Your search keyword '"Ralph, Tc"' showing total 105 results

1. Intensity noise measurements and high power quenching of an Erbium-doped fibre laser

Author

Ralph, TC, Stevenson, A, Savage, CM, and Bachor, H-A

Published

1992

2. Noiseless linear amplification and distillation of entanglement

Author

Xiang, GY, Ralph, TC, Lund, AP, Walk, N, and Pryde, Geoff J

Published

2009

3. Passive quantum error correction of linear optics networks through error averaging

Author

Marshman, RJ, Lund, AP, Rohde, PP, Ralph, TC, Marshman, RJ, Lund, AP, Rohde, PP, and Ralph, TC

Abstract

© 2018 American Physical Society. We propose and investigate a method of error detection and noise correction for bosonic linear networks using a method of unitary averaging. The proposed error averaging does not rely on ancillary photons or control and feedforward correction circuits, remaining entirely passive in its operation. We construct a general mathematical framework for this technique and then give a series of proof of principle examples including numerical analysis. Two methods for the construction of averaging are then compared to determine the most effective manner of implementation and probe the related error thresholds. Finally we discuss some of the potential uses of this scheme.

Published

2018

4. Quantum sampling problems, BosonSampling and quantum supremacy

Author

Lund, AP, Bremner, MJ, Ralph, TC, Lund, AP, Bremner, MJ, and Ralph, TC

Abstract

© 2017 by the Authors. There is a large body of evidence for the potential of greater computational power using information carriers that are quantum mechanical over those governed by the laws of classical mechanics. But the question of the exact nature of the power contributed by quantum mechanics remains only partially answered. Furthermore, there exists doubt over the practicality of achieving a large enough quantum computation that definitively demonstrates quantum supremacy. Recently the study of computational problems that produce samples from probability distributions has added to both our understanding of the power of quantum algorithms and lowered the requirements for demonstration of fast quantum algorithms. The proposed quantum sampling problems do not require a quantum computer capable of universal operations and also permit physically realistic errors in their operation. This is an encouraging step towards an experimental demonstration of quantum algorithmic supremacy. In this paper, we will review sampling problems and the arguments that have been used to deduce when sampling problems are hard for classical computers to simulate. Two classes of quantum sampling problems that demonstrate the supremacy of quantum algorithms are BosonSampling and Instantaneous Quantum Polynomial-time Sampling. We will present the details of these classes and recent experimental progress towards demonstrating quantum supremacy in BosonSampling.

Published

2017

5. Arbitrary Multi-Qubit Generation

Author

Shahandeh, F, Lund, AP, Ralph, TC, and Vanner, M

Subjects

Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

We propose and analyse a scheme for single-rail-encoded arbitrary multi-qubit quantum-state generation to provide a versatile tool for quantum optics and quantum information applications. Our scheme can be realised, for small numbers of qubits, with current technologies using single photon inputs, passive linear optics, and heralding measurements. The particular examples of two- and three-qubit cluster states are studied in detail. We show that such states can be prepared with a high probability of success. Our analysis quantifies the effects of experimentally relevant imperfections and inefficiencies. The general case of arbitrary N-qubit preparation is discussed and some interesting connections to the boson sampling problem are given.

Published

2016

6. Error tolerance of the boson-sampling model for linear optics quantum computing

Author

Rohde, PP and Ralph, TC

Subjects

General Physics

Abstract

Linear optics quantum computing is a promising approach to implementing scalable quantum computation. However, this approach has very demanding physical resource requirements. Recently, Aaronson and Arkhipov (e-print arXiv:1011.3245) showed that a simplified model, which avoids the requirement for fast feed-forward and postselection, while likely not capable of solving BQP-complete problems efficiently, can solve an interesting sampling problem believed to be classically hard. Loss and mode mismatch are the dominant sources of error in such systems. We provide evidence that even lossy systems or systems with mode mismatch are likely to be classically hard to solve. This is of practical interest to experimentalists wishing to demonstrate such systems since it suggests that, even with errors in their implementation, they are likely implementing an algorithm that is classically hard to solve. Our results also equivalently apply to the multiwalker quantum walk model. © 2012 American Physical Society.

Published

2012

7. Time-resolved detection and mode mismatch in a linear optics quantum gate

Author

Rohde, PP and Ralph, TC

Subjects

Fluids & Plasmas

Abstract

Linear optics (LO) is a promising candidate for the implementation of quantum information processing protocols. In such systems, single photons are used to represent qubits. In practice, single photons from different sources will not be perfectly temporally and frequency matched. Therefore, understanding the effects of temporal and frequency mismatch is important in characterizing the dynamics of the system. In this paper, we discuss the impact of temporal and frequency mismatch, how they differ from each other and what their effect is on a simple LO quantum gate. We show that temporal and frequency mismatch have inherently different effects on the operation of the gate. We also consider the spectral effects of the photodetectors, focusing on time-resolved detection, which we show has a strong impact on the operation of such protocols. © IOP Publishing Ltd and Deutsche Physikalische Gesellschaft.

Published

2011

8. Entanglement dynamics and quasi-periodicity in discrete quantum walks

Author

Rohde, PP, Fedrizzi, A, Ralph, TC, Rohde, PP, Fedrizzi, A, and Ralph, TC

Abstract

We study the entanglement dynamics of discrete time quantum walks acting on bounded finite sized graphs. We demonstrate that, depending on system parameters, the dynamics may be monotonic, oscillatory but highly regular, or quasi-periodic. While the dynamics of the system are not chaotic since the system comprises linear evolution, the dynamics often exhibit some features similar to chaos such as high sensitivity to the system's parameters, irregularity and infinite periodicity. Our observations are of interest for entanglement generation, which is one primary use for the quantum walk formalism. Furthermore, we show that the systems we model can easily be mapped to optical beamsplitter networks, rendering experimental observation of quasi-periodic dynamics within reach. © 2012 Copyright Taylor and Francis Group, LLC.

Published

2012

9. Practical effects in the preparation of cluster states using weak non-linearities

Author

Rohde, PP, Munro, WJ, Ralph, TC, Van Loock, P, Nemoto, K, Rohde, PP, Munro, WJ, Ralph, TC, Van Loock, P, and Nemoto, K

Abstract

We discuss experimental effects in the implementation of a recent scheme for performing bus mediated entangling operations between qubits. Here a bus mode, a strong coherent state, successively undergoes weak Kerr-type non-linear interactions with qubits. A quadrature measurement on the bus then projects the qubits into an entangled state. This approach has the benefit that entangling gates are non-destructive, may be performed non-locally, and there is no need for efficient single photon detection. In this paper we examine practical issues affecting its experimental implementation. In particular, we analyze the effects of post-selection errors, qubit loss, bus loss, mismatched coupling rates and mode-mismatch. We derive error models for these effects and relate them to realistic fault-tolerant thresholds, providing insight into realistic experimental requirements. © Rinton Press.

Published

2008

10. Error tolerance and tradeoffs in loss- and failure-tolerant quantum computing schemes

Author

Rohde, PP, Ralph, TC, Munro, WJ, Rohde, PP, Ralph, TC, and Munro, WJ

Abstract

Qubit loss and gate failure are significant problems for the development of scalable quantum computing. Recently, various schemes have been proposed for tolerating qubit loss and gate failure. These include schemes based on cluster and parity states. We show that by designing such schemes specifically to tolerate these error types we cause an exponential blowout in depolarizing noise. We discuss several examples and propose techniques for minimizing this problem. In general, this introduces a tradeoff with other undesirable effects. In some cases this is physical resource requirements, while in others it is noise rates. © 2007 The American Physical Society.

Published

2007

11. Practical limitations in optical entanglement purification

Author

Rohde, PP, Ralph, TC, Munro, WJ, Rohde, PP, Ralph, TC, and Munro, WJ

Abstract

Entanglement purification protocols play an important role in the distribution of entangled systems, which is necessary for various quantum information processing applications. We consider the effects of photodetector efficiency and bandwidth, channel loss and mode mismatch on the operation of an optical entanglement purification protocol. We derive necessary detector and mode-matching requirements to facilitate practical operation of such a scheme, without having to resort to destructive coincidence-type demonstrations. © 2006 The American Physical Society.

Published

2006

12. Modelling photo-detectors in quantum optics

Author

Rohde, PP, Ralph, TC, Rohde, PP, and Ralph, TC

Abstract

Photo-detection plays a fundamental role in experimental quantum optics and is of particular importance in the emerging field of linear optics quantum computing. Present theoretical treatment of photo-detectors is highly idealized and fails to consider many important physical effects. We present a physically motivated model for photo-detectors which accommodates for the effects of finite resolution, bandwidth and efficiency, as well as dark counts and dead-time. We apply our model to two simple well-known applications, which illustrates the significance of these characteristics.

Published

2006

13. Error models for mode mismatch in linear optics quantum computing

Author

Rohde, PP, Ralph, TC, Rohde, PP, and Ralph, TC

Abstract

One of the most significant challenges facing the development of linear optics quantum computing (LOQC) is mode mismatch, whereby photon distinguishability is introduced within circuits, undermining quantum interference effects. We examine the effects of mode mismatch on the parity (or fusion) gate, the fundamental building block in several recent LOQC schemes. We derive simple error models for the effects of mode mismatch on its operation, and relate these error models to current fault-tolerant-threshold estimates. © 2006 The American Physical Society.

Published

2006

14. Frequency and temporal effects in linear optical quantum computing

Author

Rohde, PP, Ralph, TC, Rohde, PP, and Ralph, TC

Abstract

Typically linear optical quantum computing (LOQC) models assume that all input photons are completely indistinguishable. In practice there will inevitably be nonidealities associated with the photons and the experimental setup which will introduce a degree of distinguishability between photons. We consider a nondeterministic optical controlled-NOT gate, a fundamental LOQC gate, and examine the effect of temporal and spectral distinguishability on its operation. We also consider the effect of utilizing nonideal photon counters, which have finite bandwidth and time response. ©2005 The American Physical Society.

Published

2005

15. Quantum-gate characterization in an extended Hilbert space

Author

Rohde, PP, Pryde, GJ, O'Brien, JL, Ralph, TC, Rohde, PP, Pryde, GJ, O'Brien, JL, and Ralph, TC

Abstract

We describe an approach for characterizing the process performed by a quantum gate using quantum process tomography, by first modeling the gate in an extended Hilbert space, which includes nonqubit degrees of freedom. To prevent unphysical processes from being predicted, present quantum process tomography procedures incorporate mathematical constraints, which make no assumptions as to the actual physical nature of the system being described. By contrast, the procedure presented here assumes a particular class of physical processes, and enforces physicality by fitting the data to this model. This allows quantum process tomography to be performed using a smaller experimental data set, and produces parameters with a direct physical interpretation. The approach is demonstrated by example of mode matching in an all-optical controlled-NOT gate. The techniques described are general and could be applied to other optical circuits or quantum computing architectures. © 2005 The American Physical Society.

Published

2005

16. Optimal photons for quantum-information processing

Author

Rohde, PP, Ralph, TC, Nielsen, MA, Rohde, PP, Ralph, TC, and Nielsen, MA

Abstract

Photonic quantum-information processing schemes, such as linear optics quantum computing, and other experiments relying on single-photon interference, inherently require complete photon indistinguishability to enable the desired photonic interactions to take place. Mode-mismatch is the dominant cause of photon distinguishability in optical circuits. Here we study the effects of photon wave-packet shape on tolerance against the effects of mode mismatch in linear optical circuits, and show that Gaussian distributed photons with large bandwidth are optimal. The result is general and holds for arbitrary linear optical circuits, including ones which allow for postselection and classical feed forward. Our findings indicate that some single photon sources, frequently cited for their potential application to quantum-information processing, may in fact be suboptimal for such applications. © 2005 The American Physical Society.

Published

2005

17. Comparison of architectures for approximating number-resolving photo-detection using non-number-resolving detectors

Author

Rohde, PP, Webb, JG, Huntington, EH, Ralph, TC, Rohde, PP, Webb, JG, Huntington, EH, and Ralph, TC

Abstract

Number-resolving photo-detection is necessary for many quantum optics experiments, especially in the application of entangled state preparation. Several schemes have been proposed for approximating number-resolving photo-detection using non-number-resolving detectors. Such techniques include multi-port detection and time-division multiplexing. We provide a detailed analysis and comparison of different number-resolving detection schemes, with a view to creating a useful reference for experimentalists. We show that the ideal architecture for projective measurements is a function of the detector's dark count and efficiency parameters. We also describe a process for selecting an appropriate topology given actual experimental component parameters.

18. Comparison of architectures for approximating number-resolving photo-detection using non-number-resolving detectors

Author

Rohde, PP, Webb, JG, Huntington, EH, Ralph, TC, Rohde, PP, Webb, JG, Huntington, EH, and Ralph, TC

Abstract

Number-resolving photo-detection is necessary for many quantum optics experiments, especially in the application of entangled state preparation. Several schemes have been proposed for approximating number-resolving photo-detection using non-number-resolving detectors. Such techniques include multi-port detection and time-division multiplexing. We provide a detailed analysis and comparison of different number-resolving detection schemes, with a view to creating a useful reference for experimentalists. We show that the ideal architecture for projective measurements is a function of the detector's dark count and efficiency parameters. We also describe a process for selecting an appropriate topology given actual experimental component parameters.

19. Error propagation in loss- and failure-tolerant quantum computation schemes

Author

Rohde, PP, Ralph, TC, Munro, WJ, Rohde, PP, Ralph, TC, and Munro, WJ

Abstract

Qubit loss and gate failure are significant obstacles for the implementation of scalable quantum computation. Recently there have been several proposals for overcoming these problems, including schemes based on parity and cluster states. While effective at dealing with loss and gate failure, these schemes typically lead to a blow-out in effective depolarizing noise rates. In this supplementary paper we present a detailed analysis of this problem and techniques for minimizing it.

20. Error propagation in loss- and failure-tolerant quantum computation schemes

Author

Rohde, PP, Ralph, TC, Munro, WJ, Rohde, PP, Ralph, TC, and Munro, WJ

Abstract

Qubit loss and gate failure are significant obstacles for the implementation of scalable quantum computation. Recently there have been several proposals for overcoming these problems, including schemes based on parity and cluster states. While effective at dealing with loss and gate failure, these schemes typically lead to a blow-out in effective depolarizing noise rates. In this supplementary paper we present a detailed analysis of this problem and techniques for minimizing it.

21. Simplifying quantum logic using higher-dimensional Hilbert spaces

Author

Kevin J. Resch, Jeremy L. O'Brien, Thomas Jennewein, Geoff J. Pryde, Marcelo P. Almeida, Andrew White, Alexei Gilchrist, Timothy C. Ralph, B. P. Lanyon, Marco Barbieri, Department of Physics and Centre for Quantum Computer Technology, University of Queensland [Brisbane], Laboratoire Charles Fabry de l'Institut d'Optique / Optique quantique, Laboratoire Charles Fabry de l'Institut d'Optique (LCFIO), Centre National de la Recherche Scientifique (CNRS)-Institut d'Optique Graduate School (IOGS)-Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS)-Institut d'Optique Graduate School (IOGS)-Université Paris-Sud - Paris 11 (UP11), Institute for Quantum Optics and Quantum Information, Austrian Academy of Sciences (OeAW), Institute for Quantum Computing [Waterloo] (IQC), University of Waterloo [Waterloo], Department of Physics and Astronomy [Waterloo], Centre for Quantum Dynamics, Griffith University [Brisbane], Centre for Quantum Photonics, University of Bristol [Bristol], Physics Department, Macquarie University, Lanyon, Bp, Barbieri, Marco, Almeida, Mp, Jennewein, T, Ralph, Tc, Resch, Kj, Pryde, Gj, O'Brien, Jl, Gilchrist, A, and White, Ag

Subjects

Physics, Quantum network, General Physics and Astronomy, Toffoli gate, 01 natural sciences, 010305 fluids & plasmas, Computer Science::Hardware Architecture, Open quantum system, Quantum circuit, Computer Science::Emerging Technologies, Quantum gate, [PHYS.QPHY]Physics [physics]/Quantum Physics [quant-ph], Computer engineering, Quantum error correction, 0103 physical sciences, Statistical physics, Quantum information, 010306 general physics, Quantum computer

Abstract

International audience; Quantum computation promises to solve fundamental, yet otherwise intractable, problems across a range of active fields of research. Recently, universal quantum logic-gate sets--the elemental building blocks for a quantum computer--have been demonstrated in several physical architectures. A serious obstacle to a full-scale implementation is the large number of these gates required to build even small quantum circuits. Here, we present and demonstrate a general technique that harnesses multi-level information carriers to significantly reduce this number, enabling the construction of key quantum circuits with existing technology. We present implementations of two key quantum circuits: the three-qubit Toffoli gate and the general two-qubit controlled-unitary gate. Although our experiment is carried out in a photonic architecture, the technique is independent of the particular physical encoding of quantum information, and has the potential for wider application.

Published

2008

22. Noise Transfer Approach to GKP Quantum Circuits.

Author

Ralph TC, Winnel MS, Swain SN, and Marshman RJ

Abstract

The choice between the Schrödinger and Heisenberg pictures can significantly impact the computational resources needed to solve a problem, even though they are equivalent formulations of quantum mechanics. Here, we present a method for analysing Bosonic quantum circuits based on the Heisenberg picture which allows, under certain conditions, a useful factoring of the evolution into signal and noise contributions, similar way to what can be achieved with classical communication systems. We provide examples which suggest that this approach may be particularly useful in analysing quantum computing systems based on the Gottesman-Kitaev-Preskill (GKP) qubits.

Published

2024

23. Deterministic Preparation of Optical Squeezed Cat and Gottesman-Kitaev-Preskill States.

Author

Winnel MS, Guanzon JJ, Singh D, and Ralph TC

Abstract

Large-amplitude squeezed cat states and high-quality Gottesman-Kitaev-Preskill (GKP) states are essential for effective quantum error correction, yet their optical preparation has been hindered by challenges such as low success probabilities, small amplitudes, and insufficient squeezing. Addressing these limitations, our research introduces scalable optical schemes for the deterministic preparation of large-amplitude squeezed cat states from photon-number states. Fock states have the benefit of producing consistent cat states across all measurement outcomes and intrinsically provides a degree of squeezing. Notably, these squeezed cat states facilitate the deterministic generation of high-quality approximate GKP states via "breeding," showing that GKP error correction in optics is technically feasible in near-term experiments. Our schemes allow fault-tolerant quantum computation through the use of GKP error correction.

Published

2024

24. Enhancing quantum teleportation efficacy with noiseless linear amplification.

Author

Zhao J, Jeng H, Conlon LO, Tserkis S, Shajilal B, Liu K, Ralph TC, Assad SM, and Lam PK

Abstract

Quantum teleportation constitutes a fundamental tool for various applications in quantum communication and computation. However, state-of-the-art continuous-variable quantum teleportation is restricted to moderate fidelities and short-distance configurations. This is due to unavoidable experimental imperfections resulting in thermal decoherence during the teleportation process. Here we present a heralded quantum teleporter able to overcome these limitations through noiseless linear amplification. As a result, we report a high fidelity of 92% for teleporting coherent states using a modest level of quantum entanglement. Our teleporter in principle allows nearly complete removal of loss induced onto the input states being transmitted through imperfect quantum channels. We further demonstrate the purification of a displaced thermal state, impossible via conventional deterministic amplification or teleportation approaches. The combination of high-fidelity coherent state teleportation alongside the purification of thermalized input states permits the transmission of quantum states over significantly long distances. These results are of both practical and fundamental significance; overcoming long-standing hurdles en route to highly-efficient continuous-variable quantum teleportation, while also shining new light on applying teleportation to purify quantum systems from thermal noise., (© 2023. Springer Nature Limited.)

Published

2023

25. Berry Phase from the Entanglement of Future and Past Light Cones: Detecting the Timelike Unruh Effect.

Author

Quach JQ, Ralph TC, and Munro WJ

Abstract

The Unruh effect can not only arise out of the entanglement between modes of left and right Rindler wedges, but also between modes of future and past light cones. We explore the geometric phase resulting from this timelike entanglement between the future and past, showing that it can be captured in a simple Λ system. This provides an alternative paradigm to the Unruh-deWitt detector. The Unruh effect has not been experimentally verified because the accelerations needed to excite a response from Unruh-deWitt detectors are prohibitively large. We demonstrate that a stationary but time-dependent Λ-system detects the timelike Unruh effect with current technology.

Published

2022

26. Relativistic Bohmian trajectories of photons via weak measurements.

Author

Foo J, Asmodelle E, Lund AP, and Ralph TC

Abstract

Bohmian mechanics is a nonlocal hidden-variable interpretation of quantum theory which predicts that particles follow deterministic trajectories in spacetime. Historically, the study of Bohmian trajectories has mainly been restricted to nonrelativistic regimes due to the widely held belief that the theory is incompatible with special relativity. Here, we present an approach for constructing the relativistic Bohmian-type velocity field of single particles. The advantage of our proposal is that it is operational in nature, grounded in weak measurements of the particle's momentum and energy. We apply our weak measurement formalism to obtain the relativistic spacetime trajectories of photons in a Michelson-Sagnac interferometer. The trajectories satisfy quantum-mechanical continuity and the relativistic velocity addition rule. We propose a modified Alcubierre metric which could give rise to these trajectories within the paradigm of general relativity., (© 2022. The Author(s).)

Published

2022

27. Ideal Quantum Teleamplification up to a Selected Energy Cutoff Using Linear Optics.

Author

Guanzon JJ, Winnel MS, Lund AP, and Ralph TC

Abstract

We introduce a linear optical technique that can implement ideal quantum teleamplification up to the nth Fock state, where n can be any positive integer. Here teleamplification consists of both quantum teleportation and noiseless linear amplification (NLA). This simple protocol consists of a beam splitter and an (n+1) splitter, with n ancillary photons and detection of n photons. For a given target fidelity, our technique improves success probability and physical resource costs by orders of magnitude over current alternative teleportation and NLA schemes. We show how this protocol can also be used as a loss-tolerant quantum relay for entanglement distribution and distillation.

Published

2022

28. Quantum channel correction outperforming direct transmission.

Author

Slussarenko S, Weston MM, Shalm LK, Verma VB, Nam SW, Kocsis S, Ralph TC, and Pryde GJ

Abstract

Long-distance optical quantum channels are necessarily lossy, leading to errors in transmitted quantum information, entanglement degradation and, ultimately, poor protocol performance. Quantum states carrying information in the channel can be probabilistically amplified to compensate for loss, but are destroyed when amplification fails. Quantum correction of the channel itself is therefore required, but break-even performance-where arbitrary states can be better transmitted through a corrected channel than an uncorrected one-has so far remained out of reach. Here we perform distillation by heralded amplification to improve a noisy entanglement channel. We subsequently employ entanglement swapping to demonstrate that arbitrary quantum information transmission is unconditionally improved-i.e., without relying on postselection or post-processing of data-compared to the uncorrected channel. In this way, it represents realization of a genuine quantum relay. Our channel correction for single-mode quantum states will find use in quantum repeater, communication and metrology applications., (© 2022. The Author(s).)

Published

2022

29. Satellite testing of a gravitationally induced quantum decoherence model.

Author

Xu P, Ma Y, Ren JG, Yong HL, Ralph TC, Liao SK, Yin J, Liu WY, Cai WQ, Han X, Wu HN, Wang WY, Li FZ, Yang M, Lin FL, Li L, Liu NL, Chen YA, Lu CY, Chen Y, Fan J, Peng CZ, and Pan JW

Abstract

Quantum mechanics and the general theory of relativity are two pillars of modern physics. However, a coherent unified framework of the two theories remains an open problem. Attempts to quantize general relativity have led to many rival models of quantum gravity, which, however, generally lack experimental foundations. We report a quantum optical experimental test of event formalism of quantum fields, a theory that attempts to present a coherent description of quantum fields in exotic spacetimes containing closed timelike curves and ordinary spacetime. We experimentally test a prediction of the theory with the quantum satellite Micius that a pair of time-energy-entangled particles probabilistically decorrelate passing through different regions of the gravitational potential of Earth. Our measurement results are consistent with the standard quantum theory and hence do not support the prediction of event formalism., (Copyright © 2019 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2019

30. Correlations detected in a quantum vacuum.

Author

Moskalenko AS and Ralph TC

Published

2019

31. Generation of a Cat State in an Optical Sideband.

Author

Serikawa T, Yoshikawa JI, Takeda S, Yonezawa H, Ralph TC, Huntington EH, and Furusawa A

Abstract

We propose a method to subtract a photon from a double sideband mode of continuous-wave light. The central idea is to use phase modulation as a frequency sideband beam splitter in the heralding photon subtraction scheme, where a small portion of the sideband mode is down-converted to 0 Hz to provide a trigger photon. An optical cat state is created by applying the proposed method to a squeezed state at 500 MHz sideband, which is generated by an optical parametric oscillator. The Wigner function of the cat state reconstructed from a direct homodyne measurement of the 500 MHz sideband modes shows the negativity of W(0,0)=-0.088±0.001 without any loss corrections.

Published

2018

32. Violation of Bell's Inequality Using Continuous Variable Measurements.

Author

Thearle O, Janousek J, Armstrong S, Hosseini S, Schünemann Mraz M, Assad S, Symul T, James MR, Huntington E, Ralph TC, and Lam PK

Abstract

A Bell inequality is a fundamental test to rule out local hidden variable model descriptions of correlations between two physically separated systems. There have been a number of experiments in which a Bell inequality has been violated using discrete-variable systems. We demonstrate a violation of Bell's inequality using continuous variable quadrature measurements. By creating a four-mode entangled state with homodyne detection, we recorded a clear violation with a Bell value of B=2.31±0.02. This opens new possibilities for using continuous variable states for device independent quantum protocols.

Published

2018

33. Erratum: Ultrafine Entanglement Witnessing [Phys. Rev. Lett. 118, 110502 (2017)].

Author

Shahandeh F, Ringbauer M, Loredo JC, and Ralph TC

Abstract

This corrects the article DOI: 10.1103/PhysRevLett.118.110502.

Published

2017

34. Quantum Correlations in Nonlocal Boson Sampling.

Author

Shahandeh F, Lund AP, and Ralph TC

Abstract

Determination of the quantum nature of correlations between two spatially separated systems plays a crucial role in quantum information science. Of particular interest is the questions of if and how these correlations enable quantum information protocols to be more powerful. Here, we report on a distributed quantum computation protocol in which the input and output quantum states are considered to be classically correlated in quantum informatics. Nevertheless, we show that the correlations between the outcomes of the measurements on the output state cannot be efficiently simulated using classical algorithms. Crucially, at the same time, local measurement outcomes can be efficiently simulated on classical computers. We show that the only known classicality criterion violated by the input and output states in our protocol is the one used in quantum optics, namely, phase-space nonclassicality. As a result, we argue that the global phase-space nonclassicality inherent within the output state of our protocol represents true quantum correlations.

Published

2017

35. Experimental test of photonic entanglement in accelerated reference frames.

Author

Fink M, Rodriguez-Aramendia A, Handsteiner J, Ziarkash A, Steinlechner F, Scheidl T, Fuentes I, Pienaar J, Ralph TC, and Ursin R

Abstract

The unification of the theory of relativity and quantum mechanics is a long-standing challenge in contemporary physics. Experimental techniques in quantum optics have only recently reached the maturity required for the investigation of quantum systems under the influence of non-inertial motion, such as being held at rest in gravitational fields, or subjected to uniform accelerations. Here, we report on experiments in which a genuine quantum state of an entangled photon pair is exposed to a series of different accelerations. We measure an entanglement witness for g-values ranging from 30 mg to up to 30 g-under free-fall as well on a spinning centrifuge-and have thus derived an upper bound on the effects of uniform acceleration on photonic entanglement.

Published

2017

36. Measurement-Device-Independent Approach to Entanglement Measures.

Author

Shahandeh F, Hall MJW, and Ralph TC

Abstract

Within the context of semiquantum nonlocal games, the trust can be removed from the measurement devices in an entanglement-detection procedure. Here, we show that a similar approach can be taken to quantify the amount of entanglement. To be specific, first, we show that in this context, a small subset of semiquantum nonlocal games is necessary and sufficient for entanglement detection in the local operations and classical communication paradigm. Second, we prove that the maximum payoff for these games is a universal measure of entanglement which is convex and continuous. Third, we show that for the quantification of negative-partial-transpose entanglement, this subset can be further reduced down to a single arbitrary element. Importantly, our measure is measurement device independent by construction and operationally accessible. Finally, our approach straightforwardly extends to quantify the entanglement within any partitioning of multipartite quantum states.

Published

2017

37. Ultrafine Entanglement Witnessing.

Author

Shahandeh F, Ringbauer M, Loredo JC, and Ralph TC

Abstract

Entanglement witnesses are invaluable for efficient quantum entanglement certification without the need for expensive quantum state tomography. Yet, standard entanglement witnessing requires multiple measurements and its bounds can be elusive as a result of experimental imperfections. Here, we introduce and demonstrate a novel procedure for entanglement detection which simply and seamlessly improves any standard witnessing procedure by using additional available information to tighten the witnessing bounds. Moreover, by relaxing the requirements on the witness operators, our method removes the general need for the difficult task of witness decomposition into local observables. We experimentally demonstrate entanglement detection with our approach using a separable test operator and a simple fixed measurement device for each agent. Finally, we show that the method can be generalized to higher-dimensional and multipartite cases with a complexity that scales linearly with the number of parties.

Published

2017

38. Surpassing the no-cloning limit with a heralded hybrid linear amplifier for coherent states.

Author

Haw JY, Zhao J, Dias J, Assad SM, Bradshaw M, Blandino R, Symul T, Ralph TC, and Lam PK

Abstract

The no-cloning theorem states that an unknown quantum state cannot be cloned exactly and deterministically due to the linearity of quantum mechanics. Associated with this theorem is the quantitative no-cloning limit that sets an upper bound to the quality of the generated clones. However, this limit can be circumvented by abandoning determinism and using probabilistic methods. Here, we report an experimental demonstration of probabilistic cloning of arbitrary coherent states that clearly surpasses the no-cloning limit. Our scheme is based on a hybrid linear amplifier that combines an ideal deterministic linear amplifier with a heralded measurement-based noiseless amplifier. We demonstrate the production of up to five clones with the fidelity of each clone clearly exceeding the corresponding no-cloning limit. Moreover, since successful cloning events are heralded, our scheme has the potential to be adopted in quantum repeater, teleportation and computing applications.

Published

2016

39. A quantum Fredkin gate.

Author

Patel RB, Ho J, Ferreyrol F, Ralph TC, and Pryde GJ

Subjects

Algorithms, Models, Theoretical, Quantum Theory

Abstract

Minimizing the resources required to build logic gates into useful processing circuits is key to realizing quantum computers. Although the salient features of a quantum computer have been shown in proof-of-principle experiments, difficulties in scaling quantum systems have made more complex operations intractable. This is exemplified in the classical Fredkin (controlled-SWAP) gate for which, despite theoretical proposals, no quantum analog has been realized. By adding control to the SWAP unitary, we use photonic qubit logic to demonstrate the first quantum Fredkin gate, which promises many applications in quantum information and measurement. We implement example algorithms and generate the highest-fidelity three-photon Greenberger-Horne-Zeilinger states to date. The technique we use allows one to add a control operation to a black-box unitary, something that is impossible in the standard circuit model. Our experiment represents the first use of this technique to control a two-qubit operation and paves the way for larger controlled circuits to be realized efficiently.

Published

2016

40. Photon sorting, efficient bell measurements, and a deterministic controlled-Z gate using a passive two-level nonlinearity.

Author

Ralph TC, Söllner I, Mahmoodian S, White AG, and Lodahl P

Abstract

Although the strengths of optical nonlinearities available experimentally have been rapidly increasing in recent years, significant challenges remain to using such nonlinearities to produce useful quantum devices such as efficient optical Bell state analyzers or universal quantum optical gates. Here we describe a new approach that avoids the current limitations by combining strong nonlinearities with active Gaussian operations in efficient protocols for Bell state analyzers and controlled-sign gates.

Published

2015

41. Nearly deterministic bell measurement for multiphoton qubits and its application to quantum information processing.

Author

Lee SW, Park K, Ralph TC, and Jeong H

Abstract

We propose a Bell-measurement scheme by employing a logical qubit in Greenberger-Horne-Zeilinger entanglement with an arbitrary number of photons. Remarkably, the success probability of the Bell measurement as well as teleportation of the Greenberger-Horne-Zeilinger entanglement can be made arbitrarily high using only linear optics elements and photon on-off measurements as the number of photons increases. Our scheme outperforms previous proposals using single-photon qubits when comparing the success probabilities in terms of the average photon usages. It has another important advantage for experimental feasibility in that it does not require photon-number-resolving measurements. Our proposal provides an alternative candidate for all-optical quantum information processing.

Published

2015

42. What can quantum optics say about computational complexity theory?

Author

Rahimi-Keshari S, Lund AP, and Ralph TC

Abstract

Considering the problem of sampling from the output photon-counting probability distribution of a linear-optical network for input Gaussian states, we obtain results that are of interest from both quantum theory and the computational complexity theory point of view. We derive a general formula for calculating the output probabilities, and by considering input thermal states, we show that the output probabilities are proportional to permanents of positive-semidefinite Hermitian matrices. It is believed that approximating permanents of complex matrices in general is a #P-hard problem. However, we show that these permanents can be approximated with an algorithm in the BPP^{NP} complexity class, as there exists an efficient classical algorithm for sampling from the output probability distribution. We further consider input squeezed-vacuum states and discuss the complexity of sampling from the probability distribution at the output.

Published

2015

43. Boson sampling from a Gaussian state.

Author

Lund AP, Laing A, Rahimi-Keshari S, Rudolph T, O'Brien JL, and Ralph TC

Abstract

We pose a randomized boson-sampling problem. Strong evidence exists that such a problem becomes intractable on a classical computer as a function of the number of bosons. We describe a quantum optical processor that can solve this problem efficiently based on a Gaussian input state, a linear optical network, and nonadaptive photon counting measurements. All the elements required to build such a processor currently exist. The demonstration of such a device would provide empirical evidence that quantum computers can, indeed, outperform classical computers and could lead to applications.

Published

2014

44. Configurable unitary transformations and linear logic gates using quantum memories.

Author

Campbell GT, Pinel O, Hosseini M, Ralph TC, Buchler BC, and Lam PK

Abstract

We show that a set of optical memories can act as a configurable linear optical network operating on frequency-multiplexed optical states. Our protocol is applicable to any quantum memories that employ off-resonant Raman transitions to store optical information in atomic spins. In addition to the configurability, the protocol also offers favorable scaling with an increasing number of modes where N memories can be configured to implement arbitrary N-mode unitary operations during storage and readout. We demonstrate the versatility of this protocol by showing an example where cascaded memories are used to implement a conditional cz gate.

Published

2014

45. Experimental simulation of closed timelike curves.

Author

Ringbauer M, Broome MA, Myers CR, White AG, and Ralph TC

Abstract

Closed timelike curves are among the most controversial features of modern physics. As legitimate solutions to Einstein's field equations, they allow for time travel, which instinctively seems paradoxical. However, in the quantum regime these paradoxes can be resolved, leaving closed timelike curves consistent with relativity. The study of these systems therefore provides valuable insight into nonlinearities and the emergence of causal structures in quantum mechanics--essential for any formulation of a quantum theory of gravity. Here we experimentally simulate the nonlinear behaviour of a qubit interacting unitarily with an older version of itself, addressing some of the fascinating effects that arise in systems traversing a closed timelike curve. These include perfect discrimination of non-orthogonal states and, most intriguingly, the ability to distinguish nominally equivalent ways of preparing pure quantum states. Finally, we examine the dependence of these effects on the initial qubit state, the form of the unitary interaction and the influence of decoherence.

Published

2014

46. Quantum communication: reliable teleportation.

Author

Ralph TC

Published

2013

47. High-fidelity teleportation of continuous-variable quantum states using delocalized single photons.

Author

Andersen UL and Ralph TC

Abstract

Traditional continuous-variable teleportation can only approach unit fidelity in the limit of an infinite (and unphysical) amount of squeezing. We describe a new method for continuous-variable teleportation that approaches unit fidelity with finite resources. The protocol is not based on squeezed states as in traditional teleportation but on an ensemble of single photon entangled states. We characterize the teleportation scheme with coherent states, mesoscopic superposition states, and two-mode squeezed states and we find several situations in which near-unity teleportation fidelity can be obtained with modest resources.

Published

2013

48. Direct characterization of linear-optical networks.

Author

Rahimi-Keshari S, Broome MA, Fickler R, Fedrizzi A, Ralph TC, and White AG

Abstract

We introduce an efficient method for fully characterizing multimode linear-optical networks. Our approach requires only a standard laser source and intensity measurements to directly and uniquely determine all moduli and non-trivial phases of the matrix describing a network. We experimentally demonstrate the characterization of a 6×6 fiber-optic network and independently verify the results via nonclassical two-photon interference.

Published

2013

49. Photonic boson sampling in a tunable circuit.

Author

Broome MA, Fedrizzi A, Rahimi-Keshari S, Dove J, Aaronson S, Ralph TC, and White AG

Abstract

Quantum computers are unnecessary for exponentially efficient computation or simulation if the Extended Church-Turing thesis is correct. The thesis would be strongly contradicted by physical devices that efficiently perform tasks believed to be intractable for classical computers. Such a task is boson sampling: sampling the output distributions of n bosons scattered by some passive, linear unitary process. We tested the central premise of boson sampling, experimentally verifying that three-photon scattering amplitudes are given by the permanents of submatrices generated from a unitary describing a six-mode integrated optical circuit. We find the protocol to be robust, working even with the unavoidable effects of photon loss, non-ideal sources, and imperfect detection. Scaling this to large numbers of photons should be a much simpler task than building a universal quantum computer.

Published

2013

50. Open timelike curves violate Heisenberg's uncertainty principle.

Author

Pienaar JL, Ralph TC, and Myers CR

Abstract

Toy models for quantum evolution in the presence of closed timelike curves have gained attention in the recent literature due to the strange effects they predict. The circuits that give rise to these effects appear quite abstract and contrived, as they require nontrivial interactions between the future and past that lead to infinitely recursive equations. We consider the special case in which there is no interaction inside the closed timelike curve, referred to as an open timelike curve (OTC), for which the only local effect is to increase the time elapsed by a clock carried by the system. Remarkably, circuits with access to OTCs are shown to violate Heisenberg's uncertainty principle, allowing perfect state discrimination and perfect cloning of coherent states. The model is extended to wave packets and smoothly recovers standard quantum mechanics in an appropriate physical limit. The analogy with general relativistic time dilation suggests that OTCs provide a novel alternative to existing proposals for the behavior of quantum systems under gravity.

Published

2013