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1. Efficient and Device-Independent Active Quantum State Certification

Author

Antesberger, Michael, Schmid, Mariana M. E., Cao, Huan, Dakić, Borivoje, Rozema, Lee A., and Walther, Philip

Subjects
Quantum Physics
Abstract

Entangled quantum states are essential ingredients for many quantum technologies, but they must be validated before they are used. As a full characterization is prohibitively resource-intensive, recent work has focused on developing methods to efficiently extract a few parameters of interest, in a so-called verification framework. Most existing approaches are based on preparing an ensemble of nominally identical and independent (IID) quantum states, and then measuring each copy of the ensemble. However, this leaves no states left for the intended quantum tasks and the IID assumptions do not always hold experimentally. To overcome these challenges, we experimentally implement quantum state certification (QSC), which measures only a subset of the ensemble, certifying the fidelity of the remaining states. We use active optical switches to randomly sample from sources of two-photon Bell states and three-photon GHZ states, reporting statistically-sound fidelities in real time without destroying the entire ensemble. Additionally, our QSC protocol removes the assumption that the states are identical, is device-independent, and can achieve close $N^{-1}$ scaling, in the number of states measured $N$. Altogether, these benefits make our QSC protocol suitable for benchmarking large-scale quantum computing devices and deployed quantum communication setups relying on entanglement in both standard and adversarial situations., Comment: 8 pages, 4 figures

Published
2024

2. Direct and Efficient Detection of Quantum Superposition

Author

Kun, Daniel, Strömberg, Teodor, Spagnolo, Michele, Dakić, Borivoje, Rozema, Lee A., and Walther, Philip

Subjects
Quantum Physics
Abstract

One of the most striking quantum phenomena is superposition, where one particle simultaneously inhabits different states. Most methods to verify coherent superposition are indirect, in that they require the distinct states to be recombined. Here, we adapt an XOR game, in which separated parties measure different parts of a superposed particle, and use it to verify superpositions with \textit{local measurements} and a second independent particle. We then turn this game into a resource-efficient verification scheme, obtaining a confidence that the particle is superposed which approaches unity exponentially fast. We demonstrate our scheme using a single photon, obtaining a 99\% confidence that the particle is superposed with only 37 copies. Our work shows the utility of XOR games to verify quantum resources, allowing us to efficiently detect quantum superposition without reinterfering the superposed states., Comment: 13 pages (incl. 8 pages appendix) , 7 figures

Published
2024

3. Experimental Aspects of Indefinite Causal Order in Quantum Mechanics

Author

Rozema, Lee A., Strömberg, Teodor, Cao, Huan, Guo, Yu, Liu, Bi-Heng, and Walther, Philip

Subjects
Quantum Physics
Abstract

In the past decade, the toolkit of quantum information has been expanded to include processes in which the basic operations do not have definite causal relations. Originally considered in the context of the unification of quantum mechanics and general relativity, these causally indefinite processes have been shown to offer advantages in a wide variety of quantum information processing tasks, ranging from quantum computation to quantum metrology. Here we overview these advantages and the experimental efforts to realise them. We survey both the different experimental techniques employed, as well as theoretical methods developed in support of the experiments, before discussing the interpretations of current experimental results and giving an outlook on the future of the field., Comment: 22 page review article. Comments welcome!

Published
2024
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4. Quasi-phase-matched up- and down-conversion in periodically poled layered semiconductors

Author

Trovatello, Chiara, Ferrante, Carino, Yang, Birui, Bajo, Josip, Braun, Benjamin, Xu, Xinyi, Peng, Zhi Hao, Jenke, Philipp K., Ye, Andrew, Delor, Milan, Basov, D. N., Park, Jiwoong, Walther, Philip, Rozema, Lee A., Dean, Cory, Marini, Andrea, Cerullo, Giulio, and Schuck, P. James

Subjects
Physics - Optics, Condensed Matter - Materials Science
Abstract

Nonlinear optics lies at the heart of classical and quantum light generation. The invention of periodic poling revolutionized nonlinear optics and its commercial applications by enabling robust quasi-phase-matching in crystals such as lithium niobate. However, reaching useful frequency conversion efficiencies requires macroscopic dimensions, limiting further technology development and integration. Here we realize a periodically poled van der Waals semiconductor (3R-MoS$_2$). Due to its exceptional nonlinearity, we achieve macroscopic frequency conversion efficiency over a microscopic thickness of only 1.2${\mu}$m, $10-100\times$ thinner than current systems with similar performances. Due to unique intrinsic cavity effects, the thickness-dependent quasi-phase-matched second harmonic signal surpasses the usual quadratic enhancement by $50\%$. Further, we report the broadband generation of photon pairs at telecom wavelengths via quasi-phase-matched spontaneous parametric down-conversion. This work opens the new and unexplored field of phase-matched nonlinear optics with microscopic van der Waals crystals, unlocking applications that require simple, ultra-compact technologies such as on-chip entangled photon-pair sources for integrated quantum circuitry and sensing.

Published
2023

5. Generating a 4-photon Tetrahedron State: Towards Simultaneous Super-sensitivity to Non-commuting Rotations

Author

Ferretti, Hugo, Yilmaz, Y. Batuhan, Bonsma-Fisher, Kent, Goldberg, Aaron Z., Lupu-Gladstein, Noah, Pang, Arthur O. T., Rozema, Lee A., and Steinberg, Aephraim M.

Subjects
Quantum Physics
Abstract

It is often thought that the super-sensitivity of a quantum state to an observable comes at the cost of a decreased sensitivity to other non-commuting observables. For example, a squeezed state squeezed in position quadrature is super-sensitive to position displacements, but very insensitive to momentum displacements. This misconception was cleared with the introduction of the compass state, a quantum state equally super-sensitive to displacements in position and momentum. When looking at quantum states used to measure spin rotations, N00N states are known to be more advantageous than classical methods as long as they are aligned to the rotation axis. When considering the estimation of a rotation with unknown direction and amplitude, a certain class of states stands out with interesting properties. These states are equally sensitive to rotations around any axis, are second-order unpolarized, and can possess the rotational properties of platonic solids in particular dimensions. Importantly, these states are optimal for simultaneously estimating the three parameters describing a rotation. In the asymptotic limit, estimating all d parameters describing a transformation simultaneously rather than sequentially can lead to a reduction of the appropriately-weighted sum of the measured parameters' variances by a factor of d. We report the experimental creation and characterization of the lowest-dimensional such state, which we call the "tetrahedron state" due to its tetrahedral symmetry. This tetrahedron state is created in the symmetric subspace of four optical photons' polarization in a single spatial and temporal mode, which behaves as a spin-2 particle. While imperfections due to the hardware limit the performance of our method, we argue that better technology can improve our method to the point of outperforming any other existing strategy in per-photon comparisons., Comment: 13 pages, 6 figures

Published
2023

6. Genuine multipartite entanglement detection with imperfect measurements: concept and experiment

Author

Cao, Huan, Morelli, Simon, Rozema, Lee A., Zhang, Chao, Tavakoli, Armin, and Walther, Philip

Subjects
Quantum Physics
Abstract

Standard procedures for entanglement detection assume that experimenters can exactly implement specific quantum measurements. Here, we depart from such idealizations and investigate, in both theory and experiment, the detection of genuine multipartite entanglement when measurements are subject to small imperfections. For arbitrary qubits number $n$, we construct multipartite entanglement witnesses where the detrimental influence of the imperfection is independent of $n$. In a tabletop four-partite photonic experiment we demonstrate first how a small amount of alignment error can undermine the conclusions drawn from standard entanglement witnesses, and then perform the correction analysis. Furthermore, since we consider quantum devices that are trusted but not perfectly controlled, we showcase advantages in terms of noise resilience as compared to device-independent models., Comment: 6+9 pages, 3+7 figures

Published
2023
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7. Distribution of Telecom Entangled Photons through a 7.7 km Antiresonant Hollow-Core Fiber

Author

Antesberger, Michael, Richter, Carla M. D., Poletti, Francesco, Slavík, Radan, Petropoulos, Periklis, Hübel, Hannes, Trenti, Alessandro, Walther, Philip, and Rozema, Lee A.

Subjects
Quantum Physics
Abstract

State of the art classical and quantum communication rely on standard optical fibers with solid cores to transmit light over long distances. However, recent advances have led to the emergence of antiresonant hollow-core optical fibers (AR-HCFs), which due to the novel fiber geometry, show remarkable optical guiding properties, which are not as limited by the material properties as solid-core fibers. In this paper, we explore the transmission of entangled photons through a novel 7.7 km AR-HCF in a laboratory environment at 1550 nm, presenting the first successful demonstration of entanglement distribution via a long AR-HCF. In addition to showing these novel fibers are compatible with long distance quantum communication, we highlight the low latency and low chromatic dispersion intrinsic to AR-HCF, which can increase the secure key rate in time-bin based quantum key distribution protocols., Comment: 11 pages (incl. 2 pages appendix), 5 figures

Published
2023
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8. Higher-order Process Matrix Tomography of a passively-stable Quantum SWITCH

Author

Antesberger, Michael, Quintino, Marco Túlio, Walther, Philip, and Rozema, Lee A.

Subjects
Quantum Physics
Abstract

The field of indefinite causal order (ICO) has seen a recent surge in interest. Much of this research has focused on the quantum SWITCH, wherein multiple parties act in a superposition of different orders in a manner transcending the quantum circuit model. This results in a new resource for quantum protocols, and is exciting for its relation to issues in foundational physics. The quantum SWITCH is also an example of a higher-order quantum operation, in that it not only transforms quantum states, but also other quantum operations. To date, no higher-order quantum operation has been completely experimentally characterized. Indeed, past work on the quantum SWITCH has confirmed its ICO by measuring causal witnesses or demonstrating resource advantages, but the complete process matrix has only been described theoretically. Here, we perform higher-order quantum process tomography. However, doing so requires exponentially many measurements with a scaling worse than standard process tomography. We overcome this challenge by creating a new passively-stable fiber-based quantum SWITCH using active optical elements to deterministically generate and manipulate time-bin encoded qubits. Moreover, our new architecture for the quantum SWITCH can be readily scaled to multiple parties. By reconstructing the process matrix, we estimate its fidelity and tailor different causal witnesses directly for our experiment. To achieve this, we measure a set of tomographically complete settings, that also spans the input operation space. Our tomography protocol allows for the characterization and debugging of higher-order quantum operations with and without an ICO, while our experimental time-bin techniques could enable the creation of a new realm of higher-order quantum operations with an ICO., Comment: 20 pages (12 pages, 4 pages appendix + reference list and introduction), 8 figures; v2 with updated funding information

Published
2023
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9. Experimental superposition of time directions

Author

Strömberg, Teodor, Schiansky, Peter, Quintino, Marco Túlio, Antesberger, Michael, Rozema, Lee, Agresti, Iris, Brukner, Časlav, and Walther, Philip

Subjects
Quantum Physics
Abstract

In the macroscopic world, time is intrinsically asymmetric, flowing in a specific direction, from past to future. However, the same is not necessarily true for quantum systems, as some quantum processes produce valid quantum evolutions under time reversal. Supposing that such processes can be probed in both time directions, we can also consider quantum processes probed in a coherent superposition of forwards and backwards time directions. This yields a broader class of quantum processes than the ones considered so far in the literature, including those with indefinite causal order. In this work, we demonstrate for the first time an operation belonging to this new class: the quantum time flip. Using a photonic realisation of this operation, we apply it to a game formulated as a discrimination task between two sets of operators. This game not only serves as a witness of an indefinite time direction, but also allows for a computational advantage over strategies using a fixed time direction, and even those with an indefinite causal order., Comment: Improved manuscript, closer to published version. 15 pages, 5 figures

Published
2022
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10. Nonlinear quantum logic with colliding graphene plasmons

Author

Calajò, Giuseppe, Jenke, Philipp K., Rozema, Lee A., Walther, Philip, Chang, Darrick E., and Cox, Joel D.

Subjects
Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics
Abstract

Graphene has emerged as a promising platform to bring nonlinear quantum optics to the nanoscale, where a large intrinsic optical nonlinearity enables long-lived and actively tunable plasmon polaritons to strongly interact. Here we theoretically study the collision between two counter-propagating plasmons in a graphene nanoribbon, where transversal subwavelength confinement endows propagating plasmons with %large effective masses a flat band dispersion that enhances their interaction. This scenario presents interesting possibilities towards the implementation of multi-mode polaritonic gates that circumvent limitations imposed by the Shapiro no-go theorem for photonic gates in nonlinear optical fibers. As a paradigmatic example we demonstrate the feasibility of a high fidelity conditional Pi phase shift (CZ), where the gate performance is fundamentally limited only by the single-plasmon lifetime. These results open new exciting avenues towards quantum information and many-body applications with strongly-interacting polaritons., Comment: 13 pages, 5 figures

Published
2022
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11. Giant enhancement of third-harmonic generation in graphene-metal heterostructures

Author

Calafell, Irati Alonso, Rozema, Lee A., Iranzo, David Alcaraz, Trenti, Alessandro, Cox, Joel D., Kumar, Avinash, Bieliaiev, Hlib, Nanot, Sebastian, Peng, Cheng, Efetov, Dmitri K., Hong, Jin Yong, Kong, Jing, Englund, Dirk R., de Abajo, F. Javier García, Koppens, Frank H. L., and Walther, Philp

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics
Abstract

Nonlinear nanophotonics leverages engineered nanostructures to funnel light into small volumes and intensify nonlinear optical processes with spectral and spatial control. Due to its intrinsically large and electrically tunable nonlinear optical response, graphene is an especially promising nanomaterial for nonlinear optoelectronic applications. Here we report on exceptionally strong optical nonlinearities in graphene-insulator-metal heterostructures, demonstrating an enhancement by three orders of magnitude in the third-harmonic signal compared to bare graphene. Furthermore, by increasing the graphene Fermi energy through an external gate voltage, we find that graphene plasmons mediate the optical nonlinearity and modify the third-harmonic signal. Our findings show that graphene-insulator-metal is a promising heterostructure for optically-controlled and electrically-tunable nano-optoelectronic components.

Published
2022
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12. High-harmonic generation enhancement with graphene heterostructures

Author

Calafell, Irati Alonso, Rozema, Lee A., Trenti, Alessandro, Bohn, Justus, Dias, Eduardo J. C., Jenke, Philipp K., Menghrajani, Kishan S., Iranzo, David Alcaraz, de Abajo, F. Javier Garcia, Koppens, Frank H. L., Hendry, Euan, and Walther, Philip

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics
Abstract

We investigate high-harmonic generation in graphene heterostructures consisting of metallic nanoribbons separated from a graphene sheet by either a few-nanometer layer of aluminum oxide or an atomic monolayer of hexagonal boron nitride. The nanoribbons amplify the near-field at the graphene layer relative to the externally applied pumping, thus allowing us to observe third- and fifth-harmonic generation in the carbon monolayer at modest pump powers in the mid-infrared. We study the dependence of the nonlinear signals on the ribbon width and spacer thickness, as well as pump power and polarization, and demonstrate enhancement factors relative to bare graphene reaching 1600 and 4100 for third- and fifth-harmonic generation, respectively. Our work supports the use of graphene heterostructures to selectively enhance specific nonlinear processes of interest, an essential capability for the design of nanoscale nonlinear devices.

Published
2022
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13. Semi-device-independent certification of indefinite causal order in a photonic quantum switch

Author

Cao, Huan, Bavaresco, Jessica, Wang, Ning-Ning, Rozema, Lee A., Zhang, Chao, Huang, Yun-Feng, Liu, Bi-Heng, Li, Chuan-Feng, Guo, Guang-Can, and Walther, Philip

Subjects
Quantum Physics
Abstract

We report an experimental certification of indefinite causal order that relies only on the characterization of the operations of a single party. We do so in the semi-device-independent scenario with the fewest possible assumptions of characterization of the parties' local operations in which indefinite causal order can be demonstrated with the quantum switch. To achieve this result, we introduce the concept of semi-device-independent causal inequalities and show that the correlations generated in a photonic quantum switch, in which all parties are able to collect local outcome statistics, achieve a violation of this inequality of 224 standard deviations. This result consists of the experimental demonstration of indefinite causal order with the fewest device-characterization assumptions to date., Comment: 9 + 4 pages, 5 + 1 figures. Close to the published version

Published
2022
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14. Experimental Higher-Order Interference in a Nonlinear Triple Slit

Author

Namdar, Peter, Jenke, Philipp K., Calafell, Irati Alonso, Trenti, Alessandro, Radonjić, Milan, Dakić, Borivoje, Walther, Philip, and Rozema, Lee A.

Subjects
Quantum Physics
Abstract

Interference between two waves is a well-known concept in physics, and its generalization to more than two waves is straight-forward. The order of interference is defined as the number of paths that interfere in a manner that cannot be reduced to patterns of a lower order. In practice, second-order interference means that in, say, a triple-slit experiment, the interference pattern when all three slits are open can be predicted from the interference patterns between all possible pairs of slits. Quantum mechanics is often said to only exhibit second-order interference. However, this is only true under specific assumptions, typically single-particles undergoing linear evolution. Here we experimentally show that nonlinear evolution can in fact lead to higher-order interference. The higher-order interference in our experiment has a simple quantum mechanical description; namely, optical coherent states interacting in a nonlinear medium. Our work shows that nonlinear evolution could open a loophole for experiments attempting to verify Born's rule by ruling out higher-order interference., Comment: 5 pages, 3 figures, plus an appendix

Published
2021

15. Enhanced Photonic Maxwell's Demon with Correlated Baths

Author

Zanin, Guilherme L., Antesberger, Michael, Jacquet, Maxime J., Ribeiro, Paulo H. Souto, Rozema, Lee A., and Walther, Philip

Subjects
Quantum Physics
Abstract

Maxwell's Demon is at the heart of the interrelation between quantum information processing and thermodynamics. In this thought experiment, a demon generates a temperature gradient between two thermal baths initially at equilibrium by gaining information at the single-particle level and applying classical feed-forward operations, allowing for the extraction of work. Here we implement a photonic version of Maxwell's Demon with active feed-forward in a fibre-based system using ultrafast optical switches. We experimentally show that, if correlations exist between the two thermal baths, the Demon can generate a temperature difference over an order of magnitude larger than without correlations, and so extract more work. Our work demonstrates the great potential of photonic experiments -- which provide a unique degree of control on the system -- to access new regimes in quantum thermodynamics., Comment: 25 pages with appendix, 6 figures. Final version published on Quantum

Published
2021
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16. Inferring work by quantum superposing forward and time-reversal evolutions

Author

Rubino, Giulia, Manzano, Gonzalo, Rozema, Lee A., Walther, Philip, Parrondo, Juan M. R., and Brukner, Časlav

Subjects
Quantum Physics
Abstract

The study of thermodynamic fluctuations allows one to relate the free energy difference between two equilibrium states with the work done on a system through processes far from equilibrium. This finding plays a crucial role in the quantum regime, where the definition of work becomes non-trivial. Based on these relations, here we develop a simple interferometric method allowing a direct estimation of the work distribution and the average dissipative work during a driven thermodynamic process by superposing the forward and time-reversal evolutions of the process. We show that our scheme provides useful upper bounds on the average dissipative work even without full control over the thermodynamic process, and we propose methodological variations depending on the possible experimental limitations encountered. Finally, we exemplify its applicability by an experimental proposal for implementing our method on a quantum photonics system, on which the thermodynamic process is performed through polarization rotations induced by liquid crystals acting in a discrete temporal regime., Comment: 13 pages, 4 figures. Accepted version

Published
2021
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17. Experimental Quantum Communication Enhancement by Superposing Trajectories

Author

Rubino, Giulia, Rozema, Lee A., Ebler, Daniel, Kristjánsson, Hlér, Salek, Sina, Guérin, Philippe Allard, Abbott, Alastair A., Branciard, Cyril, Brukner, Časlav, Chiribella, Giulio, and Walther, Philip

Subjects
Quantum Physics
Abstract

In quantum communication networks, wires represent well-defined trajectories along which quantum systems are transmitted. In spite of this, trajectories can be used as a quantum control to govern the order of different noisy communication channels, and such a control has been shown to enable the transmission of information even when quantum communication protocols through well-defined trajectories fail. This result has motivated further investigations on the role of the superposition of trajectories in enhancing communication, which revealed that the use of quantum control of parallel communication channels, or of channels in series with quantum-controlled operations, can also lead to communication advantages. Building upon these findings, here we experimentally and numerically compare different ways in which two trajectories through a pair of noisy channels can be superposed. We observe that, within the framework of quantum interferometry, the use of channels in series with quantum-controlled operations generally yields the largest advantages. Our results contribute to clarify the nature of these advantages in experimental quantum-optical scenarios, and showcase the benefit of an extension of the quantum communication paradigm in which both the information exchanged and the trajectory of the information carriers are quantum., Comment: 20 pages, 11 figures. Accepted version

Published
2020
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18. Higher-order interference between multiple quantum particles interacting nonlinearly

Author

Rozema, Lee A., Zhuo, Zhao, Paterek, Tomasz, and Dakić, Borivoje

Subjects
Quantum Physics
Abstract

The double-slit experiment is the most direct demonstration of interference between individual quantum objects. Since similar experiments with single particles and more slits produce interference fringes reducible to a combination of double-slit patterns it is usually argued that quantum interference occurs between pairs of trajectories, compactly denoted as second-order interference. Here we show that quantum mechanics in fact allows for interference of arbitrarily high order. This occurs naturally when one considers multiple quantum objects interacting in the presence of a nonlinearity, both of which are required to observe higher-order interference. We make this clear by treating a generalised multi-slit interferometer using second-quantisation. We then present explicit experimentally-relevant examples both with photons interacting in nonlinear media and an interfering Bose-Einstein condensate with particle-particle interactions. These examples are all perfectly described by quantum theory, and yet exhibit higher-order interference based on multiple particles interacting nonlinearly., Comment: 7 pages, 3 figures

Published
2020
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19. Experimental few-copy multi-particle entanglement detection

Author

Saggio, Valeria, Dimić, Aleksandra, Greganti, Chiara, Rozema, Lee A., Walther, Philip, and Dakić, Borivoje

Subjects
Quantum Physics
Abstract

Quantum technologies lead to a variety of applications that outperform their classical counterparts. In order to build a quantum device it must be verified that it operates below some error threshold. Recently, because of technological developments which allow for the experimental realization of quantum states with increasing complexity, these tasks must be applied to large multi-qubit states. However, due to the exponentially-increasing system size, tasks like quantum entanglement verification become hard to carry out in such cases. Here we develop a generic framework to translate any entanglement witness into a resource-efficient probabilistic scheme. We show that the confidence to detect entanglement grows exponentially with the number of individual detection events. To benchmark our findings, we experimentally verify the presence of entanglement in a photonic six-qubit cluster state generated using three single-photon sources operating at telecommunication wavelengths. We find that its presence can be certified with at least 99.74% confidence by detecting 20 copies of the quantum state. Additionally, we show that genuine six-qubit entanglement is verified with at least 99% confidence by using 112 copies of the state. Our protocol can be carried out with a remarkably low number of copies, making it a practical and applicable method to verify large-scale quantum devices., Comment: 9 pages, 4 figures

Published
2018
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20. Experimental entanglement of temporal order

Author

Rubino, Giulia, Rozema, Lee A., Massa, Francesco, Araújo, Mateus, Zych, Magdalena, Brukner, Časlav, and Walther, Philip

Subjects
Quantum Physics
Abstract

The study of causal relations has recently been applied to the quantum realm, leading to the discovery that not all physical processes have a definite causal structure. While indefinite causal processes have previously been experimentally shown, these proofs relied on the quantum description of the experiments. Yet, the same experimental data could also be compatible with definite causal structures within different descriptions. Here, we present the first demonstration of indefinite temporal order outside of quantum formalism. We show that our experimental outcomes are incompatible with a class of generalised probabilistic theories satisfying the assumptions of locality and definite temporal order. To this end, we derive physical constraints (in the form of a Bell-like inequality) on experimental outcomes within such a class of theories. We then experimentally invalidate these theories by violating the inequality using entangled temporal order. This provides experimental evidence that there exist correlations in nature which are incompatible with the assumptions of locality and definite temporal order., Comment: 29 pages, 8 figures

Published
2017
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23. Experimental Verification of an Indefinite Causal Order

Author

Rubino, Giulia, Rozema, Lee A., Feix, Adrien, Araújo, Mateus, Zeuner, Jonas M., Procopio, Lorenzo M., Brukner, Časlav, and Walther, Philip

Subjects
Quantum Physics
Abstract

Investigating the role of causal order in quantum mechanics has recently revealed that the causal distribution of events may not be a-priori well-defined in quantum theory. While this has triggered a growing interest on the theoretical side, creating processes without a causal order is an experimental task. Here we report the first decisive demonstration of a process with an indefinite causal order. To do this, we quantify how incompatible our set-up is with a definite causal order by measuring a 'causal witness'. This mathematical object incorporates a series of measurements which are designed to yield a certain outcome only if the process under examination is not consistent with any well-defined causal order. In our experiment we perform a measurement in a superposition of causal orders - without destroying the coherence - to acquire information both inside and outside of a 'causally non-ordered process'. Using this information, we experimentally determine a causal witness, demonstrating by almost seven standard deviations that the experimentally implemented process does not have a definite causal order., Comment: 11 pages + a 9-page Appendix; 5 figures + 5 in the Appendix. Corrected definitions of unitaries in Appendix

Published
2016
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24. Comment on Adler's 'Does the Peres experiment using photons test for hyper-complex (quaternionic) quantum theories?'

Author

Procopio, Lorenzo M., Rozema, Lee A., Dakić, Borivoje, and Walther, Philip

Subjects
Quantum Physics
Abstract

In his recent article [arXiv:1604.04950], Adler questions the usefulness of the bound found in our experimental search for genuine effects of hyper-complex quantum mechanics [arXiv:1602.01624]. Our experiment was performed using a black-box (instrumentalist) approach to generalized probabilistic theories; therefore, it does not assume a priori any particular underlying mechanism. From that point of view our experimental results do indeed place meaningful bounds on possible effects of "post-quantum theories", including quaternionic quantum mechanics. In his article, Adler compares our experiment to non-relativistic and M\"oller formal scattering theory within quaternionic quantum mechanics. With a particular set of assumptions, he finds that quaternionic effects would likely not manifest themselves in general. Although these assumptions are justified in the non-relativistic case, a proper calculation for relativistic particles is still missing. Here, we provide a concrete relativistic example of Klein-Gordon scattering wherein the quaternionic effects persist. We note that when the Klein-Gordon equation is formulated using a Hamiltonian formalism it displays a so-called "indefinite metric", a characteristic feature of relativistic quantum wave equations. In Adler's example this is directly forbidden by his assumptions, and therefore our present example is not in contradiction to his work. In complex quantum mechanics this problem of an indefinite metric is solved in second quantization. Unfortunately, there is no known algorithm for canonical field quantization in quaternionic quantum mechanics., Comment: 5 pages, one figure

Published
2016
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25. Experimental Test of Hyper-Complex Quantum Theories

Author

Procopio, Lorenzo M., Rozema, Lee A., Wong, Zi Jing, Hamel, Deny R., O'Brien, Kevin, Zhang, Xiang, Dakic, Borivoje, and Walther, Philip

Subjects
Quantum Physics
Abstract

In standard quantum mechanics, complex numbers are used to describe the wavefunction. Although complex numbers have proven sufficient to predict the results of existing experiments, there is no apparent theoretical reason to choose them over real numbers or generalizations of complex numbers, i.e. hyper-complex numbers. Experiments performed to date have proven that real numbers are insufficient, but whether or not hyper-complex numbers are required remains an open question. Quantum theories based on hyper-complex numbers are one example of a post-quantum theory, which must be put on a firm experimental foundation. Here we experimentally probe hyper-complex quantum theories, by studying one of their deviations from complex quantum theory: the non-commutativity of phases. We do so by passing single photons through a Sagnac interferometer containing two physically different phases, having refractive indices of opposite sign. By showing that the phases commute with high precision, we place limits on a particular prediction of hyper-complex quantum theories.

Published
2016

26. Single-photon test of hyper-complex quantum theories using a metamaterial.

Author

Procopio, Lorenzo M, Rozema, Lee A, Wong, Zi Jing, Hamel, Deny R, O'Brien, Kevin, Zhang, Xiang, Dakić, Borivoje, and Walther, Philip

Abstract

In standard quantum mechanics, complex numbers are used to describe the wavefunction. Although this has so far proven sufficient to predict experimental results, there is no theoretical reason to choose them over real numbers or generalizations of complex numbers, that is, hyper-complex numbers. Experiments performed to date have proven that real numbers are insufficient, but the need for hyper-complex numbers remains an open question. Here we experimentally probe hyper-complex quantum theories, studying one of their deviations from complex quantum theory: the non-commutativity of phases. We do so by passing single photons through a Sagnac interferometer containing both a metamaterial with a negative refractive index, and a positive phase shifter. To accomplish this we engineered a fishnet metamaterial to have a negative refractive index at 780 nm. We show that the metamaterial phase commutes with other phases with high precision, allowing us to place limits on a particular prediction of hyper-complex quantum theories.

Published
2017

28. Characterizing an Entangled-Photon Source with Classical Detectors and Measurements

Author

Rozema, Lee A., Wang, Chao, Mahler, Dylan H., Hayat, Alex, Steinberg, Aephraim M., Sipe, John E., and Liscidini, Marco

Subjects
Quantum Physics
Abstract

Quantum state tomography (QST) is a universal tool for the design and optimization of entangled-photon sources. It typically requires single-photon detectors and coincidence measurements. Recently, it was suggested that the information provided by the QST of photon pairs generated by spontaneous parametric down-conversion could be obtained by exploiting the stimulated version of this process, namely difference frequency generation. In this protocol, so-called "stimulated-emission tomography" (SET), a seed field is injected along with the pump pulse, and the resulting stimulated emission is measured. Since the intensity of the stimulated field can be several orders of magnitude larger than the intensity of the corresponding spontaneous emission, measurements can be made with simple classical detectors. Here, we experimentally demonstrate SET and compare it with QST. We show that one can accurately reconstruct the polarization density matrix, and predict the purity and concurrence of the polarization state of photon pairs without performing any single-photon measurements., Comment: 5+3 pages, 5 figures, 1 table

Published
2014

29. Experimental Superposition of Orders of Quantum Gates

Author

Procopio, Lorenzo M., Moqanaki, Amir, Araújo, Mateus, Costa, Fabio, Calafell, Irati A., Dowd, Emma G., Hamel, Deny R., Rozema, Lee A., Brukner, Časlav, and Walther, Philip

Subjects
Quantum Physics
Abstract

In a quantum computer, creating superpositions of quantum bits (qubits) in different states can lead to a speed-up over classical computers [1], but quantum mechanics also allows for the superposition of quantum circuits [2]. In fact, it has recently been theoretically predicted that superimposing quantum circuits, each with a different gate order, could provide quantum computers with an even further computational advantage [3-5]. Here, we experimentally demonstrate this enhancement by applying two quantum gates in a superposition of both possible orders to determine whether the two gates commute or anti-commute. We are able to make this determination with only a single use (or query) of each gate, while all quantum circuits with a fixed order of gates would require at least two uses of one of the gates [3]. Remarkably, when the problem is scaled to N gates, creating a superposition of quantum circuits is likely to provide an exponential advantage over classical algorithms, and a linear advantage over quantum algorithms with fixed gate order [4]. The new resource that we exploit in our experiment can be interpreted as a "superposition of causal orders". We demonstrate such a superposition could allow some quantum algorithms to be implemented with an efficiency that is unlikely to be achieved on a quantum computer with a fixed gate order., Comment: 10 pages, 7 figures, 2 tables

Published
2014
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30. Quantum Data Compression of a Qubit Ensemble

Author

Rozema, Lee A., Mahler, Dylan H., Hayat, Alex, Turner, Peter S., and Steinberg, Aephraim M.

Subjects
Quantum Physics
Abstract

Data compression is a ubiquitous aspect of modern information technology, and the advent of quantum information raises the question of what types of compression are feasible for quantum data, where it is especially relevant given the extreme difficulty involved in creating reliable quantum memories. We present a protocol in which an ensemble of quantum bits (qubits) can in principle be perfectly compressed into exponentially fewer qubits. We then experimentally implement our algorithm, compressing three photonic qubits into two. This protocol sheds light on the subtle differences between quantum and classical information. Furthermore, since data compression stores all of the available information about the quantum state in fewer physical qubits, it could provide a vast reduction in the amount of quantum memory required to store a quantum ensemble, making even today's limited quantum memories far more powerful than previously recognized.

Published
2014
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31. On the Optimal Choice of Spin-Squeezed States for Detecting and Characterizing a Quantum Process

Author

Rozema, Lee A., Mahler, Dylan H., Blume-Kohout, Robin, and Steinberg, Aephraim M.

Subjects
Quantum Physics
Abstract

Quantum metrology uses quantum states with no classical counterpart to measure a physical quantity with extraordinary sensitivity or precision. Most metrology schemes measure a single parameter of a dynamical process by probing it with a specially designed quantum state. The success of such a scheme usually relies on the process belonging to a particular one-parameter family. If this assumption is violated, or if the goal is to measure more than one parameter, a different quantum state may perform better. In the most extreme case, we know nothing about the process and wish to learn everything. This requires quantum process tomography, which demands an informationally-complete set of probe states. It is very convenient if this set is group-covariant -- i.e., each element is generated by applying an element of the quantum system's natural symmetry group to a single fixed fiducial state. In this paper, we consider metrology with 2-photon ("biphoton") states, and report experimental studies of different states' sensitivity to small, unknown collective SU(2) rotations ("SU(2) jitter"). Maximally entangled N00N states are the most sensitive detectors of such a rotation, yet they are also among the worst at fully characterizing an a-priori unknown process. We identify (and confirm experimentally) the best SU(2)-covariant set for process tomography; these states are all less entangled than the N00N state, and are characterized by the fact that they form a 2-design., Comment: 10 pages, 5 figures

Published
2014
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32. Scalable Spatial Super-Resolution using Entangled Photons

Author

Rozema, Lee A., Bateman, James D., Mahler, Dylan H., Okamoto, Ryo, Feizpour, Amir, Hayat, Alex, and Steinberg, Aephraim M.

Subjects
Quantum Physics
Abstract

N00N states -- maximally path-entangled states of N photons -- exhibit spatial interference patterns sharper than any classical interference pattern. This is known as super-resolution. However, even with perfectly efficient number-resolving detectors, the detection efficiency of all previously demonstrated methods to measure such interference decreases exponentially with the number of photons in the N00N state, often leading to the conclusion that N00N states are unsuitable for spatial measurements. Here, we create spatial super-resolution fringes with two-, three-, and four-photon N00N states, and demonstrate a scalable implementation of the so-called ``optical centroid measurement'' which provides an in-principle perfect detection efficiency. Moreover, we compare the N00N-state interference to the corresponding classical super-resolution interference. Although both provide the same increase in spatial frequency, the visibility of the classical fringes decreases exponentially with the number of detected photons, while the visibility of our experimentally measured N00N-state super-resolution fringes remains approximately constant with N. Our implementation of the optical centroid measurement is a scalable method to measure high photon-number quantum interference, an essential step forward for quantum-enhanced measurements, overcoming what was believed to be a fundamental challenge to quantum metrology.

Published
2013
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33. Macroscopic coherence between quantum condensates formed at different times

Author

Hayat, Alex, Lange, Christoph, Rozema, Lee A., Chang, Rockson, Potnis, Shreyas, van Driel, Henry M., Steinberg, Aephraim M., Steger, Mark, Snoke, David W., Pfeiffer, Loren N., and West, Kenneth W.

Subjects
Condensed Matter - Quantum Gases, Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics
Abstract

We demonstrate macroscopic coherence between quantum condensates generated at different times, separated by more than the particle dephasing time. This is possible due to the dressed light-matter nature of exciton-polaritons, which can be injected resonantly by optical excitation at well-defined momenta. We show that the build-up of coherence between condensates depends on the interaction between the particles, particle density, as well as temperature despite the non-equilibrium nature of the condensate, whereas the mass of the particles plays no role in the condensation of resonantly injected polaritons. This experiment also makes it possible for us to measure directly the large nonlinear phase shift resulting from the polariton-polariton interaction energy. Our results provide direct evidence for coherence between different condensates and demonstrate a new approach for probing their ultrafast dynamics, opening new directions in the study of matter coherence as well as in practical applications such as quantum information and ultrafast logic.

Published
2013

34. A Note on Different Definitions of Momentum Disturbance

Author

Rozema, Lee A., Mahler, Dylan H., Hayat, Alex, and Steinberg, Aephraim M.

Subjects
Quantum Physics
Abstract

In [1], Busch et al. showed that it is possible to construct an error-disturbance relation having the same form as Heisenberg's original heuristic definition[2], in contrast to the theory proposed by Ozawa[3] which we and others recently confirmed experimentally[4,5]. With Ozawa's definitions of measurement error and disturbance, a relation of Heisenberg's form is not in general valid, and a new error-disturbance relationship can be derived. Here we explain the different physical significance of the two definitions, and suggest that Ozawa's definition better corresponds to the usual understanding of the disturbance that Heisenberg discussed.

Published
2013

35. Adaptive quantum state tomography improves accuracy quadratically

Author

Mahler, D. H., Rozema, Lee A., Darabi, Ardavan, Ferrie, Chris, Blume-Kohout, Robin, and Steinberg, A. M.

Subjects
Quantum Physics
Abstract

We introduce a simple protocol for adaptive quantum state tomography, which reduces the worst-case infidelity between the estimate and the true state from $O(N^{-1/2})$ to $O(N^{-1})$. It uses a single adaptation step and just one extra measurement setting. In a linear optical qubit experiment, we demonstrate a full order of magnitude reduction in infidelity (from $0.1%$ to $0.01%$) for a modest number of samples ($N=3\times10^4$)., Comment: 8 pages, 7 figures

Published
2013
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36. Violation of Heisenberg's Measurement-Disturbance Relationship by Weak Measurements

Author

Rozema, Lee A., Darabi, Ardavan, Mahler, Dylan H., Hayat, Alex, Soudagar, Yasaman, and Steinberg, Aephraim M.

Subjects
Quantum Physics
Abstract

While there is a rigorously proven relationship about uncertainties intrinsic to any quantum system, often referred to as "Heisenberg's Uncertainty Principle," Heisenberg originally formulated his ideas in terms of a relationship between the precision of a measurement and the disturbance it must create. Although this latter relationship is not rigorously proven, it is commonly believed (and taught) as an aspect of the broader uncertainty principle. Here, we experimentally observe a violation of Heisenberg's "measurement-disturbance relationship", using weak measurements to characterize a quantum system before and after it interacts with a measurement apparatus. Our experiment implements a 2010 proposal of Lund and Wiseman to confirm a revised measurement-disturbance relationship derived by Ozawa in 2003. Its results have broad implications for the foundations of quantum mechanics and for practical issues in quantum mechanics., Comment: 5 pages, 4 figures

Published
2012
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37. Dynamic Stark Effect in Strongly Coupled Microcavity Exciton-Polaritons

Author

Hayat, Alex, Lange, Christoph, Rozema, Lee A., Darabi, Ardavan, van Driel, Henry M., Steinberg, Aephraim M., Nelsen, Bryan, Snoke, David W., Pfeiffer, Loren N., and West, Kenneth W.

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

We present experimental observations of a non-resonant dynamic Stark shift in strongly coupled microcavity quantum well exciton-polaritons - a system which provides a rich variety of solid-state collective phenomena. The Stark effect is demonstrated in a GaAs/AlGaAs system at 10K by femtosecond pump-probe measurements, with the blue shift approaching the meV scale for a pump fluence of 2 mJcm^-2 and 50 meV red detuning, in good agreement with theory. The energy level structure of the strongly coupled polariton Rabi-doublet remains unaffected by the blue shift. The demonstrated effect should allow generation of ultrafast density-independent potentials and imprinting well-defined phase profiles on polariton condensates, providing a powerful tool for manipulation of these condensates, similar to dipole potentials in cold atom systems.

Published
2012
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38. Self-calibrating Quantum State Tomography

Author

Branczyk, Agata M., Mahler, Dylan H., Rozema, Lee A., Darabi, Ardavan, Steinberg, Aephraim M., and James, Daniel F. V.

Subjects
Quantum Physics
Abstract

We introduce and experimentally demonstrate a technique for performing quantum state tomography on multiple-qubit states despite incomplete knowledge about the unitary operations used to change the measurement basis. Given unitary operations with unknown rotation angles, our method can be used to reconstruct the density matrix of the state up to local sigma-z rotations as well as recover the magnitude of the unknown rotation angle. We demonstrate high-fidelity self-calibrating tomography on polarization-encoded one- and two-photon states. The unknown unitary operations are realized in two ways: using a birefringent polymer sheet---an inexpensive smartphone screen protector---or alternatively a liquid crystal wave plate with a tuneable retardance. We explore how our technique may be adapted for quantum state tomography of systems such as biological molecules where the magnitude and orientation of the transition dipole moment is not known with high accuracy., Comment: 13 pages, 4 figures

Published
2011
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39. A reply to 'Problems with modelling closed timelike curves as post-selected teleportation'

Author

Lloyd, Seth, Maccone, Lorenzo, Garcia-Patron, Raul, Giovannetti, Vittorio, Shikano, Yutaka, Pirandola, Stefano, Rozema, Lee A., Darabi, Ardavan, Soudagar, Yasaman, Shalm, Lynden K., and Steinberg, Aephraim M.

Subjects
Quantum Physics
Abstract

In arXiv:1107.4675 Ralph uses our post-selection model of closed timelike curves (P-CTC) to construct an "unproven-theorem" paradox, and claims that this voids our argument that P-CTCs are able to resolve such types of paradoxes. Here we point out that Ralph has not accounted for all the interactions needed for his construction. A more careful analysis confirms that indeed there is no paradox, contrary to his claims., Comment: 2 pages, 1 figure

Published
2011

40. Closed timelike curves via post-selection: theory and experimental demonstration

Author

Lloyd, Seth, Maccone, Lorenzo, Garcia-Patron, Raul, Giovannetti, Vittorio, Shikano, Yutaka, Pirandola, Stefano, Rozema, Lee A., Darabi, Ardavan, Soudagar, Yasaman, Shalm, Lynden K., and Steinberg, Aephraim M.

Subjects
Quantum Physics
Abstract

Closed timelike curves (CTCs) are trajectories in spacetime that effectively travel backwards in time: a test particle following a CTC can in principle interact with its former self in the past. CTCs appear in many solutions of Einstein's field equations and any future quantum version of general relativity will have to reconcile them with the requirements of quantum mechanics and of quantum field theory. A widely accepted quantum theory of CTCs was proposed by Deutsch. Here we explore an alternative quantum formulation of CTCs and show that it is physically inequivalent to Deutsch's. Because it is based on combining quantum teleportation with post-selection, the predictions/retrodictions of our theory are experimentally testable: we report the results of an experiment demonstrating our theory's resolution of the well-known `grandfather paradox., Comment: 5 pages, 4 figures

Published
2010
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41. On the correct formula for the lifetime broadened superconducting density of states

Author

Mitrovic, Bozidar and Rozema, Lee A.

Subjects
Condensed Matter - Superconductivity
Abstract

We argue that the well known Dynes formula [Dynes R C {\it et al.} 1978 {\it Phys. Rev. Lett.} {\bf 41} 1509] for the superconducting quasiparticle density of states, which tries to incorporate the lifetime broadening in an approximate way, cannot be justified microscopically for conventional superconductors. Instead, we propose a new simple formula in which the energy gap has a finite imaginary part $-\Delta_2$ and the quasiparticle energy is real. We prove that in the quasiparticle approximation 2$\Delta_2$ gives the quasiparticle decay rate at the gap edge for conventional superconductors. This conclusion does not depend on the nature of interactions that cause the quasiparticle decay. The new formula is tested on the case of a strong coupling superconductor Pb$_{0.9}$Bi$_{0.1}$ and an excellent agreement with theoretical predictions is obtained. While both the Dynes formula and the one proposed in this work give good fits and fit parameters for Pb$_{0.9}$Bi$_{0.1}$, only the latter formula can be justified microscopically., Comment: 6 pages, 4 figures

Published
2007
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43. Photonic Maxwell’s Demon: Feed-forward methods for photonic thermodynamic tasks

Author

Jacquet Maxime, Zanin Guilherme, Antesberger Michael, Souto Ribeiro Paulo, Rozema Lee, and Walther Philip

Subjects
Physics, QC1-999
Abstract

Maxwell’s Demon is at the heart of the interrelation between quantum information processing and thermodynamics. In this thought experiment, a demon extracts work from two thermal baths at equilibrium by gaining information about them at the single-particle level and applying classical feed-forward operations. In this talk I will show how to implement a photonic version of Maxwell’s Demon with active feed-forward in a fiber-based system using ultrafast optical switches. This is the first realisation of an active Demon. The experiment [1] shows that, if correlations exist between the two thermal baths, the Demon can extract over an order of magnitude more work than without correlations. This demonstrates the great potential of photonic experiments – which provide a unique degree of control on the system – to access new regimes in quantum thermodynamics.

Published
2022
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50. High‐Harmonic Generation Enhancement with Graphene Heterostructures

Author

Alonso Calafell, Irati, primary, Rozema, Lee A., additional, Trenti, Alessandro, additional, Bohn, Justus, additional, Dias, Eduardo J. C., additional, Jenke, Philipp K., additional, Menghrajani, Kishan S., additional, Alcaraz Iranzo, David, additional, García de Abajo, F. Javier, additional, Koppens, Frank H. L., additional, Hendry, Euan, additional, and Walther, Philip, additional

Published
2022
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