate fidelity. Our work paves the way for ion trap quantum computing with hundreds to thousands of qubits on a 2D ion crystal. Quantum gates in 2D ion crystals are more challenging than in 1D. Here, the authors use their 2D ion trap platform and acousto-optical deflectors to demonstrate a 2-qubit gate that can stand the ion micromotion in such configuration. [ABSTRACT FROM AUTHOR]

Published

2024

14. Spin-photon entanglement with direct photon emission in the telecom C-band.

Author

Laccotripes, P., Müller, T., Stevenson, R. M., Skiba-Szymanska, J., Ritchie, D. A., and Shields, A. J.

Subjects

QUANTUM communication, PICOSECOND pulses, QUANTUM entanglement, QUANTUM computing, TELECOMMUNICATION systems, ELECTRON spin states

Abstract

Quantum networks, relying on the distribution of quantum entanglement between remote locations, have the potential to transform quantum computation and secure long-distance quantum communication. However, a fundamental ingredient for fibre-based implementations of such networks, namely entanglement between a single spin and a photon directly emitted at telecom wavelengths, has been unattainable so far. Here, we use a negatively charged exciton in an InAs/InP quantum dot to implement an optically active spin qubit taking advantage of the lowest-loss transmission window, the telecom C-band. We investigate the coherent interactions of the spin-qubit system under resonant excitation, demonstrating high fidelity spin initialisation and coherent control using picosecond pulses. We further use these tools to measure the coherence of a single, undisturbed electron spin in our system. Finally, we demonstrate spin-photon entanglement in a solid-state system with entanglement fidelity F = 80.07 ± 2.9%, more than 10 standard deviations above the classical limit. Quantum communication networks would greatly benefit from the possibility to have solid-state emitters being directly interfaced with telecom fibers, without the need for wavelength conversion. Here, the authors demonstrate coherent control of an InAs/InP quantum dot, as well as entanglement between its electron spin and the frequency of a telecom photon. [ABSTRACT FROM AUTHOR]

Published

2024

15. Generation of photonic entanglement in green fluorescent proteins.

Author

Siyuan Shi, Kumar, Prem, and Kim Fook Lee

Subjects

GREEN fluorescent protein, PHOTONICS, SPECTROSCOPIC imaging, BIOMATERIALS, POLARIZATION (Nuclear physics)

Abstract

Recent development of spectroscopic techniques based on quantum states of light can precipitate many breakthroughs in observing and controlling light-matter interactions in biological materials on a fundamental quantum level. For this reason, the generation of entangled light in biologically produced fluorescent proteins would be promising because of their biocompatibility. Here we demonstrate the generation of polarization-entangled twophoton state through spontaneous four-wave mixing in enhanced green fluorescent proteins. The reconstructed density matrix indicates that the entangled state is subject to decoherence originating from two-photon absorption. However, the prepared state is less sensitive to environmental decoherence because of the protective β-barrel structure that encapsulates the fluorophore in the protein. We further explore the quantumness, including classical and quantum correlations, of the state in the decoherence environment. Our method for photonic entanglement generation may have potential for developing quantum spectroscopic techniques and quantum-enhanced measurements in biological materials. [ABSTRACT FROM AUTHOR]

Published

2017

16. Photonic simulation of entanglement growth and engineering after a spin chain quench.

Author

Pitsios, Ioannis, Banchi, Leonardo, Rab, Adil S., Bentivegna, Marco, Caprara, Debora, Crespi, Andrea, Spagnolo, Nicolò, Bose, Sougato, Mataloni, Paolo, Osellame, Roberto, and Sciarrino, Fabio

Subjects

QUANTUM entanglement, METAL quenching

Abstract

The time evolution of quantum many-body systems is one of the most important processes for benchmarking quantum simulators. The most curious feature of such dynamics is the growth of quantum entanglement to an amount proportional to the system size (volume law) even when interactions are local. This phenomenon has great ramifications for fundamental aspects, while its optimisation clearly has an impact on technology (e.g., for on-chip quantum networking). Here we use an integrated photonic chip with a circuit-based approach to simulate the dynamics of a spin chain and maximise the entanglement generation. The resulting entanglement is certified by constructing a second chip, which measures the entanglement between multiple distant pairs of simulated spins, as well as the block entanglement entropy. This is the first photonic simulation and optimisation of the extensive growth of entanglement in a spin chain, and opens up the use of photonic circuits for optimising quantum devices. [ABSTRACT FROM AUTHOR]

Published

2017

17. Room-temperature quantum nanoplasmonic coherent perfect absorption.

Author

Lai, Yiming, Clarke, Daniel D. A., Grimm, Philipp, Devi, Asha, Wigger, Daniel, Helbig, Tobias, Hofmann, Tobias, Thomale, Ronny, Huang, Jer-Shing, Hecht, Bert, and Hess, Ortwin

Subjects

QUANTUM states, QUANTUM perturbations, QUANTUM electrodynamics, QUANTUM information science, DECOHERENCE (Quantum mechanics), ABSORPTION, EXCITED states

Abstract

Light-matter superposition states obtained via strong coupling play a decisive role in quantum information processing, but the deleterious effects of material dissipation and environment-induced decoherence inevitably destroy coherent light-matter polaritons over time. Here, we propose the use of coherent perfect absorption under near-field driving to prepare and protect the polaritonic states of a single quantum emitter interacting with a plasmonic nanocavity at room temperature. Our scheme of quantum nanoplasmonic coherent perfect absorption leverages an inherent frequency specificity to selectively initialize the coupled system in a chosen plasmon-emitter dressed state, while the coherent, unidirectional and non-perturbing near-field energy transfer from a proximal plasmonic waveguide can in principle render the dressed state robust against dynamic dissipation under ambient conditions. Our study establishes a previously unexplored paradigm for quantum state preparation and coherence preservation in plasmonic cavity quantum electrodynamics, offering compelling prospects for elevating quantum nanophotonic technologies to ambient temperatures. Quantum states are incredibly sensitive to their environment, making them perfect for ultrasensitive quantum detection—if they can be maintained long enough. Here, the authors showed that they can 'immortalize' the excited state of a coupled light-matter system using a technique called 'coherent perfect absorption'. [ABSTRACT FROM AUTHOR]

Published

2024

18. Squeezed light from an oscillator measured at the rate of oscillation.

Author

Bærentsen, Christian, Fedorov, Sergey A., Østfeldt, Christoffer, Balabas, Mikhail V., Zeuthen, Emil, and Polzik, Eugene S.

Subjects

SQUEEZED light, QUANTUM measurement, OSCILLATIONS, OPTICAL polarization, RESONANCE, HARMONIC oscillators

Abstract

Sufficiently fast continuous measurements of the position of an oscillator approach measurements projective on position eigenstates. We evidence the transition into the projective regime for a spin oscillator within an ensemble of 2 × 1010 room-temperature atoms by observing correlations between the quadratures of the meter light field. These correlations squeeze the fluctuations of one light quadrature below the vacuum level. When the measurement is slower than the oscillation, we generate 11. 5 − 1.5 + 2.5 dB and detect 8. 5 − 0.1 + 0.1 dB of squeezing in a tunable band that is a fraction of the resonance frequency. When the measurement is as fast as the oscillation, we detect 4.7 dB of squeezing that spans more than one decade of frequencies below the resonance. Our results demonstrate a new regime of continuous quantum measurements on material oscillators, and set a new benchmark for the performance of a linear quantum sensor. The authors demonstrated an unprecedented level of polarization squeezing of light generated by an atomic ensemble, and a new regime of continuous quantum measurements on a macroscopic material oscillator. [ABSTRACT FROM AUTHOR]

Published

2024

19. Reversibility of quantum resources through probabilistic protocols.

Author

Regula, Bartosz and Lami, Ludovico

Abstract

Among the most fundamental questions in the manipulation of quantum resources such as entanglement is the possibility of reversibly transforming all resource states. The key consequence of this would be the identification of a unique entropic resource measure that exactly quantifies the limits of achievable transformation rates. Remarkably, previous results claimed that such asymptotic reversibility holds true in very general settings; however, recently those findings have been found to be incomplete, casting doubt on the conjecture. Here we show that it is indeed possible to reversibly interconvert all states in general quantum resource theories, as long as one allows protocols that may only succeed probabilistically. Although such transformations have some chance of failure, we show that their success probability can be ensured to be bounded away from zero, even in the asymptotic limit of infinitely many manipulated copies. As in previously conjectured approaches, the achievability here is realised through operations that are asymptotically resource non-generating, and we show that this choice is optimal: smaller sets of transformations cannot lead to reversibility. Our methods are based on connecting the transformation rates under probabilistic protocols with strong converse rates for deterministic transformations, which we strengthen into an exact equivalence in the case of entanglement distillation. [ABSTRACT FROM AUTHOR]

Published

2024

20. Demonstration of hypergraph-state quantum information processing.

Author

Huang, Jieshan, Li, Xudong, Chen, Xiaojiong, Zhai, Chonghao, Zheng, Yun, Chi, Yulin, Li, Yan, He, Qiongyi, Gong, Qihuang, and Wang, Jianwei

Subjects

QUANTUM information science, QUANTUM computing, QUBITS, HUMAN information processing, SILICON isotopes, HYPERGRAPHS

Abstract

Complex entangled states are the key resources for measurement-based quantum computations, which is realised by performing a sequence of measurements on initially entangled qubits. Executable quantum algorithms in the graph-state quantum computing model are determined by the entanglement structure and the connectivity of entangled qubits. By generalisation from graph-type entanglement in which only the nearest qubits interact to a new type of hypergraph entanglement in which any subset of qubits can be arbitrarily entangled via hyperedges, hypergraph states represent more general resource states that allow arbitrary quantum computation with Pauli universality. Here we report experimental preparation, certification and processing of complete categories of four-qubit hypergraph states under the principle of local unitary equivalence, on a fully reprogrammable silicon-photonic quantum chip. Genuine multipartite entanglement for hypergraph states is certificated by the characterisation of entanglement witness, and the observation of violations of Mermin inequalities without any closure of distance or detection loopholes. A basic measurement-based protocol and an efficient resource state verification by color-encoding stabilizers are implemented with local Pauli measurement to benchmark the building blocks for hypergraph-state quantum computation. Our work prototypes hypergraph entanglement as a general resource for quantum information processing. [ABSTRACT FROM AUTHOR]

Published

2024

21. Hermitian and non-Hermitian topology from photon-mediated interactions.

Author

Roccati, Federico, Bello, Miguel, Gong, Zongping, Ueda, Masahito, Ciccarello, Francesco, Chenu, Aurélia, and Carollo, Angelo

Subjects

TOPOLOGICAL property, TOPOLOGY, GROUP velocity, QUANTUM cryptography, HARDY spaces

Abstract

As light can mediate interactions between atoms in a photonic environment, engineering it for endowing the photon-mediated Hamiltonian with desired features, like robustness against disorder, is crucial in quantum research. We provide general theorems on the topology of photon-mediated interactions in terms of both Hermitian and non-Hermitian topological invariants, unveiling the phenomena of topological preservation and reversal, and revealing a system-bath topological correspondence. Depending on the Hermiticity of the environment and the parity of the spatial dimension, the atomic and photonic topological invariants turn out to be equal or opposite. Consequently, the emergence of atomic and photonic topological boundary modes with opposite group velocities in two-dimensional Hermitian topological systems is established. Owing to its general applicability, our results can guide the design of topological systems. Topological properties of a photonic environment are crucial to engineer robust photon-mediated interactions between quantum emitters. Here, the authors find general theorems on the topology of photon-mediated interactions, unveiling the phenomena of topological preservation and reversal. [ABSTRACT FROM AUTHOR]

Published

2024

22. Cavity-coupled telecom atomic source in silicon.

Author

Johnston, Adam, Felix-Rendon, Ulises, Yu-En Wong, and Songtao Chen

Abstract

Novel T centers in silicon hold great promise for quantum networking applications due to their telecom band optical transitions and the long-lived ground state electronic spins. An open challenge for advancing the T center platform is to enhance its weak and slow zero phonon line (ZPL) emission. In this work, by integrating single T centers with a low-loss, small mode-volume silicon photonic crystal cavity, we demonstrate an enhancement of the fluorescence decay rate by a factor of F = 6.89. Efficient photon extraction enables the system to achieve an average ZPL photon outcoupling rate of 73.3 kHz under saturation, which is about two orders of magnitude larger than the previously reported value. The dynamics of the coupled system is well modeled by solving the Lindblad master equation. These results represent a significant step towards building efficient T center spin-photon interfaces for quantum information processing and networking applications. [ABSTRACT FROM AUTHOR]

Published

2024

23. Thermally robust spin correlations between two 85Rb atoms in an optical microtrap.

Author

Sompet, Pimonpan, Szigeti, Stuart S., Schwartz, Eyal, Bradley, Ashton S., and Andersen, Mikkel F.

Abstract

The complex collisional properties of atoms fundamentally limit investigations into a range of processes in many-atom ensembles. In contrast, the bottom-up assembly of few- and many-body systems from individual atoms offers a controlled approach to isolating and studying such collisional processes. Here, we use optical tweezers to individually assemble pairs of trapped 85Rb atoms, and study the spin dynamics of the two-body system in a thermal state. The spin-2 atoms show strong pair correlation between magnetic sublevels on timescales exceeding one second, with measured relative number fluctuations 11.9 ± 0.3 dB below quantum shot noise, limited only by detection efficiency. Spin populations display relaxation dynamics consistent with simulations and theoretical predictions for 85Rb spin interactions, and contrary to the coherent spin waves witnessed in finite-temperature many-body experiments and zero-temperature two-body experiments. Our experimental approach offers a versatile platform for studying two-body quantum dynamics and may provide a route to thermally robust entanglement generation. Spin-changing atomic collisions are important for thermally robust entanglement generation with applications in quantum information. Here the authors demonstrate record high spin state correlations and long spin relaxation times in the collision of two Rb atoms at relatively warm temperatures. [ABSTRACT FROM AUTHOR]

Published

2019

24. Effective light cone and digital quantum simulation of interacting bosons.

Author

Kuwahara, Tomotaka, Vu, Tan Van, and Saito, Keiji

Abstract

The speed limit of information propagation is one of the most fundamental features in non-equilibrium physics. The region of information propagation by finite-time dynamics is approximately restricted inside the effective light cone that is formulated by the Lieb-Robinson bound. To date, extensive studies have been conducted to identify the shape of effective light cones in most experimentally relevant many-body systems. However, the Lieb-Robinson bound in the interacting boson systems, one of the most ubiquitous quantum systems in nature, has remained a critical open problem for a long time. This study reveals a tight effective light cone to limit the information propagation in interacting bosons, where the shape of the effective light cone depends on the spatial dimension. To achieve it, we prove that the speed for bosons to clump together is finite, which in turn leads to the error guarantee of the boson number truncation at each site. Furthermore, we applied the method to provide a provably efficient algorithm for simulating the interacting boson systems. The results of this study settle the notoriously challenging problem and provide the foundation for elucidating the complexity of many-body boson systems.Studying bounds on the speed of information propagation across interacting boson systems is notoriously difficult. Here, the authors find tight bounds for both the transport of boson particles and information propagation, for arbitrary time-dependent Bose-Hubbard-type Hamiltonians in arbitrary dimensions. [ABSTRACT FROM AUTHOR]

Published

2024

25. Gravitationally induced decoherence vs space-time diffusion: testing the quantum nature of gravity.

Author

Oppenheim, Jonathan, Sparaciari, Carlo, Šoda, Barbara, and Weller-Davies, Zachary

Abstract

We consider two interacting systems when one is treated classically while the other system remains quantum. Consistent dynamics of this coupling has been shown to exist, and explored in the context of treating space-time classically. Here, we prove that any such hybrid dynamics necessarily results in decoherence of the quantum system, and a breakdown in predictability in the classical phase space. We further prove that a trade-off between the rate of this decoherence and the degree of diffusion induced in the classical system is a general feature of all classical quantum dynamics; long coherence times require strong diffusion in phase-space relative to the strength of the coupling. Applying the trade-off relation to gravity, we find a relationship between the strength of gravitationally-induced decoherence versus diffusion of the metric and its conjugate momenta. This provides an experimental signature of theories in which gravity is fundamentally classical. Bounds on decoherence rates arising from current interferometry experiments, combined with precision measurements of mass, place significant restrictions on theories where Einstein’s classical theory of gravity interacts with quantum matter. We find that part of the parameter space of such theories are already squeezed out, and provide figures of merit which can be used in future mass measurements and interference experiments.Consistent theories have been proposed in which spacetime is treated classically while matter remains quantum. Here, the authors prove that such theories are constrained by a trade-off between the decoherence induced in the quantum system, and stochasticity in the classical one, providing a way to experimentally test the quantum nature of gravity. [ABSTRACT FROM AUTHOR]

Published

2023

26. Coherent optical control of a superconducting microwave cavity via electro-optical dynamical back-action

Author

Liu Qiu, Rishabh Sahu, William Hease, Georg Arnold, and Johannes M. Fink

Subjects

Science

Abstract

Abstract Recent quantum technologies have established precise quantum control of various microscopic systems using electromagnetic waves. Interfaces based on cryogenic cavity electro-optic systems are particularly promising, due to the direct interaction between microwave and optical fields in the quantum regime. Quantum optical control of superconducting microwave circuits has been precluded so far due to the weak electro-optical coupling as well as quasi-particles induced by the pump laser. Here we report the coherent control of a superconducting microwave cavity using laser pulses in a multimode electro-optical device at millikelvin temperature with near-unity cooperativity. Both the stationary and instantaneous responses of the microwave and optical modes comply with the coherent electro-optical interaction, and reveal only minuscule amount of excess back-action with an unanticipated time delay. Our demonstration enables wide ranges of applications beyond quantum transductions, from squeezing and quantum non-demolition measurements of microwave fields, to entanglement generation and hybrid quantum networks.

Published

2023

27. Synchronization of spin-driven limit cycle oscillators optically levitated in vacuum.

Author

Brzobohatý, Oto, Duchaň, Martin, Jákl, Petr, Ježek, Jan, Šiler, Martin, Zemánek, Pavel, and Simpson, Stephen H.

Subjects

LIMIT cycles, THERMODYNAMIC equilibrium, SYNCHRONIZATION, PARTICLE motion, HOPF bifurcations, NONLINEAR oscillators, MOTION

Abstract

We explore, experimentally and theoretically, the emergence of coherent coupled oscillations and synchronization between a pair of non-Hermitian, stochastic, opto-mechanical oscillators, levitated in vacuum. Each oscillator consists of a polystyrene microsphere trapped in a circularly polarized, counter-propagating Gaussian laser beam. Non-conservative, azimuthal forces, deriving from inhomogeneous optical spin, push the micro-particles out of thermodynamic equilibrium. For modest optical powers each particle shows a tendency towards orbital circulation. Initially, their stochastic motion is weakly correlated. As the power is increased, the tendency towards orbital circulation strengthens and the motion of the particles becomes highly correlated. Eventually, centripetal forces overcome optical gradient forces and the oscillators undergo a collective Hopf bifurcation. For laser powers exceeding this threshold, a pair of limit cycles appear, which synchronize due to weak optical and hydrodynamic interactions. In principle, arrays of such Non-Hermitian elements can be arranged, paving the way for opto-mechanical topological materials or, possibly, classical time crystals. In addition, the preparation of synchronized states in levitated optomechanics could lead to new and robust sensors or alternative routes to the entanglement of macroscopic objects. Researchers investigate synchronized oscillations of two microspheres optically levitated in vacuum, paving the way for numerous future applications, from classical time crystals to robust sensors or the entanglement of macroscopic objects. [ABSTRACT FROM AUTHOR]

Published

2023

28. Thermally robust spin correlations between two 85Rb atoms in an optical microtrap

Author

Sompet, Pimonpan, Szigeti, Stuart S., Schwartz, Eyal, Bradley, Ashton S., and Andersen, Mikkel F.

Published

2019

29. Cavity-enhanced single-shot readout of a quantum dot spin within 3 nanoseconds.

Author

Antoniadis, Nadia O., Hogg, Mark R., Stehl, Willy F., Javadi, Alisa, Tomm, Natasha, Schott, Rüdiger, Valentin, Sascha R., Wieck, Andreas D., Ludwig, Arne, and Warburton, Richard J.

Abstract

Rapid, high-fidelity single-shot readout of quantum states is a ubiquitous requirement in quantum information technologies. For emitters with a spin-preserving optical transition, spin readout can be achieved by driving the transition with a laser and detecting the emitted photons. The speed and fidelity of this approach is typically limited by low photon collection rates and measurement back-action. Here we use an open microcavity to enhance the optical readout signal from a semiconductor quantum dot spin state, largely overcoming these limitations. We achieve single-shot readout of an electron spin in only 3 nanoseconds with a fidelity of (95.2 ± 0.7)%, and observe quantum jumps using repeated single-shot measurements. Owing to the speed of our readout, errors resulting from measurement-induced back-action have minimal impact. Our work reduces the spin readout-time well below both the achievable spin relaxation and dephasing times in semiconductor quantum dots, opening up new possibilities for their use in quantum technologies.Single-shot readout of optically active spin qubits is typically limited by low photon collection rates and measurement back-action. Here the authors overcome these limitations by using an open cavity approach for single-shot readout of a semiconductor quantum dot and demonstrate record readout time of a few ns. [ABSTRACT FROM AUTHOR]

Published

2023

30. Demonstration of quantum-digital payments.

Author

Schiansky, Peter, Kalb, Julia, Sztatecsny, Esther, Roehsner, Marie-Christine, Guggemos, Tobias, Trenti, Alessandro, Bozzio, Mathieu, and Walther, Philip

Subjects

ELECTRONIC funds transfers, INFORMATION-theoretic security, QUANTUM cryptography, OPTICAL fibers, PHOTONS, DATA security failures, NEAR field communication, EMAIL security

Abstract

Digital payments have replaced physical banknotes in many aspects of our daily lives. Similarly to banknotes, they should be easy to use, unique, tamper-resistant and untraceable, but additionally withstand digital attackers and data breaches. Current technology substitutes customers' sensitive data by randomized tokens, and secures the payment's uniqueness with a cryptographic function, called a cryptogram. However, computationally powerful attacks violate the security of these functions. Quantum technology comes with the potential to protect even against infinite computational power. Here, we show how quantum light can secure daily digital payments by generating inherently unforgeable quantum cryptograms. We implement the scheme over an urban optical fiber link, and show its robustness to noise and loss-dependent attacks. Unlike previously proposed protocols, our solution does not depend on long-term quantum storage or trusted agents and authenticated channels. It is practical with near-term technology and may herald an era of quantum-enabled security. There are different quantum algorithms developed for the security of current cryptographic concepts. Here the authors demonstrate a method to perform quantum-secured digital payments using unforgeable quantum cryptograms over an optical fiber link and verify the information-theoretic security. [ABSTRACT FROM AUTHOR]

Published

2023

31. Native qudit entanglement in a trapped ion quantum processor.

Author

Hrmo, Pavel, Wilhelm, Benjamin, Gerster, Lukas, van Mourik, Martin W., Huber, Marcus, Blatt, Rainer, Schindler, Philipp, Monz, Thomas, and Ringbauer, Martin

Subjects

ION traps, HILBERT space, QUBITS, CALIBRATION

Abstract

Quantum information carriers, just like most physical systems, naturally occupy high-dimensional Hilbert spaces. Instead of restricting them to a two-level subspace, these high-dimensional (qudit) quantum systems are emerging as a powerful resource for the next generation of quantum processors. Yet harnessing the potential of these systems requires efficient ways of generating the desired interaction between them. Here, we experimentally demonstrate an implementation of a native two-qudit entangling gate up to dimension 5 in a trapped-ion system. This is achieved by generalizing a recently proposed light-shift gate mechanism to generate genuine qudit entanglement in a single application of the gate. The gate seamlessly adapts to the local dimension of the system with a calibration overhead that is independent of the dimension. Encoding quantum information in qudits instead of qubits allows for several advantages, but scalable native entangling techniques would be needed. Here, the authors show how to use light-shift gates to perform entangling operations on trapped ion systems, with a calibration overhead which is independent on the qudit dimension. [ABSTRACT FROM AUTHOR]

Published

2023

32. Prethermalization in one-dimensional quantum many-body systems with confinement.

Author

Birnkammer, Stefan, Bastianello, Alvise, and Knap, Michael

Subjects

THERMAL neutrons, QUANTUM spin models, THERMAL equilibrium, MESONS, QUANTUM theory, SYSTEM dynamics

Abstract

Unconventional nonequilibrium phases with restricted correlation spreading and slow entanglement growth have been proposed to emerge in systems with confined excitations, calling their thermalization dynamics into question. Here, we show that in confined systems the thermalization dynamics after a quantum quench instead exhibits multiple stages with well separated time scales. As an example, we consider the confined Ising spin chain, in which domain walls in the ordered phase form bound states reminiscent of mesons. The system first relaxes towards a prethermal state, described by a Gibbs ensemble with conserved meson number. The prethermal state arises from rare events in which mesons are created in close vicinity, leading to an avalanche of scattering events. Only at much later times a true thermal equilibrium is achieved in which the meson number conservation is violated by a mechanism akin to the Schwinger effect. The discussed prethermalization dynamics is directly relevant to generic one-dimensional, many-body systems with confined excitations. Some quantum spin models provide a condensed-matter realization of confinement, and previous work has shown that confinement affects the way they thermalize. Here the authors demonstrate for a many-body model with confinement that thermalization dynamics occurs in multiple stages, starting with a prethermal state. [ABSTRACT FROM AUTHOR]

Published

2022

33. Quantum physics in connected worlds.

Author

Tindall, Joseph, Searle, Amy, Alhajri, Abdulla, and Jaksch, Dieter

Subjects

QUANTUM theory, DENSE graphs, PHASES of matter, RANDOM graphs, UNIT cell

Abstract

Theoretical research into many-body quantum systems has mostly focused on regular structures which have a small, simple unit cell and where a vanishingly small fraction of the pairs of the constituents directly interact. Motivated by advances in control over the pairwise interactions in many-body simulators, we determine the fate of spin systems on more general, arbitrary graphs. Placing the minimum possible constraints on the underlying graph, we prove how, with certainty in the thermodynamic limit, such systems behave like a single collective spin. We thus understand the emergence of complex many-body physics as dependent on 'exceptional', geometrically constrained structures such as the low-dimensional, regular ones found in nature. Within the space of dense graphs we identify hitherto unknown exceptions via their inhomogeneity and observe how complexity is heralded in these systems by entanglement and highly non-uniform correlation functions. Our work paves the way for the discovery and exploitation of a whole class of geometries which can host uniquely complex phases of matter. Quantum simulators allow for experimental studies of many-body systems in complex geometries, which has rarely been addressed by theory. Here the authors study many-body Hamiltonians on generic random graphs and show that many-body effects emerge only in a small class of exceptional, highly structured graphs. [ABSTRACT FROM AUTHOR]

Published

2022

34. Continuous entanglement distribution over a transnational 248 km fiber link.

Author

Neumann, Sebastian Philipp, Buchner, Alexander, Bulla, Lukas, Bohmann, Martin, and Ursin, Rupert

Subjects

CONTINUOUS distributions, OPTICAL dispersion, QUANTUM communication, QUANTUM cryptography, PHOTON pairs, BIT rate, FIBERS

Abstract

Reliable long-distance distribution of entanglement is a key technique for many quantum applications, most notably quantum key distribution. Here, we present a continuously working, trusted-node free international link between Austria and Slovakia, directly distributing polarization-entangled photon pairs via 248 km of deployed telecommunication fiber. Despite 79 dB loss, we observe stable detected pair rates of 9 s−1 over 110 h. We mitigate multi-pair detections with strict temporal filtering, enabled by nonlocal compensation of chromatic dispersion and superconducting nanowire detectors. Fully automatized active polarization stabilization keeps the entangled state's visibility at 86% for altogether 82 h. In a quantum cryptography context, this corresponds to an asymptotic secure key rate of 1.4 bits/s and 258 kbit of total key, considering finite-key effects. Our work paves the way for low-maintenance, ultra-stable quantum communication over long distances, independent of weather conditions and time of day, thus constituting an important step towards the quantum internet. Fibre-based entanglement distribution represents a key primitive for quantum applications such as QKD. Here, the authors demonstrate it across 248 km of deployed fiber, observing stable detected pair rates of 9 Hz for 110 h. [ABSTRACT FROM AUTHOR]

Published

2022

35. Scaling behavior of electron decoherence in a graphene Mach-Zehnder interferometer.

Author

Jo, M., Lee, June-Young M., Assouline, A., Brasseur, P., Watanabe, K., Taniguchi, T., Roche, P., Glattli, D. C., Kumada, N., Parmentier, F. D., Sim, H. -S., and Roulleau, P.

Subjects

GRAPHENE, ELECTRONS, ELECTRONIC probes, LOW temperatures, INTERFEROMETERS, HIGH temperatures

Abstract

Over the past 20 years, many efforts have been made to understand and control decoherence in 2D electron systems. In particular, several types of electronic interferometers have been considered in GaAs heterostructures, in order to protect the interfering electrons from decoherence. Nevertheless, it is now understood that several intrinsic decoherence sources fundamentally limit more advanced quantum manipulations. Here, we show that graphene offers a unique possibility to reach a regime where the decoherence is frozen and to study unexplored regimes of electron interferometry. We probe the decoherence of electron channels in a graphene quantum Hall PN junction, forming a Mach-Zehnder interferometer1,2, and unveil a scaling behavior of decay of the interference visibility with the temperature scaled by the interferometer length. It exhibits a remarkable crossover from an exponential decay at higher temperature to an algebraic decay at lower temperature where almost no decoherence occurs, a regime previously unobserved in GaAs interferometers. Quantum Hall edge channels provide a platform to study electron interference, however understanding decoherence in these systems remains an open problem. Jo et al. realize a regime of suppressed decoherence in an electronic Mach-Zehnder interferometer formed in a graphene quantum Hall pn junction. [ABSTRACT FROM AUTHOR]

Published

2022

36. Experimental time-reversed adaptive Bell measurement towards all-photonic quantum repeaters.

Author

Hasegawa, Yasushi, Ikuta, Rikizo, Matsuda, Nobuyuki, Tamaki, Kiyoshi, Lo, Hoi-Kwong, Yamamoto, Takashi, Azuma, Koji, and Imoto, Nobuyuki

Abstract

An all-optical network is identified as a promising infrastructure for fast and energy-efficient communication. Recently, it has been shown that its quantum version based on 'all-photonic quantum repeaters'—inheriting, at least, the same advantages—expands its possibility to the quantum realm, that is, a global quantum internet with applications far beyond the conventional Internet. Here we report a proof-of-principle experiment for a key component for the all-photonic repeaters—called all-photonic time-reversed adaptive (TRA) Bell measurement, with a proposal for the implementation. In particular, our TRA measurement—based only on optical devices without any quantum memories and any quantum error correction—passively but selectively performs the Bell measurement only on single photons that have successfully survived their lossy travel over optical channels. In fact, our experiment shows that only the survived single-photon state is faithfully teleported without the disturbance from the other lost photons, as the theory predicts. Storage-free quantum repeaters represent a viable alternative to quantum-memory-based ones. Here, the authors propose a modified scheme for Bell state measurements which reduces the necessary resources for realising such an all-photonic repeater, and show a proof-of-principle implementation. [ABSTRACT FROM AUTHOR]

Published

2019

37. Two-colour high-purity Einstein-Podolsky-Rosen photonic state.

Author

Brasil, Tulio Brito, Novikov, Valeriy, Kerdoncuff, Hugo, Lassen, Mikael, and Polzik, Eugene S.

Subjects

QUANTUM correlations, SQUEEZED light, WAVELENGTHS

Abstract

We report a high-purity Einstein-Podolsky-Rosen (EPR) state between light modes with the wavelengths separated by more than 200 nm. We demonstrate highly efficient EPR-steering between the modes with the product of conditional variances E 2 = 0.11 ± 0.01 ≪ 1 . The modes display − 7.7 ± 0.5 dB of two-mode squeezing and an overall state purity of 0.63 ± 0.16. EPR-steering is observed over five octaves of sideband frequencies from RF down to audio-band. The demonstrated combination of high state purity, strong quantum correlations, and extended frequency range enables new matter-light quantum protocols. Engineering quantum correlations between light modes at different frequency would open new avenues for quantum networks and sensing. Here, the authors propose and demonstrate a way for obtaining high-purity strongly entangled continuous variable states with more than 200 nm difference in wavelength. [ABSTRACT FROM AUTHOR]

Published

2022

38. Transmon platform for quantum computing challenged by chaotic fluctuations.

Author

Berke, Christoph, Varvelis, Evangelos, Trebst, Simon, Altland, Alexander, and DiVincenzo, David P.

Subjects

COMPUTING platforms, LOCALIZATION theory, WAVE functions, BALANCE disorders, QUBITS, IMAGE encryption

Abstract

From the perspective of many-body physics, the transmon qubit architectures currently developed for quantum computing are systems of coupled nonlinear quantum resonators. A certain amount of intentional frequency detuning ('disorder') is crucially required to protect individual qubit states against the destabilizing effects of nonlinear resonator coupling. Here we investigate the stability of this variant of a many-body localized phase for system parameters relevant to current quantum processors developed by the IBM, Delft, and Google consortia, considering the cases of natural or engineered disorder. Applying three independent diagnostics of localization theory — a Kullback–Leibler analysis of spectral statistics, statistics of many-body wave functions (inverse participation ratios), and a Walsh transform of the many-body spectrum — we find that some of these computing platforms are dangerously close to a phase of uncontrollable chaotic fluctuations. Superconducting quantum processors need to balance intentional disorder (to protect qubits) and nonlinear resonator coupling (to manipulate qubits), while avoiding chaotic instabilities. Berke et al. use the techniques of many-body localization theory to study the stability of current platforms against quantum chaos. [ABSTRACT FROM AUTHOR]

Published

2022

39. Thermally robust spin correlations between two

Author

Pimonpan, Sompet, Stuart S, Szigeti, Eyal, Schwartz, Ashton S, Bradley, and Mikkel F, Andersen

Subjects

Quantum physics, Atomic and molecular collision processes, Ultracold gases, Article

Abstract

The complex collisional properties of atoms fundamentally limit investigations into a range of processes in many-atom ensembles. In contrast, the bottom-up assembly of few- and many-body systems from individual atoms offers a controlled approach to isolating and studying such collisional processes. Here, we use optical tweezers to individually assemble pairs of trapped 85Rb atoms, and study the spin dynamics of the two-body system in a thermal state. The spin-2 atoms show strong pair correlation between magnetic sublevels on timescales exceeding one second, with measured relative number fluctuations 11.9 ± 0.3 dB below quantum shot noise, limited only by detection efficiency. Spin populations display relaxation dynamics consistent with simulations and theoretical predictions for 85Rb spin interactions, and contrary to the coherent spin waves witnessed in finite-temperature many-body experiments and zero-temperature two-body experiments. Our experimental approach offers a versatile platform for studying two-body quantum dynamics and may provide a route to thermally robust entanglement generation., Spin-changing atomic collisions are important for thermally robust entanglement generation with applications in quantum information. Here the authors demonstrate record high spin state correlations and long spin relaxation times in the collision of two Rb atoms at relatively warm temperatures.

Published

2018

40. Bidirectional interconversion of microwave and light with thin-film lithium niobate.

Author

Xu, Yuntao, Sayem, Ayed Al, Fan, Linran, Zou, Chang-Ling, Wang, Sihao, Cheng, Risheng, Fu, Wei, Yang, Likai, Xu, Mingrui, and Tang, Hong X.

Subjects

LITHIUM niobate, PHOTOREFRACTIVE effect, MICROWAVES, HYBRID systems, MICROWAVE photonics, SUPERCONDUCTING circuits

Abstract

Superconducting cavity electro-optics presents a promising route to coherently convert microwave and optical photons and distribute quantum entanglement between superconducting circuits over long-distance. Strong Pockels nonlinearity and high-performance optical cavity are the prerequisites for high conversion efficiency. Thin-film lithium niobate (TFLN) offers these desired characteristics. Despite significant recent progresses, only unidirectional conversion with efficiencies on the order of 10−5 has been realized. In this article, we demonstrate the bidirectional electro-optic conversion in TFLN-superconductor hybrid system, with conversion efficiency improved by more than three orders of magnitude. Our air-clad device architecture boosts the sustainable intracavity pump power at cryogenic temperatures by suppressing the prominent photorefractive effect that limits cryogenic performance of TFLN, and reaches an efficiency of 1.02% (internal efficiency of 15.2%). This work firmly establishes the TFLN-superconductor hybrid EO system as a highly competitive transduction platform for future quantum network applications. Coherent conversion between optical and microwave photonics is needed for future quantum applications. Here, the authors combine thin-film lithium niobate and superconductor platforms as a hybrid electro-optic system to achieve high-efficiency frequency conversion between microwave and optical modes. [ABSTRACT FROM AUTHOR]

Published

2021

41. Room-temperature single-photon source with near-millisecond built-in memory.

Author

Dideriksen, Karsten B., Schmieg, Rebecca, Zugenmaier, Michael, and Polzik, Eugene S.

Subjects

BELL'S theorem, SINGLE photon generation, PHOTON emission, QUANTUM information science, MEMORY

Abstract

Non-classical photon sources are a crucial resource for distributed quantum networks. Photons generated from matter systems with memory capability are particularly promising, as they can be integrated into a network where each source is used on-demand. Among all kinds of solid state and atomic quantum memories, room-temperature atomic vapours are especially attractive due to their robustness and potential scalability. To-date room-temperature photon sources have been limited either in their memory time or the purity of the photonic state. Here we demonstrate a single-photon source based on room-temperature memory. Following heralded loading of the memory, a single photon is retrieved from it after a variable storage time. The single-photon character of the retrieved field is validated by the strong suppression of the two-photon component with antibunching as low as g RR∣W=1 (2) = 0.20 ± 0.07 . Non-classical correlations between the heralding and the retrieved photons are maintained for up to τ NC R = (0.68 ± 0.08) ms , more than two orders of magnitude longer than previously demonstrated with other room-temperature systems. Correlations sufficient for violating Bell inequalities exist for up to τBI = (0.15 ± 0.03) ms. Room-temperature single photon sources with memory capabilities are promising for quantum information processing, but are currently limited in their memory time or photon purity. Here, the authors report single photon emission with good antibunching from an atomic vapour cell source with 0.68 ms memory time. [ABSTRACT FROM AUTHOR]

Published

2021

42. Entanglement of dark electron-nuclear spin defects in diamond.

Author

Degen, M. J., Loenen, S. J. H., Bartling, H. P., Bradley, C. E., Meinsma, A. L., Markham, M., Twitchen, D. J., and Taminiau, T. H.

Subjects

NUCLEAR spin, QUANTUM phase transitions, ELECTRON spin, QUBITS, QUANTUM information science, DEGREES of freedom, DIAMONDS

Abstract

A promising approach for multi-qubit quantum registers is to use optically addressable spins to control multiple dark electron-spin defects in the environment. While recent experiments have observed signatures of coherent interactions with such dark spins, it is an open challenge to realize the individual control required for quantum information processing. Here, we demonstrate the heralded initialisation, control and entanglement of individual dark spins associated to multiple P1 centers, which are part of a spin bath surrounding a nitrogen-vacancy center in diamond. We realize projective measurements to prepare the multiple degrees of freedom of P1 centers—their Jahn-Teller axis, nuclear spin and charge state—and exploit these to selectively access multiple P1s in the bath. We develop control and single-shot readout of the nuclear and electron spin, and use this to demonstrate an entangled state of two P1 centers. These results provide a proof-of-principle towards using dark electron-nuclear spin defects as qubits for quantum sensing, computation and networks. The use of optically addressable spins to control dark electron-spins is promising for multi-qubit platforms; however, control over darks spins has remained challenging. Here, the authors realize entanglement between individual dark spins associated with substitutional nitrogen defects in diamond. [ABSTRACT FROM AUTHOR]

Published

2021

43. The tight Second Law inequality for coherent quantum systems and finite-size heat baths.

Author

Łobejko, Marcin

Subjects

QUANTUM thermodynamics, SECOND law of thermodynamics, BATHS, ENERGY storage

Abstract

In classical thermodynamics, the optimal work is given by the free energy difference, what according to the result of Skrzypczyk et al. can be generalized for individual quantum systems. The saturation of this bound, however, requires an infinite bath and ideal energy storage that is able to extract work from coherences. Here we present the tight Second Law inequality, defined in terms of the ergotropy (rather than free energy), that incorporates both of those important microscopic effects – the locked energy in coherences and the locked energy due to the finite-size bath. The former is solely quantified by the so-called control-marginal state, whereas the latter is given by the free energy difference between the global passive state and the equilibrium state. Furthermore, we discuss the thermodynamic limit where the finite-size bath correction vanishes, and the locked energy in coherences takes the form of the entropy difference. We supplement our results by numerical simulations for the heat bath given by the collection of qubits and the Gaussian model of the work reservoir. Quantum versions of the second law of thermodynamics proposed so far required an infinite bath and ideal energy storage in order to be tight. Here, Łobejko loosens these requirements, proving a tight upper bound on the average work that can be extracted in a quantum scenario. [ABSTRACT FROM AUTHOR]

Published

2021

44. Sequential generation of linear cluster states from a single photon emitter.

Author

Istrati, D., Pilnyak, Y., Loredo, J. C., Antón, C., Somaschi, N., Hilaire, P., Ollivier, H., Esmann, M., Cohen, L., Vidro, L., Millet, C., Lemaître, A., Sagnes, I., Harouri, A., Lanco, L., Senellart, P., and Eisenberg, H. S.

Abstract

Light states composed of multiple entangled photons—such as cluster states—are essential for developing and scaling-up quantum computing networks. Photonic cluster states can be obtained from single-photon sources and entangling gates, but so far this has only been done with probabilistic sources constrained to intrinsically low efficiencies, and an increasing hardware overhead. Here, we report the resource-efficient generation of polarization-encoded, individually-addressable photons in linear cluster states occupying a single spatial mode. We employ a single entangling-gate in a fiber loop configuration to sequentially entangle an ever-growing stream of photons originating from the currently most efficient single-photon source technology—a semiconductor quantum dot. With this apparatus, we demonstrate the generation of linear cluster states up to four photons in a single-mode fiber. The reported architecture can be programmed for linear-cluster states of any number of photons, that are required for photonic one-way quantum computing schemes.Generating photonic cluster states using a single non-heralded source and a single entangling gate would optimise scalability and reduce resource overhead. Here, the authors generate up to 4-photon cluster states using a quantum dot coupled to a fibre loop, with a fourfold generation rate of 10 Hz. [ABSTRACT FROM AUTHOR]

Published

2020

45. Fast electrical modulation of strong near-field interactions between erbium emitters and graphene.

Author

Cano, Daniel, Ferrier, Alban, Soundarapandian, Karuppasamy, Reserbat-Plantey, Antoine, Scarafagio, Marion, Tallaire, Alexandre, Seyeux, Antoine, Marcus, Philippe, de Riedmatten, Hugues, Goldner, Philippe, Koppens, Frank H. L., and Tielrooij, Klaas-Jan

Subjects

ERBIUM

Published

2020

46. Quantum walks and Dirac cellular automata on a programmable trapped-ion quantum computer.

Author

Huerta Alderete, C., Singh, Shivani, Nguyen, Nhung H., Zhu, Daiwei, Balu, Radhakrishnan, Monroe, Christopher, Chandrashekar, C. M., and Linke, Norbert M.

Subjects

CELLULAR automata, QUANTUM computers, DIRAC equation, QUANTUM gates, ALGORITHMS, ION traps, QUBITS

Abstract

The quantum walk formalism is a widely used and highly successful framework for modeling quantum systems, such as simulations of the Dirac equation, different dynamics in both the low and high energy regime, and for developing a wide range of quantum algorithms. Here we present the circuit-based implementation of a discrete-time quantum walk in position space on a five-qubit trapped-ion quantum processor. We encode the space of walker positions in particular multi-qubit states and program the system to operate with different quantum walk parameters, experimentally realizing a Dirac cellular automaton with tunable mass parameter. The quantum walk circuits and position state mapping scale favorably to a larger model and physical systems, allowing the implementation of any algorithm based on discrete-time quantum walks algorithm and the dynamics associated with the discretized version of the Dirac equation. Implementations of quantum walks on ion trap quantum computers have been so far limited to the analogue simulation approach. Here, the authors implement a quantum-circuit-based discrete quantum walk in one-dimensional position space, realizing a Dirac cellular automaton with tunable mass parameter. [ABSTRACT FROM AUTHOR]

Published

2020

47. Spin-controlled generation of indistinguishable and distinguishable photons from silicon vacancy centres in silicon carbide.

Author

Morioka, Naoya, Babin, Charles, Nagy, Roland, Gediz, Izel, Hesselmeier, Erik, Liu, Di, Joliffe, Matthew, Niethammer, Matthias, Dasari, Durga, Vorobyov, Vadim, Kolesov, Roman, Stöhr, Rainer, Ul-Hassan, Jawad, Son, Nguyen Tien, Ohshima, Takeshi, Udvarhelyi, Péter, Thiering, Gergő, Gali, Adam, Wrachtrup, Jörg, and Kaiser, Florian

Subjects

SILICON carbide, PHOTONS, NUCLEAR spin, ERROR correction (Information theory), ELECTRONIC equipment

Abstract

Quantum systems combining indistinguishable photon generation and spin-based quantum information processing are essential for remote quantum applications and networking. However, identification of suitable systems in scalable platforms remains a challenge. Here, we investigate the silicon vacancy centre in silicon carbide and demonstrate controlled emission of indistinguishable and distinguishable photons via coherent spin manipulation. Using strong off-resonant excitation and collecting zero-phonon line photons, we show a two-photon interference contrast close to 90% in Hong-Ou-Mandel type experiments. Further, we exploit the system's intimate spin-photon relation to spin-control the colour and indistinguishability of consecutively emitted photons. Our results provide a deep insight into the system's spin-phonon-photon physics and underline the potential of the industrially compatible silicon carbide platform for measurement-based entanglement distribution and photonic cluster state generation. Additional coupling to quantum registers based on individual nuclear spins would further allow for high-level network-relevant quantum information processing, such as error correction and entanglement purification. Defects in silicon carbide can act as single photon sources that also have the benefit of a host material that is already used in electronic devices. Here the authors demonstrate that they can control the distinguishability of the emitted photons by changing the defect spin state. [ABSTRACT FROM AUTHOR]

Published

2020

48. High-fidelity entanglement between a trapped ion and a telecom photon via quantum frequency conversion.

Author

Bock, Matthias, Eich, Pascal, Kucera, Stephan, Kreis, Matthias, Lenhard, Andreas, Becher, Christoph, and Eschner, Jürgen

Subjects

ION traps, PHOTONS, FREQUENCY changers, ATOM trapping, QUANTUM dots

Abstract

Entanglement between a stationary quantum system and a flying qubit is an essential ingredient of a quantum-repeater network. It has been demonstrated for trapped ions, trapped atoms, color centers in diamond, or quantum dots. These systems have transition wavelengths in the blue, red or near-infrared spectral regions, whereas long-range fibercommunication requires wavelengths in the low-loss, low-dispersion telecom regime. A proven tool to interconnect flying qubits at visible/NIR wavelengths to the telecom bands is quantum frequency conversion. Here we use an efficient polarization-preserving frequency converter connecting 854 nm to the telecom O-band at 1310 nm to demonstrate entanglement between a trapped 4OCa+ ion and the polarization state of a telecom photon with a high fidelity of 98.2 ± 0.2%. The unique combination of 99.75 ± 0.18% process fidelity in the polarization-state conversion, 26.5% external frequency conversion efficiency and only 11.4 photons/s conversion-induced unconditional background makes the converter a powerful ion-telecom quantum interface. [ABSTRACT FROM AUTHOR]

Published

2018

49. Quantum engine efficiency bound beyond the second law of thermodynamics.

Author

Niedenzu, Wolfgang, Mukherjee, Victor, Ghosh, Arnab, Kofman, Abraham G., and Kurizki, Gershon

Subjects

QUANTUM thermodynamics, SECOND law of thermodynamics, QUANTUM efficiency, HEAT engines, THERMODYNAMIC laws, STIRLING engines

Abstract

According to the second law, the efficiency of cyclic heat engines is limited by the Carnot bound that is attained by engines that operate between two thermal baths under the reversibility condition whereby the total entropy does not increase. Quantum engines operating between a thermal and a squeezed-thermal bath have been shown to surpass this bound. Yet, their maximum efficiency cannot be determined by the reversibility condition, which may yield an unachievable efficiency bound above unity. Here we identify the fraction of the exchanged energy between a quantum system and a bath that necessarily causes an entropy change and derive an inequality for this change. This inequality reveals an efficiency bound for quantum engines energised by a non-thermal bath. This bound does not imply reversibility, unless the two baths are thermal. It cannot be solely deduced from the laws of thermodynamics. [ABSTRACT FROM AUTHOR]

Published

2018

50. Super-radiance reveals infinite-range dipole interactions through a nanofiber.

Author

Solano, P., Barberis-Blostein, P., Fatemi, F. K., Orozco, L. A., and Rolston, S. L.

Subjects

NANOFIBERS, DIPOLE interactions, ELECTROMAGNETIC fields, QUANTUM information theory, ATOM-atom collisions, QUANTUM optics, OPTICAL waveguides

Abstract

Atoms interact with each other through the electromagnetic field, creating collective states that can radiate faster or slower than a single atom, i.e., super- and sub-radiance. When the field is confined to one dimension it enables infinite-range atom-atom interactions. Here we present the first report of infinite-range interactions between macroscopically separated atomic dipoles mediated by an optical waveguide. We use cold 87Rb atoms in the vicinity of a single-mode optical nanofiber (ONF) that coherently exchange evanescently coupled photons through the ONF mode. In particular, we observe super-radiance of a few atoms separated by hundreds of resonant wavelengths. The same platform allows us to measure sub-radiance, a rarely observed effect, presenting a unique tool for quantum optics. This result constitutes a proof of principle for collective behavior of macroscopically delocalized atomic states, a crucial element for new proposals in quantum information and many-body physics. [ABSTRACT FROM AUTHOR]

Published

2017