Your search keyword '"Daley, Andrew J"' showing total 542 results

1. Engineered Chirality of One-Dimensional Nanowires

Author

Briggeman, Megan, Mansfield, Elliott, Kombe, Johannes, Damanet, François, Lee, Hyungwoo, Tang, Yuhe, Yu, Muqing, Biswas, Sayanwita, Li, Jianan, Huang, Mengchen, Eom, Chang-Beom, Irvin, Patrick, Daley, Andrew J., and Levy, Jeremy

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

The origin and function of chirality in DNA, proteins, and other building blocks of life represent a central question in biology. Observations of spin polarization and magnetization associated with electron transport through chiral molecules, known collectively as the chiral induced spin selectivity (CISS) effect, suggest that chirality improves electron transfer by inhibiting backscattering. Meanwhile, the role of coherence in the electron transport within chiral nanowires is believed to be important but is challenging to investigate experimentally. Using reconfigurable nanoscale control over conductivity at the LaAlO$_3$/SrTiO$_3$ interface, we create chiral electron potentials that explicitly lack mirror symmetry. Quantum transport measurements on these chiral regions that constitute effective nanowires for the electrons reveal oscillatory transmission resonances as a function of both magnetic field and chemical potential. We interpret these resonances as arising from an engineered axial spin-orbit interaction within the chiral region. The ability to create 1D effective electron waveguides with this specificity and complexity creates new opportunities to test, via analog quantum simulation, theories about the relationship between chirality and spin-polarized electron transport in one-dimensional geometries.

Published

2025

2. Entangled states from sparsely coupled spins for metrology with neutral atoms

Author

Kuriyattil, Sridevi, Poggi, Pablo M., Pritchard, Jonathan D., Kombe, Johannes, and Daley, Andrew J.

Subjects

Quantum Physics, Condensed Matter - Quantum Gases

Abstract

Quantum states featuring extensive multipartite entanglement are a resource for quantum-enhanced metrology, with sensitivity up to the Heisenberg limit. However, robust generation of these states using unitary dynamics typically requires all-to-all interactions among particles. Here, we demonstrate that optimal states for quantum sensing can be generated with sparse interaction graphs featuring only a logarithmic number of couplings per particle. We show that specific sparse graphs with long-range interactions can approximate the dynamics of all-to-all spin models, such as the one-axis twisting model, even for large system sizes. The resulting sparse coupling graphs and protocol can also be efficiently implemented using dynamic reconfiguration of atoms in optical tweezers., Comment: 5 Pages + Supplementary Material. 4 figures in the main text

Published

2024

3. Influenza A(H5N1) Virus Clade 2.3.2.1a in Traveler Returning to Australia from India, 2024

Author

Deng, Yi-Mo, Wille, Michelle, Dapat, Clyde, Xie, Ruopeng, Lay, Olivia, Peck, Heidi, Daley, Andrew J., Dhanasakeran, Vijaykrishna, and Barr, Ian G.

Subjects

World Health Organization, Diseases, Baloxavir marboxil, Travelers, Avian influenza, Avian influenza viruses

Abstract

The global panzootic of highly pathogenic avian influenza (HPAI) A(H5N1) clade 2.3.4.4b is affecting wild and domestic birds and mammals worldwide (1). This viral clade emerged after decades of evolution [...]

Published

2025

4. Few-body bound topological and flat-band states in a Creutz Ladder

Author

Pelegrí, Gerard, Flannigan, Stuart, and Daley, Andrew J.

Subjects

Condensed Matter - Quantum Gases

Abstract

We investigate the properties of few interacting bosons in a Creutz ladder, which has become a standard model for topological systems, and which can be realised in experiments with cold atoms in optical lattices. At the single-particle level, this system may exhibit a completely flat energy landscape with non-trivial topological properties. In this scenario, we identify topological two-body edge states resulting from the bonding of single-particle edge and flat-band states. We also explore the formation of two- and three-body bound states in the strongly-interacting limit, and we show how these quasi-particles can be engineered to replicate the flat-band and topological features of the original single-particle model. Furthermore, we show that in this geometry perfect Aharonov-Bohm caging of two-body bound states may occur for arbitrary interaction strengths, and we provide numerical evidence that the main features of this effect are preserved in an interacting many-body scenario resulting in many-body Aharonov-Bohm caging.

Published

2024

5. Commensurate and incommensurate 1D interacting quantum systems

Author

Di Carli, Andrea, Parsonage, Christopher, La Rooij, Arthur, Koehn, Lennart, Ulm, Clemens, Duncan, Callum W., Daley, Andrew J., Haller, Elmar, and Kuhr, Stefan

Published

2024

6. Onset of scrambling as a dynamical transition in tunable-range quantum circuits

Author

Kuriyattil, Sridevi, Hashizume, Tomohiro, Bentsen, Gregory, and Daley, Andrew J.

Subjects

Quantum Physics, Condensed Matter - Quantum Gases

Abstract

In a fast scrambling many-body quantum system, information is spread and entanglement is built up on a timescale that grows logarithmically with the system size. This is of fundamental interest in understanding the dynamics of many-body systems, as well as in efficiently producing entangled resource states and error-correcting codes. In this work, we identify a dynamical transition marking the onset of scrambling in quantum circuits with different levels of long-range connectivity. In particular, we show that as a function of the interaction range for circuits of different structures, the tripartite mutual information exhibits a scaling collapse around a critical point between two clearly defined regimes of different dynamical behaviour. We study this transition analytically in a related long-range Brownian circuit model and show how the transition can be mapped onto the statistical mechanics of a long-range Ising model in a particular region of parameter space. This mapping predicts mean-field critical exponents $\nu = -1/(1+s_c)$, which are consistent with the critical exponents extracted from Clifford circuit numerics. In addition to systems with conventional power-law interactions, we identify the same phenomenon in deterministic, sparse circuits that can be realised in experiments with neutral atom arrays., Comment: 19 pages, 9 figures

Published

2023

7. Many-body spin rotation by adiabatic passage in spin-1/2 XXZ chains of ultracold atoms

Author

Dimitrova, Ivana, Flannigan, Stuart, Lee, Yoo Kyung, Lin, Hanzhen, Amato-Grill, Jesse, Jepsen, Niklas, Cepaite, Ieva, Daley, Andrew J., and Ketterle, Wolfgang

Subjects

Condensed Matter - Quantum Gases, Physics - Atomic Physics

Abstract

Quantum many-body phases offer unique properties and emergent phenomena, making them an active area of research. A promising approach for their experimental realization in model systems is to adiabatically follow the ground state of a quantum Hamiltonian from a product state of isolated particles to one that is strongly-correlated. Such protocols are relevant also more broadly in coherent quantum annealing and adiabatic quantum computing. Here we explore one such protocol in a system of ultracold atoms in an optical lattice. A fully magnetized state is connected to a correlated zero-magnetization state (an xy-ferromagnet) by a many-body spin rotation, realized by sweeping the detuning and power of a microwave field. The efficiency is characterized by applying a reverse sweep with a variable relative phase. We restore up to 50% of the original magnetization independent of the relative phase, evidence for the formation of correlations. The protocol is limited by the many-body gap of the final state, which is inversely proportional to system size, and technical noise. Our experimental and theoretical studies highlight the potential and challenges for adiabatic preparation protocols to prepare many-body eigenstates of spin Hamiltonians.

Published

2022

8. Variational Quantum Algorithms for Computational Fluid Dynamics

Author

Jaksch, Dieter, Givi, Peyman, Daley, Andrew J., and Rung, Thomas

Subjects

Quantum Physics, Physics - Computational Physics, Physics - Fluid Dynamics

Abstract

Quantum computing uses the physical principles of very small systems to develop computing platforms which can solve problems that are intractable on conventional supercomputers. There are challenges not only in building the required hardware, but also in identifying the most promising application areas and developing the corresponding quantum algorithms. The availability of intermediate-scale noisy quantum computers is now propelling the developments of novel algorithms, with applications across a variety of domains, including in aeroscience. Variational quantum algorithms are particularly promising since they are comparatively noise tolerant and aim to achieve a quantum advantage with only a few hundred qubits. Furthermore, they are applicable to a wide range of optimization problems arising throughout the natural sciences and industry. To demonstrate the possibilities for the aeroscience community, we give a perspective on how variational quantum algorithms can be utilized in computational fluid dynamics. We discuss how classical problems are translated into quantum algorithms and their logarithmic scaling with problem size. As an explicit example we apply this method to Burgers' Equation in one spatial dimension. We argue that a quantum advantage over classical computing methods could be achieved by the end of this decade if quantum hardware progresses as currently envisaged and emphasize the importance of joining up development of quantum algorithms with application-specific expertise to achieve real-world impact., Comment: 22 pages, 5 figures, submitted to AIAA Virtual collection "Short Surveys of Quantum Information Science and Technology for Aerospace Research"

Published

2022

9. Counterdiabatic Optimised Local Driving

Author

Čepaitė, Ieva, Polkovnikov, Anatoli, Daley, Andrew J., and Duncan, Callum W.

Subjects

Quantum Physics, Condensed Matter - Quantum Gases

Abstract

Adiabatic protocols are employed across a variety of quantum technologies, from implementing state preparation and individual operations that are building blocks of larger devices, to higher-level protocols in quantum annealing and adiabatic quantum computation. The problem of speeding up these processes has garnered a large amount of interest, resulting in a menagerie of approaches, most notably quantum optimal control and shortcuts to adiabaticity. The two approaches are complementary: optimal control manipulates control fields to steer the dynamics in the minimum allowed time while shortcuts to adiabaticity aim to retain the adiabatic condition upon speed-up. We outline a new method which combines the two methodologies and takes advantage of the strengths of each. The new technique improves upon approximate local counterdiabatic driving with the addition of time-dependent control fields. We refer to this new method as counterdiabatic optimised local driving (COLD) and we show that it can result in a substantial improvement when applied to annealing protocols, state preparation schemes, entanglement generation and population transfer on a lattice. We also demonstrate a new approach to the optimisation of control fields which does not require access to the wavefunction or the computation of system dynamics. COLD can be enhanced with existing advanced optimal control methods and we explore this using the chopped randomised basis method and gradient ascent pulse engineering., Comment: 20 pages, 10 figures

Published

2022

10. Tunable Geometries in Sparse Clifford Circuits

Author

Hashizume, Tomohiro, Kuriyattil, Sridevi, Daley, Andrew J., and Bentsen, Gregory

Subjects

Quantum Physics, Condensed Matter - Quantum Gases

Abstract

We investigate the emergence of different effective geometries in stochastic Clifford circuits with sparse coupling. By changing the probability distribution for choosing two-site gates as a function of distance, we generate sparse interactions that either decay or grow with distance as a function of a single tunable parameter. Tuning this parameter reveals three distinct regimes of geometry for the spreading of correlations and growth of entanglement in the system. We observe linear geometry for short-range interactions, treelike geometry on a sparse coupling graph for long-range interactions, and an intermediate fast scrambling regime at the crossover point between the linear and treelike geometries. This transition in geometry is revealed in calculations of the subsystem entanglement entropy and tripartite mutual information. We also study emergent lightcones that govern these effective geometries by teleporting a single qubit of information from an input qubit to an output qubit. These tools help to analyze distinct geometries arising in dynamics and correlation spreading in quantum many-body systems., Comment: 19 pages, 11 figures

Published

2022

11. High-fidelity multiqubit Rydberg gates via two-photon adiabatic rapid passage

Author

Pelegrí, Gerard, Daley, Andrew J., and Pritchard, Jonathan D.

Subjects

Quantum Physics, Condensed Matter - Quantum Gases

Abstract

We present a robust protocol for implementing high-fidelity multiqubit controlled phase gates $(C^kZ)$ on neutral atom qubits coupled to highly excited Rydberg states. Our approach is based on extending adiabatic rapid passage to two-photon excitation via a short-lived intermediate excited state common to alkali-atom Rydberg experiments, accounting for the full impact of spontaneous decay and differential AC Stark shifts from the complete manifold of hyperfine excited states. We evaluate and optimize gate performance, concluding that for Cs and currently available laser frequencies and powers, a $CCZ$ gate with fidelity $\mathcal{F}>0.995$ for three qubits and $CCCZ$ with $\mathcal{F}>0.99$ for four qubits is attainable in $\sim 1.8$~$\mu$s via this protocol. Higher fidelities are accessible with future technologies, and our results highlight the ultility of neutral atom arrays for the native implementation of multiqubit unitaries., Comment: 6 pages, 5 figures + supplemental material (3 pages, 2 figures)

Published

2021

12. Non-Markovian Quantum Dynamics in Strongly Coupled Multimode Cavities Conditioned on Continuous Measurement

Author

Link, Valentin, Müller, Kai, Lena, Rosaria G., Luoma, Kimmo, Damanet, François, Strunz, Walter T., and Daley, Andrew J.

Subjects

Quantum Physics

Abstract

An important challenge in non-Markovian open quantum systems is to understand what information we gain from continuous measurement of an output field. For example, atoms in multimode cavity QED systems provide an exciting platform to study many-body phenomena in regimes where the atoms are strongly coupled amongst themselves and with the cavity, but the strong coupling makes it complicated to infer the conditioned state of the atoms from the output light. In this work we address this problem, describing the reduced atomic state via a conditioned hierarchy of equations of motion, which provides an exact conditioned reduced description under monitoring (and continuous feedback). We utilise this formalism to study how different monitoring for modes of a multimode cavity affects our information gain for an atomic state, and to improve spin squeezing via measurement and feedback in a strong coupling regime. This work opens opportunities to understand continuous monitoring of non-Markovian open quantum systems, both on a practical and fundamental level.

Published

2021

13. Measurement-induced phase transitions in sparse nonlocal scramblers

Author

Hashizume, Tomohiro, Bentsen, Gregory, and Daley, Andrew J.

Subjects

Quantum Physics, Condensed Matter - Quantum Gases

Abstract

Measurement-induced phase transitions arise due to a competition between the scrambling of quantum information in a many-body system and local measurements. In this work we investigate these transitions in different classes of fast scramblers, systems that scramble quantum information as quickly as is conjectured to be possible -- on a timescale proportional to the logarithm of the system size. In particular, we consider sets of deterministic sparse couplings that naturally interpolate between local circuits that slowly scramble information and highly nonlocal circuits that achieve the fast-scrambling limit. We find that circuits featuring sparse nonlocal interactions are able to withstand substantially higher rates of local measurement than circuits with only local interactions, even at comparable gate depths. We also study the quantum error-correcting codes that support the volume-law entangled phase and find that our maximally nonlocal circuits yield codes with nearly extensive contiguous code distance. Use of these sparse, deterministic circuits opens pathways towards the design of noise-resilient quantum circuits and error correcting codes in current and future quantum devices with minimum gate numbers., Comment: 11 pages, 6 figures (plus 11 page supplement with 11 figures)

Published

2021

14. Many-body quantum state diffusion for non-Markovian dynamics in strongly interacting systems

Author

Flannigan, Stuart, Damanet, François, and Daley, Andrew J.

Subjects

Quantum Physics

Abstract

Capturing non-Markovian dynamics of open quantum systems is generally a challenging problem, especially for strongly-interacting many-body systems. In this work, we combine recently developed non-Markovian quantum state diffusion techniques with tensor network methods to address this challenge. As a first example, we explore a Hubbard-Holstein model with dissipative phonon modes, where this new approach allows us to quantitatively assess how correlations spread in the presence of non-Markovian dissipation in a 1D many-body system. We find regimes where correlation growth can be enhanced by these effects, offering new routes for dissipatively enhancing transport and correlation spreading, relevant for both solid state and cold atom experiments., Comment: 9 pages, 5 figures

Published

2021

15. Density-Matrix Renormalization Group for Continuous Quantum Systems

Author

Dutta, Shovan, Buyskikh, Anton, Daley, Andrew J., and Mueller, Erich J.

Subjects

Condensed Matter - Quantum Gases, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons, Physics - Computational Physics

Abstract

We introduce a versatile and practical framework for applying matrix product state techniques to continuous quantum systems. We divide space into multiple segments and generate continuous basis functions for the many-body state in each segment. By combining this mapping with existing numerical Density-Matrix Renormalization Group routines, we show how one can accurately obtain the ground-state wave function, spatial correlations, and spatial entanglement entropy directly in the continuum. For a prototypical mesoscopic system of strongly-interacting bosons we demonstrate faster convergence than standard grid-based discretization. We illustrate the power of our approach by studying a superfluid-insulator transition in an external potential. We outline how one can directly apply or generalize this technique to a wide variety of experimentally relevant problems across condensed matter physics and quantum field theory., Comment: Main paper: 7 pages, 5 figures; Supplement: 13 pages, 5 figures

Published

2021

16. Can multipartite entanglement be characterized by two-point connected correlation functions ?

Author

Lepori, Luca, Trombettoni, Andrea, Giuliano, Domenico, Kombe, Johannes, Malo, Jorge Yago, Daley, Andrew J., Smerzi, Augusto, and Chiofalo, Maria Luisa

Subjects

Quantum Physics, Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory, Mathematical Physics

Abstract

We discuss under which conditions multipartite entanglement in mixed quantum states can be characterized only in terms of two-point connected correlation functions, as it is the case for pure states. In turn, the latter correlations are defined via a suitable combination of (disconnected) one- and two-point correlation functions. In contrast to the case of pure states, conditions to be satisfied turn out to be rather severe. However, we were able to identify some interesting cases, as when the point-independence is valid of the one-point correlations in each possible decomposition of the density matrix, or when the operators that enter in the correlations are (semi-)positive/negative defined.

Published

2021

17. Deterministic Fast Scrambling with Neutral Atom Arrays

Author

Hashizume, Tomohiro, Bentsen, Gregory, Weber, Sebastian, and Daley, Andrew J.

Subjects

Quantum Physics, Condensed Matter - Quantum Gases

Abstract

Fast scramblers are dynamical quantum systems that produce many-body entanglement on a timescale that grows logarithmically with the system size $N$. We propose and investigate a family of deterministic, fast scrambling quantum circuits realizable in near-term experiments with arrays of neutral atoms. We show that three experimental tools -- nearest-neighbour Rydberg interactions, global single-qubit rotations, and shuffling operations facilitated by an auxiliary tweezer array -- are sufficient to generate nonlocal interaction graphs capable of scrambling quantum information using only $O(\log N)$ parallel applications of nearest-neighbor gates. These tools enable direct experimental access to fast scrambling dynamics in a highly controlled and programmable way, and can be harnessed to produce highly entangled states with varied applications., Comment: 7 pages with 4 figures (plus 7-page supplement with 4 figures); updated to match published version

Published

2021

18. Hubbard models and state preparation in an optical Lieb lattice

Author

Flannigan, Stuart, Madail, Luisa, Dias, Ricardo G., and Daley, Andrew J.

Subjects

Condensed Matter - Quantum Gases, Quantum Physics

Abstract

Inspired by the growing interest in probing many-body phases in novel two-dimensional lattice geometries we investigate the properties of cold atoms as they could be observed in an optical Lieb lattice. We begin by computing Wannier functions localised at individual sites for a realistic experimental setup, and determining coefficients for a Hubbard-like model. Based on this, we show how experiments could probe the robustness of edge states in a Lieb lattice with diagonal boundary conditions to the effects of interactions and realise strongly correlated many-body phases in this geometry. We then generalise this to interacting particles in a half-filled 1D Lieb ladder, where excitations are dominated by flat band states. We show that for strong attractive interactions, pair correlations are enhanced even when there is strong mixing with the Dirac cone. These findings in 1D raise interesting questions about the phases in the full 2D Lieb lattice which we show can be explored in current experiments., Comment: 10 pages, 8 figures

Published

2021

19. Spin-orbit-assisted electron pairing in 1D waveguides

Author

Damanet, François, Mansfield, Elliott, Briggeman, Megan, Irvin, Patrick, Levy, Jeremy, and Daley, Andrew J.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

Understanding and controlling the transport properties of interacting fermions is a key forefront in quantum physics across a variety of experimental platforms. Motivated by recent experiments in 1D electron channels written on the $\mathrm{LaAlO_3}$/$\mathrm{SrTiO_3}$ interface, we analyse how the presence of different forms of spin-orbit coupling (SOC) can enhance electron pairing in 1D waveguides. We first show how the intrinsic Rashba SOC felt by electrons at interfaces such as $\mathrm{LaAlO_3}$/$\mathrm{SrTiO_3}$ can be reduced when they are confined in 1D. Then, we discuss how SOC can be engineered, and show using a mean-field Hartree-Fock-Bogoliubov model that SOC can generate and enhance spin-singlet and triplet electron pairing. Our results are consistent with two recent sets of experiments [Briggeman et al., arXiv:1912.07164; Sci. Adv. 6, eaba6337 (2020)] that are believed to engineer the forms of SOC investigated in this work, which suggests that metal-oxide heterostructures constitute attractive platforms to control the collective spin of electron bound states. However, our findings could also be applied to other experimental platforms involving spinful fermions with attractive interactions, such as cold atoms., Comment: 12 pages, 7 figures

Published

2020

20. Enhanced repulsively bound atom pairs in topological optical lattice ladders

Author

Flannigan, Stuart and Daley, Andrew J.

Subjects

Condensed Matter - Quantum Gases, Quantum Physics

Abstract

There is a growing interest in using cold-atom systems to explore the effects of strong interactions in topological band structures. Here we investigate interacting bosons in a Cruetz ladder, which is characterised by topological flat energy bands where it has been proposed that interactions can lead to the formation of bound atomic pairs giving rise to pair superfluidity. By investigating realistic experimental implementations, we understand how the lattice topology enhances the properties of bound pairs giving rise to relatively large effective pair-tunnelling in these systems which can lead to robust pair superfluidity, and we find lattice supersolid phases involving only pairs. We identify schemes for preparation of these phases via time-dependent parameter variation and look at ways to detect and characterise these systems in a lattice. This work provides a starting point for investigating the interplay between the effects of topology, interactions and pairing in more general systems, with potential future connections to quantum simulation of topological materials., Comment: 15 pages, 9 figures

Published

2020

21. Adiabatic preparation of entangled, magnetically ordered states with cold bosons in optical lattices

Author

Venegas-Gomez, Araceli, Schachenmayer, Johannes, Buyskikh, Anton S., Ketterle, Wolfgang, Chiofalo, Maria Luisa, and Daley, Andrew J.

Subjects

Condensed Matter - Quantum Gases, Quantum Physics

Abstract

We analyze a scheme for preparation of magnetically ordered states of two-component bosonic atoms in optical lattices. We compute the dynamics during adiabatic and optimized time-dependent ramps to produce ground states of effective spin Hamiltonians, and determine the robustness to decoherence for realistic experimental system sizes and timescales. Ramping parameters near a phase transition point in both effective spin-1/2 and spin-1 models produces entangled spin-symmetric states that have potential future applications in quantum enhanced measurement. The preparation of these states and their robustness to decoherence is quantified by computing the Quantum Fisher Information of final states. We identify that the generation of useful entanglement should in general be more robust to heating than it would be implied by the state fidelity, with corresponding implications for practical applications.

Published

2020

22. Cervical lymphadenopathy in a child

Author

Daley, Andrew J.

Published

2000

23. Measurement of Identical Particle Entanglement and the Influence of Antisymmetrisation

Author

Becher, Jan Hendrik, Sindici, Enrico, Klemt, Ralf, Jochim, Selim, Daley, Andrew J., and Preiss, Philipp M.

Subjects

Condensed Matter - Quantum Gases

Abstract

We explore the relationship between symmetrisation and entanglement through measurements on few-particle systems in a multi-well potential. In particular, considering two or three trapped atoms, we measure and distinguish correlations arising from two different physical origins: antisymmetrisation of the fermionic wavefunction and interaction between particles. We quantify this through the entanglement negativity of states, and the introduction of an antisymmetric negativity, which allows us to understand the role that symmetrisation plays in the measured entanglement properties. We apply this concept both to pure theoretical states and to experimentally reconstructed density matrices of two or three mobile particles in an array of optical tweezers.

Published

2020

24. Twenty-five years of analogue quantum simulation

Author

Daley, Andrew J.

Published

2023

25. Dynamics of rotated spin states and magnetic ordering with two-component bosonic atoms in optical lattices

Author

Venegas-Gomez, Araceli, Buyskikh, Anton S., Schachenmayer, Johannes, Ketterle, Wolfgang, and Daley, Andrew J.

Subjects

Condensed Matter - Quantum Gases

Abstract

The microscopic control available over cold atoms in optical lattices has opened new opportunities to study the properties of quantum spin models. While a lot of attention is focussed on experimentally realizing ground or thermal states via adiabatic loading, it would often be more straightforward to prepare specific simple product states and to probe the properties of interacting spins by observing their dynamics. We explore this possibility for spin-1/2 and spin-1 models that can be realized with bosons in optical lattices, and which exhibit \textit{XY}-ferromagnetic (or counterflow spin superfluid) phases. We consider the dynamics of initial spin-rotated states corresponding to a mean-field version of the phases of interest. Using matrix product state methods in one dimension, we compute both non-equilibrium dynamics and ground/thermal states for these systems. We compare and contrast their behaviour in terms of correlation functions and induced spin currents, which should be directly observable with current experimental techniques. We find that although spin correlations decay substantially at large distances and on long timescales, for induction of spin currents, the rotated states behave similarly to the ground states on experimentally observable timescales.

Published

2019

26. One-dimensional Kronig-Penney superlattices at the LaAlO$_3$/SrTiO$_3$ interface

Author

Briggeman, Megan, Lee, Hyungwoo, Lee, Jung-Woo, Eom, Kitae, Damanet, François, Mansfield, Elliott, Li, Jianan, Huang, Mengchen, Daley, Andrew J., Eom, Chang-Beom, Irvin, Patrick, and Levy, Jeremy

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The paradigm of electrons interacting with a periodic lattice potential is central to solid-state physics. Semiconductor heterostructures and ultracold neutral atomic lattices capture many of the essential properties of 1D electronic systems. However, fully one-dimensional superlattices are highly challenging to fabricate in the solid state due to the inherently small length scales involved. Conductive atomic-force microscope (c-AFM) lithography has recently been demonstrated to create ballistic few-mode electron waveguides with highly quantized conductance and strongly attractive electron-electron interactions. Here we show that artificial Kronig-Penney-like superlattice potentials can be imposed on such waveguides, introducing a new superlattice spacing that can be made comparable to the mean separation between electrons. The imposed superlattice potential "fractures" the electronic subbands into a manifold of new subbands with magnetically-tunable fractional conductance (in units of $e^2/h$). The lowest $G=2e^2/h$ plateau, associated with ballistic transport of spin-singlet electron pairs, is stable against de-pairing up to the highest magnetic fields explored ($|B|=16$ T). A 1D model of the system suggests that an engineered spin-orbit interaction in the superlattice contributes to the enhanced pairing observed in the devices. These findings represent an important advance in the ability to design new families of quantum materials with emergent properties, and mark a milestone in the development of a solid-state 1D quantum simulation platform.

Published

2019

27. Collisionally inhomogeneous Bose-Einstein condensates with a linear interaction gradient

Author

Di Carli, Andrea, Henderson, Grant, Flannigan, Stuart, Colquhoun, Craig D., Mitchell, Matthew, Oppo, Gian-Luca, Daley, Andrew J., Kuhr, Stefan, and Haller, Elmar

Subjects

Condensed Matter - Quantum Gases, Quantum Physics

Abstract

We study the evolution of a collisionally inhomogeneous matter wave in a spatial gradient of the interaction strength. Starting with a Bose-Einstein condensate with weak repulsive interactions in quasi-one-dimensional geometry, we monitor the evolution of a matter wave that simultaneously extends into spatial regions with attractive and repulsive interactions. We observe the formation and the decay of soliton-like density peaks, counter-propagating self-interfering wave packets, and the creation of cascades of solitons. The matter-wave dynamics is well reproduced in numerical simulations based on the nonpolynomial Schroedinger equation with three-body loss, allowing us to better understand the underlying behaviour based on a wavelet transformation. Our analysis provides new understanding of collapse processes for solitons, and opens interesting connections to other nonlinear instabilities.

Published

2019

28. Reservoir engineering of Cooper-pair-assisted transport with cold atoms

Author

Damanet, François, Mascarenhas, Eduardo, Pekker, David, and Daley, Andrew J.

Subjects

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

Abstract

We show how Cooper-pair-assisted transport, which describes the stimulated transport of electrons in the presence of Cooper-pairs, can be engineered and controlled with cold atoms, in regimes that are difficult to access for condensed matter systems. Our model is a channel connecting two cold atomic gases, and the mechanism to generate such a transport relies on the coupling of the channel to a molecular BEC, with diatomic molecules of fermionic atoms. Our results are obtained using a Floquet-Redfield master equation that accounts for an exact treatment of the interaction between atoms in the channel. We explore, in particular, the impact of the coupling to the BEC and the interaction between atoms in the junction on its transport properties, revealing non-trivial dependence of the produced particle current. We also study the effects of finite temperatures of the reservoirs and the robustness of the current against additional dissipation acting on the junction. Our work is experimentally relevant and has potential applications to dissipation engineering of transport with cold atoms, studies of thermoelectric effects, quantum heat engines, or Floquet Majorana fermions., Comment: 13 pages and 4 figures (main) + 10 pages (appendices). Close to the published version

Published

2019

29. Treelike interactions and fast scrambling with cold atoms

Author

Bentsen, Gregory, Hashizume, Tomohiro, Buyskikh, Anton S., Davis, Emily J., Daley, Andrew J., Gubser, Steven S., and Schleier-Smith, Monika

Subjects

Quantum Physics, High Energy Physics - Theory

Abstract

We propose an experimentally realizable quantum spin model that exhibits fast scrambling, based on non-local interactions which couple sites whose separation is a power of 2. By controlling the relative strengths of deterministic, non-random couplings, we can continuously tune from the linear geometry of a nearest-neighbor spin chain to an ultrametric geometry in which the effective distance between spins is governed by their positions on a tree graph. The transition in geometry can be observed in quench dynamics, and is furthermore manifest in calculations of the entanglement entropy. Between the linear and treelike regimes, we find a peak in entanglement and exponentially fast spreading of quantum information across the system. Our proposed implementation, harnessing photon-mediated interactions among cold atoms in an optical cavity, offers a test case for experimentally observing the emergent geometry of a quantum many-body system., Comment: 6 pages, 4 figures (plus 7-page supplement with 4 figures)

Published

2019

30. Excitation modes of bright matter-wave solitons

Author

Di Carli, Andrea, Colquhoun, Craig D., Henderson, Grant, Flannigan, Stuart, Oppo, Gian-Luca, Daley, Andrew J., Kuhr, Stefan, and Haller, Elmar

Subjects

Condensed Matter - Quantum Gases

Abstract

We experimentally study the excitation modes of bright matter-wave solitons in a quasi-one-dimensional geometry. The solitons are created by quenching the interactions of a Bose-Einstein condensate of cesium atoms from repulsive to attractive in combination with a rapid reduction of the longitudinal confinement. A deliberate mismatch of quench parameters allows for the excitation of breathing modes of the emerging soliton and for the determination of its breathing frequency as a function of atom number and confinement. In addition, we observe signatures of higher-order solitons and the splitting of the wave packet after the quench. Our experimental results are compared to analytical predictions and to numerical simulations of the one-dimensional Gross-Pitaevskii equation.

Published

2019

31. Controlling Quantum Transport via Dissipation Engineering

Author

Damanet, François, Mascarenhas, Eduardo, Pekker, David, and Daley, Andrew J.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Inspired by the microscopic control over dissipative processes in quantum optics and cold atoms, we develop an open-system framework to study dissipative control of transport in strongly interacting fermionic systems, relevant for both solid state and cold atom experiments. We show how subgap currents exhibiting Multiple Andreev Reflections -- the stimulated transport of electrons in the presence of Cooper-pairs -- can be controlled via engineering of superconducting leads or superfluid atomic gases. Our approach incorporates dissipation within the channel, which is naturally occurring and can be engineered in cold gas experiments. This opens opportunities for engineering many phenomena with transport in strongly interacting systems. As examples, we consider particle loss and dephasing, and note different behaviour for currents with different microscopic origin. We also show how to induce nonreciprocal electron and Cooper-pair currents., Comment: Main text (5 pages, 4 figures) + Supplemental material (12 pages, 1 figure). Close to the published version

Published

2019

32. A simplified, amplicon-based method for whole genome sequencing of human respiratory syncytial viruses

Author

Dong, Xiaomin, Deng, Yi-Mo, Aziz, Ammar, Whitney, Paul, Clark, Julia, Harris, Patrick, Bautista, Catherine, Costa, Anna-Maria, Waller, Gregory, Daley, Andrew J, Wieringa, Megan, Korman, Tony, and Barr, Ian G.

Published

2023

33. Atom-only descriptions of the driven-dissipative Dicke model

Author

Damanet, François, Daley, Andrew J., and Keeling, Jonathan

Subjects

Quantum Physics

Abstract

We investigate how to describe the dissipative spin dynamics of the driven-dissipative Dicke model, describing $N$ two-level atoms coupled to a cavity mode, after adiabatic elimination of the cavity mode. To this end, we derive a Redfield master equation which goes beyond the standard secular approximation and large detuning limits. We show that the secular (or rotating wave) approximation and the large detuning approximation both lead to inadequate master equations, that fail to predict the Dicke transition or the damping rates of the atomic dynamics. In contrast, the full Redfield theory correctly predicts the phase transition and the effective atomic damping rates. Our work provides a reliable framework to study the full quantum dynamics of atoms in a multimode cavity, where a quantum description of the full model becomes intractable., Comment: 11 pages, 2 figures

Published

2019

34. Entanglement Dynamics in Spin Chains with Structured Long-Range Interactions

Author

Bentsen, Gregory S., Daley, Andrew J., Schachenmayer, Johannes, Laflamme, Raymond, Series Editor, Lidar, Daniel, Series Editor, Rauschenbeutel, Arno, Series Editor, Renner, Renato, Series Editor, Wang, Jingbo, Series Editor, Weinstein, Yaakov S., Series Editor, Wiseman, H. M., Series Editor, Schlosshauer, Maximilian, Section Editor, Bayat, Abolfazl, editor, Bose, Sougato, editor, and Johannesson, Henrik, editor

Published

2022

35. Resonant two-site tunnelling dynamics of bosons in a tilted optical superlattice

Author

Buyskikh, Anton S., Tagliacozzo, Luca, Schuricht, Dirk, Hooley, Chris A., Pekker, David, and Daley, Andrew J.

Subjects

Condensed Matter - Quantum Gases

Abstract

We study the non-equilibrium dynamics of a 1D Bose-Hubbard model in a gradient potential and a superlattice, beginning from a deep Mott insulator regime with an average filling of one particle per site. Studying a quench that is near resonance to tunnelling of the particles over two lattice sites, we show how a spin model emerges consisting of two coupled Ising chains that are coupled by interaction terms in a staggered geometry. We compare and contrast the behavior in this case with that in a previously studied case where the resonant tunnelling was over a single site. Using optimized tensor network techniques to calculate finite temperature behavior of the model, as well as finite size scaling for the ground state, we conclude that the universality class of the phase transition for the coupled chains is that of a tricritical Ising point. We also investigate the out-of-equilibrium dynamics after the quench in the vicinity of the resonance and compare dynamics with recent experiments realized without the superlattice geometry. This model is directly realizable in current experiments, and reflects a new general way to realize spin models with ultracold atoms in optical lattices., Comment: 13 pages, 6 figures

Published

2018

36. Spin-models, dynamics and criticality with atoms in tilted optical superlattices

Author

Buyskikh, Anton S., Tagliacozzo, Luca, Schuricht, Dirk, Hooley, Chris A., Pekker, David, and Daley, Andrew J.

Subjects

Condensed Matter - Quantum Gases

Abstract

We show that atoms in tilted optical superlattices provide a platform for exploring coupled spin chains of forms that are not present in other systems. In particular, using a period-2 superlattice in 1D, we show that coupled Ising spin chains with XZ and ZZ spin coupling terms can be engineered. We use optimized tensor network techniques to explore the criticality and non-equilibrium dynamics in these models, finding a tricritical Ising point in regimes that are accessible in current experiments. These setups are ideal for studying low-entropy physics, as initial entropy is "frozen-out" in realizing the spin models, and provide an example of the complex critical behaviour that can arise from interaction-projected models., Comment: 6 pages, 4 figures

Published

2018

37. Nonreciprocal Quantum Transport at Junctions of Structured Leads

Author

Mascarenhas, Eduardo, Damanet, François, Flannigan, Stuart, Tagliacozzo, Luca, Daley, Andrew J., Goold, John, and de Vega, Inés

Subjects

Quantum Physics

Abstract

We propose and analyze a mechanism for rectification of spin transport through a small junction between two spin baths or leads. For interacting baths we show that transport is conditioned on the spacial asymmetry of the quantum junction mediating the transport, and attribute this behavior to a gapped spectral structure of the lead-system-lead configuration. For non-interacting leads a minimal quantum model that allows for spin rectification requires an interface of only two interacting two-level systems. We obtain approximate results with a weak-coupling Born-master-equation in excellent agreement with matrix-product-state calculations that are extrapolated in time by mimicking absorbing boundary conditions. These results should be observable in controlled spin systems realized with cold atoms, trapped ions, or in electrons in quantum dot arrays.

Published

2018

38. Interspecies entanglement with impurity atoms in a lattice gas

Author

Sarkar, Saubhik, McEndoo, Suzanne, Schneble, Dominik, and Daley, Andrew J.

Subjects

Condensed Matter - Quantum Gases, Quantum Physics

Abstract

The dynamics of impurity atoms introduced into bosonic gases in an optical lattice have generated a lot of recent interest, both in theory and experiment. We investigate to what extent measurements on either the impurity species or the majority species in these systems are affected by their interspecies entanglement. This arises naturally in the dynamics and plays an important role when we measure only one species. We explore the corresponding effects in strongly interacting regimes, using a combination of few-particle analytical calculations and Density Matrix Renormalisation group methods in one dimension. We identify how the resulting effects on impurities can be used to probe the many-body states of the majority species, and separately ask how to enter regimes where this entanglement is small, so that the impurities can be used as probes that do not significantly affect the majority species. The results are accessible in current experiments, and provide important considerations for the measurement of complex systems with using few probe atoms., Comment: 22 pages, 8 figures

Published

2018

39. Inborn Errors of Immunity in Children With Invasive Pneumococcal Disease: A Multicenter Prospective Study

Author

Phuong, Linny Kimly, Cheung, Abigail, Agrawal, Rishi, Butters, Coen, Buttery, Jim, Clark, Julia, Connell, Tom, Curtis, Nigel, Daley, Andrew J., Dobinson, Hazel C., Frith, Catherine, Hameed, Nadha Shahul, Hernstadt, Hayley, Krieser, David M., Loke, Paxton, Ojaimi, Samar, McMullan, Brendan, Pinzon-Charry, Alberto, Sharp, Ella Grace, Sinnappurajar, Praisoody, Templeton, Tiarni, Wen, Sophie, Cole, Theresa, and Gwee, Amanda

Published

2023

40. Practical quantum advantage in quantum simulation

Author

Daley, Andrew J., Bloch, Immanuel, Kokail, Christian, Flannigan, Stuart, Pearson, Natalie, Troyer, Matthias, and Zoller, Peter

Published

2022

41. Influenza A(H5N1) Virus Clade 2.3.2.1a in Traveler Returning to Australia from India, 2024.

Author

Yi-Mo Deng, Wille, Michelle, Dapat, Clyde, Ruopeng Xie, Lay, Olivia, Peck, Heidi, Daley, Andrew J., Dhanasakeran, Vijaykrishna, and Barr, Ian G.

Subjects

AVIAN influenza, INFLUENZA, TRAVELERS, GENES

Abstract

We report highly pathogenic avian influenza A(H5N1) virus clade 2.3.2.1a in a child traveler returning to Australia from India. The virus was a previously unreported reassortant consisting of clade 2.3.2.1a, 2.3.4.4b, and wild bird low pathogenicity avian influenza gene segments. These findings highlight surveillance gaps in South Asia. [ABSTRACT FROM AUTHOR]

Published

2025

42. Particle statistics and lossy dynamics of ultracold atoms in optical lattices

Author

Malo, Jorge Yago, van Nieuwenburg, Evert P. L., Fischer, Mark H., and Daley, Andrew J.

Subjects

Quantum Physics

Abstract

Experimental control over ultracold quantum gases has made it possible to investigate low-dimensional systems of both bosonic and fermionic atoms. In closed 1D systems there are a lot of similarities in the dynamics of local quantities for spinless fermions and strongly interacting "hard-core" bosons, which on a lattice can be formalised via a Jordan-Wigner transformation. In this study, we analyse the similarities and differences for spinless fermions and hard-core bosons on a lattice in the presence of particle loss. The removal of a single fermion causes differences in local quantities compared with the bosonic case, because of the different particle exchange symmetry in the two cases. We identify deterministic and probabilistic signatures of these dynamics in terms of local particle density, which could be measured in ongoing experiments with quantum gas microscopes., Comment: 7 pages, 6 figures

Published

2017

43. Dynamics of many-body localization in the presence of particle loss

Author

van Nieuwenburg, Evert P. L., Malo, Jorge Yago, Daley, Andrew J., and Fischer, Mark H.

Subjects

Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Quantum Gases, Condensed Matter - Statistical Mechanics, Condensed Matter - Strongly Correlated Electrons

Abstract

At long times residual couplings to the environment become relevant even in the most isolated experiments, creating a crucial difficulty for the study of fundamental aspects of many-body dynamics. A particular example is many-body localization in a cold-atom setting, where incoherent photon scattering introduces both dephasing and particle loss. Whereas dephasing has been studied in detail and is known to destroy localization already on the level of non-interacting particles, the effect of particle loss is less well understood. A difficulty arises due to the `non-local' nature of the loss process, complicating standard numerical tools using matrix product decomposition. Utilizing symmetries of the Lindbladian dynamics, we investigate the particle loss on both the dynamics of observables, as well as the structure of the density matrix and the individual states. We find that particle loss in the presence of interactions leads to dissipation and a strong suppression of the (operator space) entanglement entropy. Our approach allows for the study of the interplay of dephasing and loss for pure and mixed initial states to long times, which is important for future experiments using controlled coupling of the environment., Comment: 10 pages, 5 figures

Published

2017

44. Clinical and Health System Impact of Biofire Filmarray Meningitis/Encephalitis Routine Testing of CSF in a Pediatric Hospital: An Observational Study

Author

Berkhout, Angela, Cheng, Daryl R., McNab, Sarah, Lee, Lai-yang, Daley, Andrew J., and Clifford, Vanessa

Published

2022

45. Risk factors for healthcare-associated infection among children in a low-and middle-income country

Author

Murni, Indah K., Duke, Trevor, Kinney, Sharon, Daley, Andrew J., Wirawan, Muhammad Taufik, and Soenarto, Yati

Published

2022

46. Andreev Molecules in Semiconductor Nanowire Double Quantum Dots

Author

Su, Zhaoen, Tacla, Alexandre B., Hocevar, Moïra, Car, Diana, Plissard, Sébastien R., Bakkers, Erik P. A. M., Daley, Andrew J., Pekker, David, and Frolov, Sergey M.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity

Abstract

Quantum simulation is a way to study unexplored Hamiltonians by mapping them onto the assemblies of well-understood quantum systems such as ultracold atoms in optical lattices, trapped ions or superconducting circuits. Semiconductor nanostructures which form the backbone of classical computing hold largely untapped potential for quantum simulation. In particular, chains of quantum dots in semiconductor nanowires can be used to emulate one-dimensional Hamiltonians such as the toy model of a topological p-wave superconductor. Here we realize a building block of this model, a double quantum dot with superconducting contacts, in an indium antimonide nanowire. In each dot, tunnel-coupling to a superconductor induces Andreev bound states. We demonstrate that these states hybridize to form the double-dot Andreev molecular states. We establish the parity and the spin structure of Andreev molecular levels by monitoring their evolution in electrostatic potential and magnetic field. Understanding Andreev molecules is a key step towards building longer chains which are predicted to generate Majorana bound states at the end sites. Two superconducting quantum dots are already sufficient to test the fusion rules of Majorana bound states, a milestone towards fault-tolerant topological quantum computing., Comment: 15 pages and 4 figures in the main text, 28 pages and 18 figures in the supplementary information. Raw data can be downloaded at http://data.4tu.nl/repository/uuid:e99d1ab7-2e82-447e-a314-f230a0da4a95

Published

2016

47. Signatures of Many-Body Localization in a Controlled Open Quantum System

Author

Lüschen, Henrik P., Bordia, Pranjal, Hodgman, Sean S., Schreiber, Michael, Sarkar, Saubhik, Daley, Andrew J., Fischer, Mark H., Altman, Ehud, Bloch, Immanuel, and Schneider, Ulrich

Subjects

Condensed Matter - Quantum Gases, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics, Condensed Matter - Strongly Correlated Electrons, Quantum Physics

Abstract

In the presence of disorder, an interacting closed quantum system can undergo many-body localization (MBL) and fail to thermalize. However, over long times even weak couplings to any thermal environment will necessarily thermalize the system and erase all signatures of MBL. This presents a challenge for experimental investigations of MBL, since no realistic system can ever be fully closed. In this work, we experimentally explore the thermalization dynamics of a localized system in the presence of controlled dissipation. Specifically, we find that photon scattering results in a stretched exponential decay of an initial density pattern with a rate that depends linearly on the scattering rate. We find that the resulting susceptibility increases significantly close to the phase transition point. In this regime, which is inaccessible to current numerical studies, we also find a strong dependence on interactions. Our work provides a basis for systematic studies of MBL in open systems and opens a route towards extrapolation of closed system properties from experiments., Comment: 5+7 pages, 9 figures

Published

2016

48. Clinical and Health System Impact of Biofire Filmarray Meningitis/Encephalitis Routine Testing of CSF in a Pediatric Hospital: An Observational Study

Author

Berkhout, Angela, Cheng, Daryl R., McNab, Sarah, Lee, Lai-yang, Daley, Andrew J., and Clifford, Vanessa

Published

2023

49. Rapid detection of human respiratory syncytial virus A and B by duplex real-time RT-PCR

Author

Todd, Angela K., Costa, Anna-Maria, Waller, Gregory, Daley, Andrew J., Barr, Ian G., and Deng, Yi-Mo

Published

2021

50. Floquet engineering of correlated tunneling in the Bose-Hubbard model with ultracold atoms

Author

Meinert, Florian, Mark, Manfred J., Lauber, Katharina, Daley, Andrew J., and Nägerl, Hanns-Christoph

Subjects

Condensed Matter - Quantum Gases

Abstract

We report on the experimental implementation of tunable occupation-dependent tunneling in a Bose-Hubbard system of ultracold atoms via time-periodic modulation of the on-site interaction energy. The tunneling rate is inferred from a time-resolved measurement of the lattice site occupation after a quantum quench. We demonstrate coherent control of the tunneling dynamics in the correlated many-body system, including full suppression of tunneling as predicted within the framework of Floquet theory. We find that the tunneling rate explicitly depends on the atom number difference in neighboring lattice sites. Our results may open up ways to realize artificial gauge fields that feature density dependence with ultracold atoms., Comment: 8 pages, 9 figures

Published

2016