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Article
Physics, Mathematical
Benjamin Doyon
Summary: Establishing the hydrodynamic equations in large, isolated, strongly interacting many-body systems is a profound question in mathematical physics. In this study, we focus on one-dimensional systems and make progress in understanding the relaxation process, determining the emergent collective degrees of freedom, showing the occurrence of hydrodynamic projection, and establishing the hydrodynamic equations. We rigorously establish these results within a general framework based on Hilbert spaces of observables, and show that the results hold in certain Gibbs states of quantum spin chains and can be generalized to higher dimensions.
COMMUNICATIONS IN MATHEMATICAL PHYSICS
(2022)
Article
Engineering, Electrical & Electronic
Constantinos Valagiannopoulos
Summary: Multistability is a key effect in memory components of various electronic, chemical, biological, and quantum systems, enabling different outputs based on past input values. We discovered that two electromagnetic metasurfaces with nonlinear Kerr-type admittances exhibit significant multistability in transmissivity. This feature arises from the discontinuous response caused by the change in material nature from dielectric to plasmonic and vice versa at different levels of input power.
IEEE TRANSACTIONS ON ANTENNAS AND PROPAGATION
(2022)
Article
Physics, Multidisciplinary
A. McDonald et al.
Summary: In this paper, we demonstrate how the presence of continuous weak symmetry can be used to analytically diagonalize the Liouvillian of a class of Markovian dissipative systems with strong interactions or nonlinearity. This method enables an exact description of the full dynamics and dissipative spectrum, providing a powerful new tool for the study of complex driven-dissipative quantum systems.
PHYSICAL REVIEW LETTERS
(2022)
Article
Multidisciplinary Sciences
Hossein Taheri et al.
Summary: This study demonstrates a dissipative discrete time crystal in a Kerr-nonlinear optical microcavity. By utilizing self-injection locking of two independent lasers, this system enables the realization of defect-carrying DTCs and phase transitions. This room-temperature system paves the way for chip-scale time crystals with practical applications.
NATURE COMMUNICATIONS
(2022)
Article
Physics, Multidisciplinary
Maurizio Fagotti
Summary: We investigate the effect of a single spin flip preceding a global quench between translationally invariant local Hamiltonians in spin-1/2 chains. The effect of the localized perturbation does not fade away however large the distance from the perturbation is. In particular, translational invariance is not restored and the infinite-time limit depends on whether the spin was flipped or not. We argue that this phenomenon is more general than the particular example considered and we conjecture that it is triggered by topological properties, specifically, the existence of semilocal charges.
PHYSICAL REVIEW LETTERS
(2022)
Article
Physics, Multidisciplinary
Michal Hajdusek et al.
Summary: This study introduces the concept of seeding of crystallization in time by studying the dynamics of an ensemble of coupled continuous time crystals. It demonstrates that a single subsystem in a broken-symmetry phase can induce time-translation symmetry breaking across the entire ensemble. The seeding effect is observed for both coherent and dissipative coupling, as well as for a broad range of parameter regimes.
PHYSICAL REVIEW LETTERS
(2022)
Article
Physics, Multidisciplinary
Berislav Buca
Summary: This study examines the possibility of spontaneous perpetual reversal of the arrow of time and investigates the existence of perpetual out-of-time-ordered correlator (OTOC) oscillations in many-body systems. The researchers provide a rigorous lower bound for the amplitude of OTOC oscillations and identify systems that exhibit out-of-time-ordered (OTO) crystals through a strictly local dynamical algebra. Additionally, the study demonstrates that a Hamiltonian satisfying this algebra possesses a large number of local invariant subspaces and remains stable under local unitary and dissipative perturbations. The Creutz ladder is shown to be an OTO crystal capable of perpetually reversing the arrow of time.
PHYSICAL REVIEW LETTERS
(2022)
Review
Physics, Multidisciplinary
Sanjay Moudgalya et al.
Summary: This review provides a pedagogical introduction to and an overview of the exact results on weak ergodicity breaking via quantum many-body scars (QMBS) in isolated quantum systems. Various mechanisms and unifying formalisms for systems exhibiting QMBS are discussed, along with the connections to Hilbert space fragmentation.
REPORTS ON PROGRESS IN PHYSICS
(2022)
Article
Physics, Multidisciplinary
Berislav Buca et al.
Summary: The study presents a general theory based on novel algebraic criteria for analyzing synchronization phenomena in quantum systems. The theory provides exact analytical solutions for persistently oscillating eigenmodes and can be used to characterize both stable and metastable synchronization. The research demonstrates synchronization in various fermionic cold atom experiments and offers compact criteria for proving the absence of synchronization.
Article
Physics, Multidisciplinary
Jamir Marino
Summary: We demonstrate that spatial resolved dissipation can alter the critical points of d-dimensional spin systems in the Ising universality class. By considering power-law decaying spin losses, we reveal the existence of soft modes decoupled from dissipation at small momenta, leading to a nonunitary counterpart of long-range interacting Ising models. A nonequilibrium critical point is found for alpha < 1, characterized by a dynamical field theory described by a Langevin model with coexisting inertial and frictional kinetic coefficients, driven by gapless Markovian noise.
PHYSICAL REVIEW LETTERS
(2022)
Article
Multidisciplinary Sciences
Phatthamon Kongkhambut et al.
Summary: In this study, we observed a limit cycle phase in a continuously pumped atom-cavity system, characterized by emergent oscillations in the photon number. This dynamical state spontaneously breaks continuous time translation symmetry and is robust against temporal perturbations, demonstrating the realization of a continuous time crystal.
Article
Physics, Multidisciplinary
Subhajit Sarkar et al.
Summary: The authors demonstrate the survival of discrete time-crystals and quasi-crystals in a general class of environments and propose a method to observe discrete time-crystals by measuring transport properties in quantum dot arrays.
COMMUNICATIONS PHYSICS
(2022)
Article
Physics, Multidisciplinary
Max McGinley et al.
Summary: We propose a model of nonunitary quantum dynamics that exhibits infinitely long-lived discrete spatiotemporal order robust against any unitary or dissipative perturbation. By combining a sequence of projective measurements with a local feedback rule, ergodicity is evaded. The results are verified through numerical simulations and explicit experimental protocols.
PHYSICAL REVIEW LETTERS
(2022)
Article
Physics, Multidisciplinary
Pablo Sala et al.
Summary: This study extends the concepts of multipole and subsystem symmetries to more general spatially modulated symmetries and provides simple microscopic models in different dimensions. Numerical investigations reveal that periodically modulated symmetries result in diffusive scaling of correlations modulated by finite microscopic momentum in one dimension, while exponential modulation leads to correlations that are infinitely long-lived at the boundary and decay exponentially in the bulk.
PHYSICAL REVIEW LETTERS
(2022)
Article
Materials Science, Multidisciplinary
Thivan M. Gunawardana et al.
Summary: This study rigorously demonstrates and explains the existence of certain algebraic structures that are exponentially stable in time, which leads to the understanding of various phenomena observed in Stark many-body localized (SMBL) systems, such as Bloch many-body oscillations, quantum many-body scars, and fragmentation. Numerical results confirm the theoretical findings. Additionally, the study provides an explanation for the thermalization observed in recent two-dimensional tilted experiments and suggests the potential for quantum information processing in Stark MBL systems even at high temperature.
Article
Optics
M. R. Lambert et al.
Summary: We study the resonant coupling of a fully connected quantum spin model with a small environment of noninteracting spins and investigate the memory of initial state properties at long times. We find that certain properties of the initial state, in addition to total energy, can be remembered during the dynamics, even if they are not conserved. This memory effect occurs in a specific energy range, where an eigenstate quantum phase transition (ESQPT) takes place. The memory effect at that energy is robust to system-environment coupling until the coupling changes the energy of the ESQPT. This work reveals the independence of ESQPT memory on integrability and suggests that this mechanism may have a wider generality in preventing thermalization at ESQPTs.
Article
Optics
Kilian Seibold et al.
Summary: In this study, we develop a quantum-mechanical model of dissipative Kerr solitons in ring microresonators and investigate the model using the truncated Wigner method. We find that the soliton experiences a finite coherence time due to quantum fluctuations originating from losses. Interpreting the results in terms of the theory of open quantum systems allows us to estimate the Liouvillian spectrum of the system, which is characterized by a set of eigenvalues with finite imaginary parts and vanishing real parts in the limit of vanishing quantum fluctuations. This feature indicates that dissipative Kerr solitons are a specific class of dissipative time crystals.
Article
Physics, Multidisciplinary
Dong Yuan et al.
Summary: This study investigates the dynamics of quantum information scrambling in quantum many-body scarred systems, focusing on the PXP model. It is found that the out-of-time-ordered correlator (OTOC) and Holevo information exhibit linear light cone and periodic oscillations within the light cone for initial states within the scarred subspace. The results signify an unusual breakdown of quantum chaos.
PHYSICAL REVIEW RESEARCH
(2022)
Article
Materials Science, Multidisciplinary
Antonio C. Lourenco et al.
Summary: In this paper, we study the genuine multipartite correlations (GMC's) in a boundary time crystal (BTC). We find that, in the thermodynamic limit, the orders of the correlations grow indefinitely in time and exhibit a power-law decaying hierarchy among its partitions. Additionally, these correlations scale extensively with the system size in the long-time limit, contrasting with the subextensive scaling in the non time crystals phase. We discuss the classical and quantum nature of these correlations using multipartite entanglement witnesses, specifically the analysis of the quantum Fisher information (QFI).
Article
Optics
Federico Carollo et al.
Summary: Time crystals are nonstationary dynamical phases that arise from the breaking of continuous time-translation symmetry in Markovian open quantum systems. In this study, we fully characterize a boundary time-crystal phase transition and provide exact expressions for the order parameter and the dynamics of quantum fluctuations. We show that boundary time crystals are critical phases with power-law divergent fluctuations, indicating distinct properties of correlations compared to stationary phases.
Article
Physics, Multidisciplinary
Koki Chinzei et al.
Summary: We investigate dissipative discrete time crystals (DTCs) in solids, where a dissipative quantum Ising model is periodically driven by a train of pulses. The interaction between the spins breaks the discrete time translation symmetry and results in a dissipative DTC, where two ferromagnetic states switch alternately by each pulse. Unlike other DTC studies, we find that the dissipation in this model stabilizes the DTC order without fine-tuning at low temperatures. We study the nonequilibrium DTC phase transition and determine the critical exponents using a time-dependent mean-field theory. We also observe phase transitions without an equilibrium counterpart due to the interplay of the periodic drive and dissipation. Additionally, we demonstrate the robustness of the DTC against small imperfections and find that discrete time quasicrystals can appear for larger imperfections. Our results pave the way for realizing the DTC and uncovering nonequilibrium critical phenomena in real solid-state materials.
PHYSICAL REVIEW RESEARCH
(2022)
Article
Physics, Multidisciplinary
Catalin-Mihai Halati et al.
Summary: In this study, the strong symmetry of bosonic atoms coupled to an optical cavity was investigated. It was found that multiple steady states exist for ideal bosons coupled to the cavity, and a dissipative phase transition occurs in each symmetry sector at different critical points. The introduction of a slight breaking of the strong symmetry led to a direct transition from multiple steady states to a unique steady state. The phenomenon of dissipative freezing, where the conservation law is broken at the level of individual realizations in the presence of strong symmetry, was also observed.
PHYSICAL REVIEW RESEARCH
(2022)
Article
Optics
Parvinder Solanki et al.
Summary: This article investigates the synchronization problem in quantum systems using the Liouville space perturbation theory. By analyzing the eigenspectrum of the Liouville superoperator, the conditions for synchronization are determined, and a powerful relationship between energy conservation, degeneracies, and synchronization in quantum systems is derived.
Article
Optics
Tong Liu et al.
Summary: We propose a scheme for discrete time crystals (DTCs) based on the metastability of the driven-dissipative Bose-Hubbard model, linking the two metastable states using rotation operations and two-photon processes, and validate it through numerical analysis. The scheme only requires local dissipations and uniform rotations, making it feasible on current noisy intermediate-scale quantum platforms.
Article
Physics, Multidisciplinary
Wen-Long You et al.
Summary: This study provides a physical example of quantum scars by investigating the many-body scars in the spin-1 Kitaev chain. The essential physics of the PXP model is illustrated through the continuous revivals of fidelity and entanglement entropy. Quantum phase transitions in the one-dimensional spin-1 Kitaev-Heisenberg model are studied using density-matrix renormalization group and Lanczos exact diagonalization methods, resulting in a rich ground-state phase diagram. The stability of the scarred state is found to depend on perturbations obeying Z(2)-symmetry, while becoming unstable against Heisenberg-type perturbations.
PHYSICAL REVIEW RESEARCH
(2022)
Article
Physics, Multidisciplinary
K. Seetharam et al.
Summary: Controlling the spread of correlations in quantum many-body systems is a challenging task in quantum science and technology. In this study, the use of dissipation for engineering various spatiotemporal correlation profiles was demonstrated. By implementing dissipation with different spatial profiles in cold atoms trapped in an optical cavity, it was shown that correlations can be created or destroyed by carefully choosing the external field and spatial distribution. The results indicate the potential of nonlocal dissipation in manipulating the dynamics of quantum information in far-from-equilibrium scenarios, with applications in quantum metrology, state preparation, and transport.
PHYSICAL REVIEW RESEARCH
(2022)
Article
Optics
Peter-Maximilian Ney et al.
Summary: This study investigates the quantum dynamics of a spin chain that simulates Conway's Game of Life. By solving the time-dependent Schrodinger equation for separable initial states, the evolution of quantum correlations across the lattice is analyzed. Examples of evolutions resulting in entangled chains or oscillating entangling structures are reported and characterized using entanglement and network measures. The quantum patterns exhibit structures that differ significantly from classical ones, even in the dynamics of local observables. A notable example is a structure that behaves as a quantum analog of a blinker, but does not have a classical counterpart.
Article
Engineering, Electrical & Electronic
Constantinos Valagiannopoulos et al.
Summary: Nonlinear materials can exhibit bistability, which can find direct application to photonic memory devices. Impedance metasurfaces producing hysteresis responses with respect to impinging beam angle under a fixed intensity profile can open new avenues towards the design of photonic systems supporting a wide range of fixed-power memory functionalities.
IEEE TRANSACTIONS ON ANTENNAS AND PROPAGATION
(2021)
Article
Physics, Multidisciplinary
Albert Cabot et al.
Summary: Research shows that quantum van der Pol oscillators, driven by squeezed drive, display multiple preferred phases and exhibit extremely long lifetimes, which is related to metastability in open quantum systems.
NEW JOURNAL OF PHYSICS
(2021)
Article
Physics, Multidisciplinary
Vincent P. Flynn et al.
Summary: The study demonstrates that Majorana bosons can emerge in noninteracting bosonic chains through the interplay between dynamical metastability and nontrivial bulk topology. This leads to a unique form of topological metastability where a localized conserved Majorana boson is paired with a symmetry generator localized on the opposite edge. Majorana bosons are shown to be robust against disorder and can be identified by signatures in the zero-frequency steady-state power spectrum.
PHYSICAL REVIEW LETTERS
(2021)
Article
Multidisciplinary Sciences
Andrea Pizzi et al.
Summary: The researchers introduced a simple cellular automaton model with power-law interactions, leading to a bistable phase of long-ranged directed percolation. They found that the system's response period is affected by periodic modulation. The self-correcting mechanism of long-ranged interactions can compensate for noise-induced imperfections.
NATURE COMMUNICATIONS
(2021)
Review
Physics, Multidisciplinary
Maksym Serbyn et al.
Summary: Thermalization is the inevitable fate of many complex quantum systems, but recent discoveries have shown the existence of a new type of behavior called quantum many-body scarring, where the system rapidly relaxes for most initial conditions, yet certain initial states display non-ergodic dynamics. This phenomenon, similar to scars observed in single-particles in specific potentials, has potential applications in quantum technology.
Article
Physics, Multidisciplinary
D. Manzano et al.
Summary: This study investigates the impact of strong symmetries on the transport properties and activity patterns of a specific class of Markovian open quantum system. The findings reveal the existence of multiple steady states and dynamical phase transitions, as well as joint large deviation statistics of activity and current at specific stages.
NEW JOURNAL OF PHYSICS
(2021)
Article
Physics, Multidisciplinary
Hans Kessler et al.
Summary: This study represents the first experimental realization of a time crystal stabilized by dissipation. The period doubled switching between distinct checkerboard density wave patterns in a driven open atom-cavity system is induced by controlled cavity dissipation, cavity-mediated interactions, and external driving. The research demonstrates the robustness of this dynamical phase against changes in system parameters and temporal perturbations of the driving.
PHYSICAL REVIEW LETTERS
(2021)
Article
Physics, Multidisciplinary
Jimmy S. C. Hung et al.
Summary: There is a growing interest in realizing quantum simulators for physical systems where perturbative methods are ineffective. The scalability and flexibility of circuit quantum electrodynamics make it a promising platform for implementing various types of simulators. A multimode superconducting parametric cavity is used as a hardware-efficient analog quantum simulator to realize a lattice in synthetic dimensions with complex hopping interactions, allowing simulation of gauge potentials and topological models. The platform can be easily extended to larger lattices and different models involving other interactions.
PHYSICAL REVIEW LETTERS
(2021)
Article
Materials Science, Multidisciplinary
Thomas Mueller et al.
Summary: The study reveals that multiple dissipative impurities can cause resonant effects in weakly interacting fermionic quantum wires, affecting their transport properties and particle momentum distribution. While the fluctuation-induced quantum Zeno effect is robust against impurity shape, the fluctuation-induced transparency is continuously lifted by impurity shape modifications.
Article
Physics, Multidisciplinary
K. Pakrouski et al.
Summary: The research shows that three highly symmetric families of states are many-body scars for certain forms of fermionic Hamiltonians, with one of them being the well-known eta-pairing states. These states, besides possessing typical scar properties, are also insensitive to electromagnetic noise and advantageous for quantum information storage and processing. Additionally, various common coupling terms and the Hamiltonians containing them support these states as scars without requiring fine-tuning.
PHYSICAL REVIEW RESEARCH
(2021)
Article
Materials Science, Multidisciplinary
Giulia Piccitto et al.
Summary: The study reveals that the observation of the boundary time crystal (BTC) phase requires two conditions to be met: the discrete symmetry held by the Hamiltonian must be explicitly broken, and the system must be uniformly coupled to the same bath to preserve total angular momentum.
Article
Physics, Multidisciplinary
Katarzyna Macieszczak et al.
Summary: The theory presented focuses on classical metastability in open quantum systems, explaining how metastable states can be approximated as probabilistic mixtures of a finite number of states and leading to various classical features in the dynamics. It is also noted that classical dynamics can be observed not only on average but also at the level of individual quantum trajectories, shedding light on the emergence of first-order dynamical phase transitions from metastability. The numerical approach developed offers an efficient way to verify the presence of classical metastability in open quantum systems, providing a set of metastable phases and effective classical dynamics.
PHYSICAL REVIEW RESEARCH
(2021)
Article
Materials Science, Multidisciplinary
Muath Natsheh et al.
Summary: In the periodically driven O(N) model, the critical properties of forming the Floquet time crystal in the prethermal phase are investigated. Key exponents such as v, beta, and theta are determined using a combination of dimensional expansion and exact solutions for large N, showing that these exponents remain the same as those in the absence of drive. The spatial structure of two-point correlation functions near the critical line exhibits longer algebraic decays compared to the absence of a drive, with period doubling and oscillations at a specific wave vector.
Review
Physics, Condensed Matter
Farokh Mivehvar et al.
Summary: The field of quantum-gas cavity QED has rapidly evolved over the past decade, offering opportunities to implement, simulate, and experimentally test fundamental solid-state Hamiltonians as well as non-equilibrium many-body phenomena. Notable experiments have observed various phenomena by designing and controlling photon-induced tunable-range interactions in open quantum environments.
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Adam Bacsi et al.
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