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Journal articleMa Y, Hanks M, Kim MS, 2023,
Non-Pauli errors can be efficiently sampled in qudit surface codes
, Physical Review Letters, Vol: 131, ISSN: 0031-9007Surface codes are the most promising candidates for fault-tolerant quantum computation. Single qudit errors are typically modeled as Pauli operators, to which general errors are converted via randomizing methods. In this Letter, we quantify remaining correlations after syndrome measurement for a qudit 2D surface code subject to non-Pauli errors via loops on the lattice, using percolation theory. Below the error correction threshold, remaining correlations are sparse and locally constrained. Syndromes for qudit surface codes are therefore efficiently samplable for non-Pauli errors, independent of the exact forms of the error and decoder.
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Journal articleHutchison CDM, Baxter JM, Fitzpatrick A, et al., 2023,
Optical control of ultrafast structural dynamics in a fluorescent protein
, NATURE CHEMISTRY, ISSN: 1755-4330 -
Journal articleSmorra C, Abbass F, Schweitzer D, et al., 2023,
BASE-STEP: a transportable antiproton reservoir for fundamental interaction studies
, Review of Scientific Instruments, Vol: 94, ISSN: 0034-6748Currently, the world's only source of low-energy antiprotons is the AD/ELENA facility located at CERN. To date, all precision measurements on single antiprotons have been conducted at this facility and provide stringent tests of fundamental interactions and their symmetries. However, magnetic field fluctuations from the facility operation limit the precision of upcoming measurements. To overcome this limitation, we have designed the transportable antiproton trap system BASE-STEP to relocate antiprotons to laboratories with a calm magnetic environment. We anticipate that the transportable antiproton trap will facilitate enhanced tests of charge, parity, and time-reversal invariance with antiprotons and provide new experimental possibilities of using transported antiprotons and other accelerator-produced exotic ions. We present here the technical design of the transportable trap system. This includes the transportable superconducting magnet, the cryogenic inlay consisting of the trap stack and detection systems, and the differential pumping section to suppress the residual gas flow into the cryogenic trap chamber.
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Journal articleYu S, Zhong Z-P, Fang Y, et al., 2023,
A universal programmable Gaussian boson sampler for drug discovery
, NATURE COMPUTATIONAL SCIENCE -
Journal articleAlexander O, Barnard J, Larsen E, et al., 2023,
Observation of recollision-based high-harmonic generation in liquid isopropanol and the role of electron scattering
, Physical Review Research, ISSN: 2643-1564 -
Journal articleSmith AWR, Paige AJ, Kim MS, 2023,
Faster variational quantum algorithms with quantum kernel-based surrogate models
, Quantum Science and Technology, Vol: 8, ISSN: 2058-9565We present a new optimization strategy for small-to-intermediate scale variational quantum algorithms (VQAs) on noisy near-term quantum processors which uses a Gaussian process surrogate model equipped with a classically-evaluated quantum kernel. VQAs are typically optimized using gradient-based approaches however these are difficult to implement on current noisy devices, requiring large numbers of objective function evaluations. Our approach shifts this computational burden onto the classical optimizer component of these hybrid algorithms, greatly reducing the number of quantum circuit evaluations required from the quantum processor. We focus on the variational quantum eigensolver (VQE) algorithm and demonstrate numerically that these surrogate models are particularly well suited to the algorithm's objective function. Next, we apply these models to both noiseless and noisy VQE simulations and show that they exhibit better performance than widely-used classical kernels in terms of final accuracy and convergence speed. Compared to the typically-used stochastic gradient-descent approach to VQAs, our quantum kernel-based approach is found to consistently achieve significantly higher accuracy while requiring less than an order of magnitude fewer quantum circuit executions. We analyze the performance of the quantum kernel-based models in terms of the kernels' induced feature spaces and explicitly construct their feature maps. Finally, we describe a scheme for approximating the best-performing quantum kernel using a classically-efficient tensor network representation of its input state and so provide a pathway for scaling this strategy to larger systems.
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Journal articleLatacz BM, Arndt BP, Devlin JA, et al., 2023,
Ultra-thin polymer foil cryogenic window for antiproton deceleration and storage
, REVIEW OF SCIENTIFIC INSTRUMENTS, Vol: 94, ISSN: 0034-6748 -
Journal articleYu S, Zhong Z-P, Fang Y, et al., 2023,
A universal programmable Gaussian boson sampler for drug discovery.
, Nat Comput Sci, Vol: 3, Pages: 839-848Gaussian boson sampling (GBS) has the potential to solve complex graph problems, such as clique finding, which is relevant to drug discovery tasks. However, realizing the full benefits of quantum enhancements requires large-scale quantum hardware with universal programmability. Here we have developed a time-bin-encoded GBS photonic quantum processor that is universal, programmable and software-scalable. Our processor features freely adjustable squeezing parameters and can implement arbitrary unitary operations with a programmable interferometer. Leveraging our processor, we successfully executed clique finding on a 32-node graph, achieving approximately twice the success probability compared to classical sampling. As proof of concept, we implemented a versatile quantum drug discovery platform using this GBS processor, enabling molecular docking and RNA-folding prediction tasks. Our work achieves GBS circuitry with its universal and programmable architecture, advancing GBS toward use in real-world applications.
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Journal articleZeng X-D, Yang Y-Z, Guo N-J, et al., 2023,
Reflective dielectric cavity enhanced emission from hexagonal boron nitride spin defect arrays.
, Nanoscale, Vol: 15, Pages: 15000-15007Among the various kinds of spin defects in hexagonal boron nitride (hBN), the negatively charged boron vacancy (VB-) spin defect that can be site-specifically generated is undoubtedly a potential candidate for quantum sensing, but its low quantum efficiency restricts its practical applications. Here, we demonstrate a robust enhancement structure called reflective dielectric cavity (RDC) with advantages including easy on-chip integration, convenient processing, low cost and suitable broad-spectrum enhancement for VB- defects. In the experiment, we used a metal reflective layer under the hBN flakes, filled with a transition dielectric layer in the middle, and adjusted the thickness of the dielectric layer to achieve the best coupling between RDC and spin defects in hBN. A remarkable 11-fold enhancement in the fluorescence intensity of VB- spin defects in hBN flakes can be achieved. By designing the metal layer into a waveguide structure, high-contrast optically detected magnetic resonance (ODMR) signal (∼21%) can be obtained. The oxide layer of the RDC can be used as the integrated material to implement secondary processing of micro-nano photonic devices, which means that it can be combined with other enhancement structures to achieve stronger enhancement. This work has guiding significance for realizing the on-chip integration of spin defects in two-dimensional materials.
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Journal articleWright SC, Doppelbauer M, Hofsass S, et al., 2023,
Cryogenic buffer gas beams of AlF, CaF, MgF, YbF, Al, Ca, Yb and NO - a comparison
, MOLECULAR PHYSICS, Vol: 121, ISSN: 0026-8976 -
Journal articleEngel RY, Alexander O, Atak K, et al., 2023,
Electron population dynamics in resonant non-linear x-ray absorption in nickel at a free-electron laser
, STRUCTURAL DYNAMICS-US, Vol: 10 -
Journal articleHajivassiliou G, Kassapis M, Tisch JWG, 2023,
Rapid retrieval of femtosecond and attosecond pulses from streaking traces using convolutional neural networks
, New Journal of Physics, Vol: 25, ISSN: 1367-2630Attosecond streaking is a powerful and versatile technique that allows the full-field characterisation of femtosecond to attosecond optical pulses. It has been instrumental in the verification of attosecond pulse generation and probing of ultrafast dynamics in matter. Recently, machine learning (ML) has been applied to retrieve the fields from streaking data (White and Chang 2019 Opt. Express27 4799; Zhu et al 2020 Sci. Rep.10 5782; Brunner et al 2022 Opt. Express30 15669–84). This offers a number of advantages compared with traditional iterative algorithms, including faster processing and better resilience to noise. Here, we implement a ML approach based on convolutional neural networks and limit the search to physically realistic pulses that can be specified with a small number of parameters. This leads to substantial reductions in both training and retrieval times, enabling near kHz retrieval rates. We examine how the retrieval performance is affected by noise, and for the first time in this context, study the effect of missing data. We show that satisfactory retrievals are still possible with signal to noise ratios as low as 10, and with up to $40\%$ of data missing.
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Journal articleHutchison CDM, Baxter JM, Fitzpatrick A, et al., 2023,
Optical control of ultrafast structural dynamics in a fluorescent protein
, NATURE CHEMISTRY, ISSN: 1755-4330 -
Journal articleMukherjee B, Frye MD, Le Sueur CR, et al., 2023,
Shielding collisions of ultracold CaF molecules with static electric fields
, Physical Review Research, Vol: 5, ISSN: 2643-1564We study collisions of ultracold CaF molecules in strong static electric fields. These fields allow the creationof long-range barriers in the interaction potential, effectively preventing the molecules from reaching theshort-range region where inelastic and other loss processes are likely to occur. We carry out coupled-channelcalculations of rate coefficients for elastic scattering and loss. We develop an efficient procedure for includingenergetically well-separated rotor functions in the basis set via a Van Vleck transformation. We show thatshielding is particularly efficient for CaF and allows the rate of two-body loss processes to be reduced by a factorof 107 or more at a field of 23 kV/cm. The loss rates remain low over a substantial range of fields. Electron andnuclear spins cause strong additional loss in some small ranges of field, but have little effect elsewhere. Theseresults pave the way for evaporative cooling of CaF towards quantum degeneracy
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Journal articleClarke J, Neveu P, Khosla KE, et al., 2023,
Cavity quantum optomechanical nonlinearities and position measurement beyond the breakdown of the linearized approximation
, Physical Review Letters, Vol: 131, ISSN: 0031-9007Several optomechanics experiments are now entering the highly sought nonlinear regime where optomechanical interactions are large even for low light levels. Within this regime, new quantum phenomena and improved performance may be achieved; however, a corresponding theoretical formalism of cavity quantum optomechanics that captures the nonlinearities of both the radiation-pressure interaction and the cavity response is needed to unlock these capabilities. Here, we develop such a nonlinear cavity quantum optomechanical framework, which we then utilize to propose how position measurement can be performed beyond the breakdown of the linearized approximation. Our proposal utilizes optical general-dyne detection, ranging from single to dual homodyne, to obtain mechanical position information imprinted onto both the optical amplitude and phase quadratures and enables both pulsed and continuous modes of operation. These cavity optomechanical nonlinearities are now being confronted in a growing number of experiments, and our framework will allow a range of advances to be made in, e.g., quantum metrology, explorations of the standard quantum limit, and quantum measurement and control.
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Journal articleThekkadath G, England D, Bouchard F, et al., 2023,
Intensity interferometry for holography with quantum and classical light
, Science Advances, Vol: 9, ISSN: 2375-2548As first demonstrated by Hanbury Brown and Twiss, it is possible to observe interference between independent light sources by measuring correlations in their intensities rather than their amplitudes. In this work, we apply this concept of intensity interferometry to holography. We combine a signal beam with a reference and measure their intensity cross-correlations using a time-tagging single-photon camera. These correlations reveal an interference pattern from which we reconstruct the signal wavefront in both intensity and phase. We demonstrate the principle with classical and quantum light, including a single photon. Since the signal and reference do not need to be phase-stable nor from the same light source, this technique can be used to generate holograms of self-luminous or remote objects using a local reference, thus opening the door to new holography applications.
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Journal articleDriver T, Pipkorn R, Averbukh V, et al., 2023,
Identification of cofragmented combinatorial peptide isomers by two-dimensional partial covariance mass spectrometry
, Journal of the American Society for Mass Spectrometry, Vol: 34, Pages: 1230-1234, ISSN: 1044-0305Combinatorial post-translational modifications (PTMs), such as those forming the so-called “histone code”, have been linked to cell differentiation, embryonic development, cellular reprogramming, aging, cancers, neurodegenerative disorders, etc. Nevertheless, a reliable mass spectral analysis of the combinatorial isomers represents a considerable challenge. The difficulty stems from the incompleteness of information that could be generated by the standard MS to differentiate cofragmented isomeric sequences in their naturally occurring mixtures based on the fragment mass-to-charge ratio and relative abundance information only. Here we show that fragment–fragment correlations revealed by two-dimensional partial covariance mass spectrometry (2D-PC-MS) allow one to solve the combinatorial PTM puzzles that cannot be tackled by the standard MS as a matter of principle. We introduce 2D-PC-MS marker ion correlation approach and demonstrate experimentally that it can provide the missing information enabling identification of cofragmentated combinatorially modified isomers. Our in silico study shows that the marker ion correlations can be used to unambiguously identify 5 times more cofragmented combinatorially acetylated tryptic peptides and 3 times more combinatorially modified Glu-C peptides of human histones than is possible using standard MS methods.
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Journal articleChen W, Lu Y, Zhang S, et al., 2023,
Scalable and programmable phononic network with trapped ions
, Nature Physics, Vol: 19, Pages: 877-883, ISSN: 1745-2473A network of bosons evolving among different modes while passing through beam splitters and phase shifters has been applied to demonstrate quantum computational advantage. While such networks have mostly been implemented in optical systems using photons, alternative realizations addressing major limitations in photonic systems such as photon loss have been explored recently. Quantized excitations of vibrational modes (phonons) of trapped ions are a promising candidate to realize such bosonic networks. Here, we demonstrate a minimal-loss programmable phononic network in which any phononic state can be deterministically prepared and detected. We realize networks with up to four collective vibrational modes, which can be extended to reveal quantum advantage. We benchmark the performance of the network for an exemplary tomography algorithm using arbitrary multi-mode states with fixed total phonon number. We obtain high reconstruction fidelities for both single- and two-phonon states. Our experiment demonstrates a clear pathway to scale up a phononic network for quantum information processing beyond the limitations of classical and photonic systems.
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Journal articleTarlton JE, Thompson RC, Lucas DM, 2023,
Surface-electrode ion trap design for near-field microwave quantum gates
, Applied Physics B: Lasers and Optics, Vol: 129, ISSN: 0721-7269We present a design study into an ion trap electrode geometry for applying near-field microwave two-qubit gates. This design features an ‘S’-shaped meander electrode to passively null the microwave field. It has ground planes separating the meander electrode from all of the DC and single-qubit microwave electrodes, which should reduce the sensitivity of the microwave field distribution to the boundary conditions of these electrodes. We show that it is possible to design a single-layer trap with this geometry such that the simulated microwave field null overlaps with the RF field null, and that the positions of these nulls can be simulated to a precision of 100 nm with moderate computing resources. We also show that such a trap can be designed such that ion chains can be trapped, transported and split with feasible DC and RF voltages. While this particular design is optimized for 43Ca+ ions, our approach could be applied to other ions by changing the microwave frequency tomatch the corresponding qubit transition frequency.
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Journal articleLatacz BM, Arndt BP, Bauer BB, et al., 2023,
BASE-high-precision comparisons of the fundamental properties of protons and antiprotons
, EUROPEAN PHYSICAL JOURNAL D, Vol: 77, ISSN: 1434-6060 -
Journal articleBird RC, Tarbutt MR, Hutson JM, 2023,
Tunable Feshbach resonances in collisions of ultracold molecules in ²∑ states with alkali-metal atoms
, Physical Review Research, Vol: 5, ISSN: 2643-1564We consider the magnetically tunable Feshbach resonances that may exist in ultracold mixtures of moleculesin 2 states and alkali-metal atoms. We focus on Rb+CaF as a prototype system. There are likely to be Feshbachresonances analogous to those between pairs of alkali-metal atoms. We investigate the patterns of near-thresholdstates and the resonances that they cause, using coupled-channel calculations of the bound states and low-energyscattering on model interaction potentials. We explore the dependence of the properties on as-yet-unknownpotential parameters. There is a high probability that resonances will exist at magnetic fields below 1000 G,and that these will be broad enough to control collisions and form triatomic molecules by magnetoassociation.We consider the effects of CaF rotation and anisotropy of the interaction potential, and conclude that they mayproduce additional resonances but should not affect the existence of rotation-free resonances.
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Journal articleLing Y, Qvarfort S, Mintert F, 2023,
Fast optomechanical photon blockade
, Physical Review Research, Vol: 5, Pages: 1-14, ISSN: 2643-1564The photon blockade effect is commonly exploited in the development of single-photon sources. While the photon blockade effect could be used to prepare high-fidelity single-photon states in idealized regimes, practical implementations in optomechanical systems suffer from an interplay of competing processes. Here we derive a control scheme that exploits destructive interference of Fock state amplitudes of more than one photon. The resulting preparation time for photon-blockaded quantum states is limited only by the optomechanical interaction strength and can thus be orders of magnitude shorter than in existing schemes that achieve photon blockade in the steady state.
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Journal articleBergmann K, Eberly JH, Halfmann T, et al., 2023,
Editorial note for the J. Phys. B. special issue 'Coherent Control: Photons, Atoms and Molecules' honoring the life and work of Bruce W Shore
, JOURNAL OF PHYSICS B-ATOMIC MOLECULAR AND OPTICAL PHYSICS, Vol: 56, ISSN: 0953-4075 -
Journal articleRuberti M, Averbukh V, 2023,
Advances in modeling attosecond electron dynamics in molecular photoionization
, WILEY INTERDISCIPLINARY REVIEWS-COMPUTATIONAL MOLECULAR SCIENCE, ISSN: 1759-0876 -
Journal articleGuo N-J, Li S, Liu W, et al., 2023,
Coherent control of an ultrabright single spin in hexagonal boron nitride at room temperature.
, Nat Commun, Vol: 14Hexagonal boron nitride (hBN) is a remarkable two-dimensional (2D) material that hosts solid-state spins and has great potential to be used in quantum information applications, including quantum networks. However, in this application, both the optical and spin properties are crucial for single spins but have not yet been discovered simultaneously for hBN spins. Here, we realize an efficient method for arraying and isolating the single defects of hBN and use this method to discover a new spin defect with a high probability of 85%. This single defect exhibits outstanding optical properties and an optically controllable spin, as indicated by the observed significant Rabi oscillation and Hahn echo experiments at room temperature. First principles calculations indicate that complexes of carbon and oxygen dopants may be the origin of the single spin defects. This provides a possibility for further addressing spins that can be optically controlled.
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Journal articleGrell G, Guo Z, Driver T, et al., 2023,
Effect of the shot-to-shot variation on charge migration induced by sub-fs x-ray free-electron laser pulses
, PHYSICAL REVIEW RESEARCH, Vol: 5 -
Journal articleYang Y-Z, Zhu T-X, Li Z-P, et al., 2023,
Laser Direct Writing of Visible Spin Defects in Hexagonal Boron Nitride for Applications in Spin-Based Technologies
, ACS Applied Nano Materials, Vol: 6, Pages: 6407-6414, ISSN: 2574-0970 -
Journal articleCoste N, Gundin M, Fioretto DA, et al., 2023,
Probing the dynamics and coherence of a semiconductor hole spin via acoustic phonon-assisted excitation
, QUANTUM SCIENCE AND TECHNOLOGY, Vol: 8, ISSN: 2058-9565- Author Web Link
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- Citations: 2
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Journal articleShah R, Barrett TJ, Colcelli A, et al., 2023,
Probing the Degree of Coherence through the Full 1D to 3D Crossover
, PHYSICAL REVIEW LETTERS, Vol: 130, ISSN: 0031-9007 -
Journal articleCheng C, Frasinski LJ, Mogol G, et al., 2023,
Multiparticle Cumulant Mapping for Coulomb Explosion Imaging
, PHYSICAL REVIEW LETTERS, Vol: 130, ISSN: 0031-9007- Author Web Link
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- Citations: 1
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