Your search keyword '"Yao, Norman Y."' showing total 32 results

1. Long-range prethermal phases of nonequilibrium matter

Author

Massachusetts Institute of Technology. Department of Physics, Machado, Francisco, Else, Dominic, Kahanamoku-Meyer, Gregory D., Nayak, Chetan, Yao, Norman Y., Massachusetts Institute of Technology. Department of Physics, Machado, Francisco, Else, Dominic, Kahanamoku-Meyer, Gregory D., Nayak, Chetan, and Yao, Norman Y.

Abstract

DARPA DRINQS program (Grant No. D18AC00033), Gordon and Betty Moore Foundation (Grant no. GBMF4303)

Published

2020

2. Improved Lieb-Robinson bound for many-body Hamiltonians with power-law interactions

Author

Massachusetts Institute of Technology. Department of Physics, Else, Dominic V., Machado, Francisco, Nayak, Chetan, Yao, Norman Y., Massachusetts Institute of Technology. Department of Physics, Else, Dominic V., Machado, Francisco, Nayak, Chetan, and Yao, Norman Y.

Published

2020

3. Topological bands with a Chern number C = 2 by dipolar exchange interactions.

Author

Peter, David, Yao, Norman Y., Lang, Nicolai, Huber, Sebastian D., Lukin, Mikhail D., and Büchler, Hans Peter

Subjects

*ENERGY bands, *SYMMETRY breaking, *OPTICAL lattices, *TOPOLOGY, *EXCHANGE interactions (Magnetism), *SPIN-orbit interactions

Abstract

We demonstrate the realization of topological band structures by exploiting the intrinsic spin-orbit coupling of dipolar interactions in combination with broken time-reversal symmetry. The system is based on polar molecules trapped in a deep optical lattice, where the dynamics of rotational excitations follows a hopping Hamiltonian which is determined by the dipolar exchange interactions. We find topological bands with Chern number C = 2 on the square lattice, while a very rich structure of different topological bands appears on the honeycomb lattice. We show that the system is robust against missing molecules. For certain parameters we obtain flat bands, providing a promising candidate for the realization of hard-core bosonic fractional Chern insulators. [ABSTRACT FROM AUTHOR]

Published

2015

4. Fractional quantum Hall states of Rydberg polaritons.

Author

Maghrebi, Mohammad F., Yao, Norman Y., Hafezi, Mohammad, Pohl, Thomas, Firstenberg, Ofer, and Gorshkov, Alexey V.

Subjects

*POLARITONS, *QUANTUM Hall effect, *QUANTUM states, *RYDBERG states, *SPIN-half particle, *OPTICAL resonance

Abstract

We propose a scheme for realizing fractional quantum Hall states of light. In our scheme, photons of two polarizations are coupled to different atomic Rydberg states to form two flavors of Rydberg polaritons that behave as an effective spin. An array of optical cavity modes overlapping with the atomic cloud enables the realization of an effective spin-1 /2 lattice. We show that the dipolar interaction between such polaritons, inherited from the Rydberg states, can be exploited to create a flat, topological band for a single spin-flip excitation. At half filling, this gives rise to a photonic (or polaritonic) fractional Chern insulator--a lattice-based, fractional quantum Hall state of light. [ABSTRACT FROM AUTHOR]

Published

2015

5. Controllable quantum spin glasses with magnetic impurities embedded in quantum solids.

Author

Lemeshko, Mikhail, Yao, Norman Y., Gorshkov, Alexey V., Weimer, Hendrik, Bennett, Steven D., Momose, Takamasa, and Gopalakrishnan, Sarang

Subjects

*QUANTUM spin models, *MAGNETIC impurities, *COORDINATE covalent bond, *ANISOTROPY, *SOLID helium

Abstract

Magnetic impurities embedded in inert solids can exhibit long coherence times and interact with one another via their intrinsic anisotropic dipolar interaction. We argue that, as a consequence of these properties, disordered ensembles of magnetic impurities provide an effective platform for realizing a controllable, tunable version of the dipolar quantum spin glass seen in LiHoxY1−xF4. Specifically, we propose and analyze a system composed of dysprosium atoms embedded in solid helium. We describe the phase diagram of the system and discuss the realizability and detectability of the quantum spin glass and antiglass phases. [ABSTRACT FROM AUTHOR]

Published

2013

6. Collectively Enhanced Interactions in Solid-State Spin Qubits.

Author

Weimer, Hendrik, Yao, Norman Y., and Lukin, Mikhail D.

Subjects

*QUBITS, *SPIN excitations, *MAGNETIC fields, *QUANTUM logic, *RYDBERG states

Abstract

We propose and analyze a technique to collectively enhance interactions between solid-state quantum registers composed from random networks of spin qubits. In such systems, disordered dipolar interactions generically result in localization. Here, we demonstrate the emergence of a single collective delocalized eigenmode as one turns on a transverse magnetic field. The interaction strength between this symmetric collective mode and a remote spin qubit is enhanced by the square root of the number of spins participating in the delocalized mode. Mediated by such collective enhancement, long-range quantum logic between remote spin registers can occur at distances consistent with optical addressing. A specific implementation utilizing nitrogen-vacancy defects in diamond is discussed and the effects of decoherence are considered. [ABSTRACT FROM AUTHOR]

Published

2013

7. Stress-Enhanced Gelation: A Dynamic Nonlinearity of Elasticity.

Author

Yao, Norman Y., Broedersz, Chase P., Depken, Martin, Becker, Daniel J., Pollak, Martin R., MacKintosh, Frederick C., and Weitz, David A.

Subjects

*STRAINS & stresses (Mechanics), *GELATION, *ELASTICITY, *BIOPOLYMERS, *PHYSICS

Abstract

A hallmark of biopolymer networks is their sensitivity to stress, reflected by pronounced nonlinear elastic stiffening. Here, we demonstrate a distinct dynamical nonlinearity in biopolymer networks consisting of filamentous actin cross-linked by a-actinin-4. Applied stress delays the onset of relaxation and flow, markedly enhancing gelation and extending the regime of solidlike behavior to much lower frequencies. We show that this macroscopic network response can be accounted for at the single molecule level by the increased binding affinity of the cross-linker under load, characteristic of catch-bond-like behavior. [ABSTRACT FROM AUTHOR]

Published

2013

8. Long-Range Quantum Gates using Dipolar Crystals.

Author

Weimer, Hendrik, Yao, Norman Y., Laumann, Chris R., and Lukin, Mikhail D.

Subjects

*QUANTUM theory, *CRYSTAL defects, *QUBITS, *PARAMAGNETISM, *PHASE transitions, *RYDBERG states, *DIAMOND crystals

Abstract

We propose the use of dipolar spin chains to enable long-range quantum logic between distant qubits. In our approach, an effective interaction between remote qubits is achieved by adiabatically following the ground state of the dipolar chain across the paramagnet to crystal phase transition. We demonstrate that the proposed quantum gate is particularly robust against disorder and derive scaling relations, showing that high-fidelity qubit coupling is possible in the presence of realistic imperfections. Possible experi-mental implementations in systems ranging from ultracold Rydberg atoms to arrays of nitrogen vacancy defect centers in diamond are discussed. [ABSTRACT FROM AUTHOR]

Published

2012

9. Symmetry-Enhanced Boundary Qubits at Infinite Temperature.

Author

Kemp, Jack, Yao, Norman Y., and Laumann, Chris R.

Subjects

*DOMAIN walls (String models), *DEGREES of freedom, *QUBITS, *HIGH temperatures, *TEMPERATURE, *ENERGY density

Abstract

The Z2×Z2 symmetry-protected topological (SPT) phase hosts a robust boundary qubit at zero temperature. At finite energy density, the SPT phase is destroyed and bulk observables equilibrate in finite time. Nevertheless, we predict parametric regimes in which the boundary qubit survives to arbitrarily high temperature, with an exponentially longer coherence time than that of the thermal bulk degrees of freedom. In a dual picture, the persistence of the qubit stems from the inability of the bulk to absorb the virtual Z2×Z2 domain walls emitted by the edge during the relaxation process. We confirm the long coherence times via exact diagonalization and connect it to the presence of a pair of conjugate almost strong zero modes. Our results provide a route to experimentally construct long-lived coherent boundary qubits at infinite temperature in disorder-free systems. To this end, we propose and analyze an implementation using a Rydberg optical-tweezer array and demonstrate that the difference between edge- and bulk-spin autocorrelators can be distinguished on timescales significantly shorter than the typical coherence time. [ABSTRACT FROM AUTHOR]

Published

2020

10. Dynamical Engineering of Interactions in Qudit Ensembles.

Author

Soonwon Choi, Yao, Norman Y., and Lukin, Mikhail D.

Subjects

*QUBITS, *DYNAMICS, *ALGORITHMS

Abstract

We propose and analyze a method to engineer effective interactions in an ensemble of d-level systems (qudits) driven by global control fields. In particular, we present (i) a necessary and sufficient condition under which a given interaction can be decoupled, (ii) the existence of a universal sequence that decouples any (cancelable) interaction, and (iii) an efficient algorithm to engineer a target Hamiltonian from an initial Hamiltonian (if possible). We illustrate the potential of this method with two examples. Specifically, we present a 6-pulse sequence that decouples effective spin-1 dipolar interactions and demonstrate that a spin-1 Ising chain can be engineered to study transitions among three distinct symmetry protected topological phases. Our work enables new approaches for the realization of both many-body quantum memories and programmable analog quantum simulators using existing experimental platforms. [ABSTRACT FROM AUTHOR]

Published

2017

11. Floquet Phases of Matter via Classical Prethermalization.

Author

Bingtian Ye, Machado, Francisco, and Yao, Norman Y.

Subjects

*PHASES of matter, *DISCRETE symmetries, *SYMMETRY breaking

Abstract

We demonstrate that the prethermal regime of periodically driven (Floquet), classical many-body systems can host nonequilibrium phases of matter. In particular, we show that there exists an effective Hamiltonian that captures the dynamics of ensembles of classical trajectories despite the breakdown of this description at the single trajectory level. In addition, we prove that the effective Hamiltonian can host emergent symmetries protected by the discrete time-translation symmetry of the drive. The spontaneous breaking of such an emergent symmetry leads to a subharmonic response, characteristic of time crystalline order, that survives to exponentially late times in the frequency of the drive. To this end, we numerically demonstrate the existence of classical prethermal time crystals in systems with different dimensionalities and ranges of interaction. Extensions to higher order and fractional time crystals are also discussed. [ABSTRACT FROM AUTHOR]

Published

2021

12. Spin transport of weakly disordered Heisenberg chain at infinite temperature.

Author

Khait, Ilia, Gazit, Snir, Yao, Norman Y., and Auerbach, Assa

Subjects

*HEISENBERG model, *SCALING laws (Nuclear physics), *CONTINUED fractions

Abstract

We study the disordered Heisenberg spin chain, which exhibits many-body localization at strong disorder, in the weak to moderate disorder regime. A continued fraction calculation of dynamical correlations is devised, using a variational extrapolation of recurrents. Good convergence for the infinite chain limit is shown. We find that the local spin correlations decay at long times as C~t-β, whereas the conductivity exhibits a low-frequency power law σ~ωα. The exponents depict subdiffusive behavior β<1/2,α>0 at all finite disorders and convergence to the scaling result α+2β=1 at large disorders. [ABSTRACT FROM AUTHOR]

Published

2016

13. Many-Body Dynamics of Dipolar Molecules in an Optical Lattice.

Author

Hazzard, Kaden R. A., Gadway, Bryce, Foss-Feig, Michael, Bo Yan, Moses, Steven A., Covey, Jacob P., Yao, Norman Y., Lukin, Mikhail D., Ye, Jun, Jin, Deborah S., and Rey, Ana Maria

Subjects

*MOLECULAR dynamics, *OPTICAL lattices, *MOLECULAR interactions, *QUANTUM theory, *SPECTRUM analysis

Abstract

We use Ramsey spectroscopy to experimentally probe the quantum dynamics of disordered dipolar-interacting ultracold molecules in a partially filled optical lattice, and we compare the results to theory. We report the capability to control the dipolar interaction strength. We find excellent agreement between our measurements of the spin dynamics and theoretical calculations with no fitting parameters, including the dynamics' dependence on molecule number and on the dipolar interaction strength. This agreement verifies the microscopic model expected to govern the dynamics of dipolar molecules, even in this strongly correlated beyond-mean-field regime, and represents the first step towards using this system to explore many-body dynamics in regimes that are inaccessible to current theoretical techniques. [ABSTRACT FROM AUTHOR]

Published

2014

14. Measurement-Induced Transition in Long-Range Interacting Quantum Circuits.

Author

Block, Maxwell, Yimu Bao, Soonwon Choi, Altman, Ehud, and Yao, Norman Y.

Subjects

*QUANTUM phase transitions, *HYBRID integrated circuits, *ISING model, *ANALYTIC mappings, *QUANTUM entanglement, *QUANTUM communication

Abstract

The competition between scrambling unitary evolution and projective measurements leads to a phase transition in the dynamics of quantum entanglement. Here, we demonstrate that the nature of this transition is fundamentally altered by the presence of long-range, power-law interactions. For sufficiently weak power laws, the measurement-induced transition is described by conformal field theory, analogous to short-range-interacting hybrid circuits. However, beyond a critical power law, we demonstrate that long-range interactions give rise to a continuum of nonconformal universality classes, with continuously varying critical exponents. We numerically determine the phase diagram for a one-dimensional, long-range-interacting hybrid circuit model as a function of the power-law exponent and the measurement rate. Finally, by using an analytic mapping to a long-range quantum Ising model, we provide a theoretical understanding for the critical power law. [ABSTRACT FROM AUTHOR]

Published

2022

15. Preparation of Low Entropy Correlated Many-Body States via Conformal Cooling Quenches.

Author

Zaletel, Michael P., Kaufman, Adam, Stamper-Kurn, Dan M., and Yao, Norman Y.

Subjects

*ENTROPY, *POLAR molecules, *COOLING, *HUBBARD model, *MATRIX multiplications, *RYDBERG states, *TOPOLOGICAL entropy

Abstract

We propose and analyze a method for preparing low entropy many-body states in isolated quantum optical systems of atoms, ions, and molecules. Our approach is based upon shifting entropy between different regions of a system by spatially modulating the magnitude of the effective Hamiltonian. We conduct two case studies, on a topological spin chain and the spinful fermionic Hubbard model, focusing on the key question: can a "conformal cooling quench" remove sufficient entropy within experimentally accessible timescales? Finite-temperature, time-dependent matrix product state calculations reveal that even moderately sized bath regions can remove enough energy and entropy density to expose coherent low-temperature physics. The protocol is particularly natural in systems with long-range interactions, such as lattice-trapped polar molecules and Rydberg-excited atoms, where the magnitude of the Hamiltonian scales directly with the interparticle spacing. To this end, we propose simple, near-term implementations of conformal cooling quenches in systems of atoms or molecules, where signatures of low-temperature phases may be observed. [ABSTRACT FROM AUTHOR]

Published

2021

16. Emergent Ergodicity at the Transition between Many-Body Localized Phases.

Author

Sahay, Rahul, Machado, Francisco, Bingtian Ye, Laumann, Chris R., and Yao, Norman Y.

Subjects

*CRYSTAL symmetry, *SPIN glasses, *GLASS fibers, *PHASE transitions, *CRYSTAL glass, *QUANTUM cryptography

Abstract

Strongly disordered systems in the many-body localized (MBL) phase can exhibit ground state order in highly excited eigenstates. The interplay between localization, symmetry, and topology has led to the characterization of a broad landscape of MBL phases ranging from spin glasses and time crystals to symmetry protected topological phases. Understanding the nature of phase transitions between these different forms of eigenstate order remains an essential open question. Here, we conjecture that no direct transition between distinct MBL orders can occur in one dimension; rather, an ergodic phase always intervenes. Motivated by recent advances in Rydberg-atom-based quantum simulation, we propose an experimental protocol where the intervening ergodic phase can be diagnosed via the dynamics of local observables. [ABSTRACT FROM AUTHOR]

Published

2021

17. Many-Body Chaos in the Sachdev-Ye-Kitaev Model.

Author

Kobrin, Bryce, Zhenbin Yang, Kahanamoku-Meyer, Gregory D., Olund, Christopher T., Moore, Joel E., Stanford, Douglas, and Yao, Norman Y.

Subjects

*MAJORANA fermions, *KRYLOV subspace, *LYAPUNOV exponents, *LOW temperatures, *BLACK holes, *THERMAL neutrons

Abstract

Many-body chaos has emerged as a powerful framework for understanding thermalization in strongly interacting quantum systems. While recent analytic advances have sharpened our intuition for many-body chaos in certain large N theories, it has proven challenging to develop precise numerical tools capable of exploring this phenomenon in generic Hamiltonians. To this end, we utilize massively parallel, matrix-free Krylov subspace methods to calculate dynamical correlators in the Sachdev-Ye-Kitaev model for up to N=60 Majorana fermions. We begin by showing that numerical results for two-point correlation functions agree at high temperatures with dynamical mean field solutions, while at low temperatures finite-size corrections are quantitatively reproduced by the exactly solvable dynamics of near extremal black holes. Motivated by these results, we develop a novel finite-size rescaling procedure for analyzing the growth of out-of-time-order correlators. Our procedure accurately determines the Lyapunov exponent, λ, across a wide range in temperatures, including in the regime where λ approaches the universal bound, λ=2π/β. [ABSTRACT FROM AUTHOR]

Published

2021

18. Emergent Hydrodynamics in Nonequilibrium Quantum Systems.

Author

Bingtian Ye, Machado, Francisco, White, Christopher David, Mong, Roger S. K., and Yao, Norman Y.

Subjects

*HYDRODYNAMICS, *DENSITY matrices, *SYSTEM dynamics, *PHYSICS

Abstract

A tremendous amount of recent attention has focused on characterizing the dynamical properties of periodically driven many-body systems. Here, we use a novel numerical tool termed "density matrix truncation" (DMT) to investigate the late-time dynamics of large-scale Floquet systems. We find that DMT accurately captures two essential pieces of Floquet physics, namely, prethermalization and late-time heating to infinite temperature. Moreover, by implementing a spatially inhomogeneous drive, we demonstrate that an interplay between Floquet heating and diffusive transport is crucial to understanding the system's dynamics. Finally, we show that DMT also provides a powerful method for quantitatively capturing the emergence of hydrodynamics in static (undriven) Hamiltonians; in particular, by simulating the dynamics of generic, large-scale quantum spin chains (up to L = 100), we are able to directly extract the energy diffusion coefficient. [ABSTRACT FROM AUTHOR]

Published

2020

19. Floquet Hopf Insulators.

Author

Schuster, Thomas, Gazit, Snir, Moore, Joel E., and Yao, Norman Y.

Subjects

*TOPOLOGICAL insulators, *DIRAC function, *PARTICLE physics, *CONDENSED matter, *PHASES of matter

Abstract

We predict the existence of a Floquet topological insulator in three-dimensional two-band systems, the Floquet Hopf insulator, which possesses two distinct topological invariants. One is the Hopf Z invariant, a linking number characterizing the (nondriven) Hopf topological insulator. The second invariant is an intrinsically Floquet Z2 invariant, and represents a condensed matter realization of the topology underlying the Witten anomaly in particle physics. Both invariants arise from topological defects in the system's time evolution, subject to a process in which defects at different quasienergies exchange even amounts of topological charge. Their contrasting classifications lead to a measurable physical consequence, namely, an unusual bulk-boundary correspondence where gapless edge modes are topologically protected, but may exist at either 0 or p quasienergy. Our results represent a phase of matter beyond the conventional classification of Floquet topological insulators. [ABSTRACT FROM AUTHOR]

Published

2019

20. Depolarization Dynamics in a Strongly Interacting Solid-State Spin Ensemble.

Author

Joonhee Choi, Soonwon Choi, Kucsko, Georg, Maurer, Peter C., Shields, Brendan J., Hitoshi Sumiya, Shinobu Onoda, Junichi Isoya, Demler, Eugene, Jelezko, Fedor, Yao, Norman Y., and Lukin, Mikhail D.

Subjects

*DYNAMICS, *NITROGEN, *DENSITY

Abstract

We study the depolarization dynamics of a dense ensemble of dipolar interacting spins, associated with nitrogen-vacancy centers in diamond. We observe anomalously fast, density-dependent, and nonexponential spin relaxation. To explain these observations, we propose a microscopic model where an interplay of long-range interactions, disorder, and dissipation leads to predictions that are in quantitative agreement with both current and prior experimental results. Our results pave the way for controlled many-body experiments with long-lived and strongly interacting ensembles of solid-state spins. [ABSTRACT FROM AUTHOR]

Published

2017

21. Adiabatic Quantum Search in Open Systems.

Author

Wild, Dominik S., Gopalakrishnan, Sarang, Knap, Michael, Yao, Norman Y., and Lukin, Mikhail D.

Subjects

*QUANTUM computing, *OPEN systems (Physics), *SEARCH algorithms

Abstract

Adiabatic quantum algorithms represent a promising approach to universal quantum computation. In isolated systems, a key limitation to such algorithms is the presence of avoided level crossings, where gaps become extremely small. In open quantum systems, the fundamental robustness of adiabatic algorithms remains unresolved. Here, we study the dynamics near an avoided level crossing associated with the adiabatic quantum search algorithm, when the system is coupled to a generic environment. At zero temperature, we find that the algorithm remains scalable provided the noise spectral density of the environment decays sufficiently fast at low frequencies. By contrast, higher order scattering processes render the algorithm inefficient at any finite temperature regardless of the spectral density, implying that no quantum speedup can be achieved. Extensions and implications for other adiabatic quantum algorithms will be discussed. [ABSTRACT FROM AUTHOR]

Published

2016

22. Floquet Flux Attachment in Cold Atomic Systems.

Author

Kamal H, Kemp J, He YC, Fuji Y, Aidelsburger M, Zoller P, and Yao NY

Abstract

Flux attachment provides a powerful conceptual framework for understanding certain forms of topological order, including most notably the fractional quantum Hall effect. Despite its ubiquitous use as a theoretical tool, directly realizing flux attachment in a microscopic setting remains an open challenge. Here, we propose a simple approach to realizing flux attachment in a periodically driven (Floquet) system of either spins or hard-core bosons. We demonstrate that such a system naturally realizes correlated hopping interactions and provides a sharp connection between such interactions and flux attachment. Starting with a simple, nearest-neighbor, free boson model, we find evidence-from both a coupled-wire analysis and large-scale density matrix renormalization group simulations-that Floquet flux attachment stabilizes the bosonic integer quantum Hall state at 1/4 filling (on a square lattice), and the Halperin-221 fractional quantum Hall state at 1/6 filling (on a honeycomb lattice). At 1/2 filling on the square lattice, time-reversal symmetry is instead spontaneously broken and bosonic integer quantum Hall states with opposite Hall conductances are degenerate. Finally, we propose an optical-lattice-based implementation of our model on a square lattice and discuss prospects for adiabatic preparation as well as effects of Floquet heating.

Published

2024

23. Enhancing a Many-Body Dipolar Rydberg Tweezer Array with Arbitrary Local Controls.

Author

Bornet G, Emperauger G, Chen C, Machado F, Chern S, Leclerc L, Gély B, Chew YT, Barredo D, Lahaye T, Yao NY, and Browaeys A

Abstract

We implement and characterize a protocol that enables arbitrary local controls in a dipolar atom array, where the degree of freedom is encoded in a pair of Rydberg states. Our approach relies on a combination of local addressing beams and global microwave fields. Using this method, we directly prepare two different types of three-atom entangled states, including a W state and a state exhibiting finite chirality. We verify the nature of the underlying entanglement by performing quantum state tomography. Finally, leveraging our ability to measure multibasis, multibody observables, we explore the adiabatic preparation of low-energy states in a frustrated geometry consisting of a pair of triangular plaquettes. By using local addressing to tune the symmetry of the initial state, we demonstrate the ability to prepare correlated states distinguished only by correlations of their chirality (a fundamentally six-body observable). Our protocol is generic, allowing for rotations on arbitrary sub-groups of atoms within the array at arbitrary times during the experiment; this extends the scope of capabilities for quantum simulations of the dipolar XY model.

Published

2024

24. Absolutely Stable Time Crystals at Finite Temperature.

Author

Machado F, Zhuang Q, Yao NY, and Zaletel MP

Abstract

We show that locally interacting, periodically driven (Floquet) Hamiltonian dynamics coupled to a Langevin bath support finite-temperature discrete time crystals (DTCs) with an infinite autocorrelation time. By contrast to both prethermal and many-body localized DTCs, the time crystalline order we uncover is stable to arbitrary perturbations, including those that break the time translation symmetry of the underlying drive. Our approach utilizes a general mapping from probabilistic cellular automata to open classical Floquet systems undergoing continuous-time Langevin dynamics. Applying this mapping to a variant of the Toom cellular automaton, which we dub the "π-Toom time crystal," leads to a 2D Floquet Hamiltonian with a finite-temperature DTC phase transition. We provide numerical evidence for the existence of this transition, and analyze the statistics of the finite temperature fluctuations. Finally, we discuss how general results from the field of probabilistic cellular automata imply the existence of discrete time crystals (with an infinite autocorrelation time) in all dimensions, d≥1.

Published

2023

25. Operator Growth in Open Quantum Systems.

Author

Schuster T and Yao NY

Abstract

The spreading of quantum information in closed systems, often termed scrambling, is a hallmark of many-body quantum dynamics. In open systems, scrambling competes with noise, errors, and decoherence. Here, we provide a universal framework that describes the scrambling of quantum information in open systems: we predict that the effect of open-system dynamics is fundamentally controlled by operator size distributions and independent of the microscopic error mechanism. This framework allows us to demonstrate that open quantum systems exhibit universal classes of information dynamics that fundamentally differ from their unitary counterparts. Implications for the Loschmidt echo, nuclear magnetic resonance experiments, and the classical simulability of open quantum dynamics will be discussed.

Published

2023

26. Quasi-Floquet Prethermalization in a Disordered Dipolar Spin Ensemble in Diamond.

Author

He G, Ye B, Gong R, Liu Z, Murch KW, Yao NY, and Zu C

Abstract

Floquet (periodic) driving has recently emerged as a powerful technique for engineering quantum systems and realizing nonequilibrium phases of matter. A central challenge to stabilizing quantum phenomena in such systems is the need to prevent energy absorption from the driving field. Fortunately, when the frequency of the drive is significantly larger than the local energy scales of the many-body system, energy absorption is suppressed. The existence of this so-called prethermal regime depends sensitively on the range of interactions and the presence of multiple driving frequencies. Here, we report the observation of Floquet prethermalization in a strongly interacting dipolar spin ensemble in diamond, where the angular dependence of the dipolar coupling helps to mitigate the long-ranged nature of the interaction. Moreover, we extend our experimental observation to quasi-Floquet drives with multiple incommensurate frequencies. In contrast to a single-frequency drive, we find that the existence of prethermalization is extremely sensitive to the smoothness of the applied field. Our results open the door to stabilizing and characterizing nonequilibrium phenomena in quasiperiodically driven systems.

Published

2023

27. Quantum Noise Spectroscopy of Dynamical Critical Phenomena.

Author

Machado F, Demler EA, Yao NY, and Chatterjee S

Abstract

The transition between distinct phases of matter is characterized by the nature of fluctuations near the critical point. We demonstrate that noise spectroscopy can not only diagnose the presence of a phase transition, but can also determine fundamental properties of its criticality. In particular, by analyzing a scaling collapse of the decoherence profile, one can directly extract the critical exponents of the transition and identify its universality class. Our approach naturally captures the presence of conservation laws and distinguishes between classical and quantum phase transitions. In the context of quantum magnetism, our proposal complements existing techniques and provides a novel toolset optimized for interrogating two-dimensional magnetic materials.

Published

2023

28. Universal Kardar-Parisi-Zhang Dynamics in Integrable Quantum Systems.

Author

Ye B, Machado F, Kemp J, Hutson RB, and Yao NY

Abstract

Although the Bethe ansatz solution of the spin-1/2 Heisenberg model dates back nearly a century, the anomalous nature of its high-temperature transport dynamics has only recently been uncovered. Indeed, numerical and experimental observations have demonstrated that spin transport in this paradigmatic model falls into the Kardar-Parisi-Zhang (KPZ) universality class. This has inspired the significantly stronger conjecture that KPZ dynamics, in fact, occur in all integrable spin chains with non-Abelian symmetry. Here, we provide extensive numerical evidence affirming this conjecture. Moreover, we observe that KPZ transport is even more generic, arising in both supersymmetric and periodically driven models. Motivated by recent advances in the realization of SU(N)-symmetric spin models in alkaline-earth-based optical lattice experiments, we propose and analyze a protocol to directly investigate the KPZ scaling function in such systems.

Published

2022

29. SWAP Gate between a Majorana Qubit and a Parity-Protected Superconducting Qubit.

Author

Chirolli L, Yao NY, and Moore JE

Abstract

High fidelity quantum information processing requires a combination of fast gates and long-lived quantum memories. In this Letter, we propose a hybrid architecture, where a parity-protected superconducting qubit is directly coupled to a Majorana qubit, which plays the role of a quantum memory. The superconducting qubit is based upon a π-periodic Josephson junction realized with gate-tunable semiconducting wires, where the tunneling of individual Cooper pairs is suppressed. One of the wires additionally contains four Majorana zero modes that define a qubit. We demonstrate that this enables the implementation of a SWAP gate, allowing for the transduction of quantum information between the topological and conventional qubit. This architecture combines fast gates, which can be realized with the superconducting qubit, with a topologically protected Majorana memory.

Published

2022

30. Realizing Hopf Insulators in Dipolar Spin Systems.

Author

Schuster T, Flicker F, Li M, Kotochigova S, Moore JE, Ye J, and Yao NY

Abstract

The Hopf insulator is a weak topological insulator characterized by an insulating bulk with conducting edge states protected by an integer-valued linking number invariant. The state exists in three-dimensional two-band models. We demonstrate that the Hopf insulator can be naturally realized in lattices of dipolar-interacting spins, where spin exchange plays the role of particle hopping. The long-ranged, anisotropic nature of the dipole-dipole interactions allows for the precise detail required in the momentum-space structure, while different spin orientations ensure the necessary structure of the complex phases of the hoppings. Our model features robust gapless edge states at both smooth edges, as well as sharp edges obeying a certain crystalline symmetry, despite the breakdown of the two-band picture at the latter. In an accompanying paper [T. Schuster et al., Phys. Rev. A 103, AW11986 (2021)PLRAAN2469-9926] we provide a specific experimental blueprint for implementing our proposal using ultracold polar molecules of ^{40}K^{87}Rb.

Published

2021

31. Cross-link-governed dynamics of biopolymer networks.

Author

Broedersz CP, Depken M, Yao NY, Pollak MR, Weitz DA, and MacKintosh FC

Subjects

Computer Simulation, Rheology, Stress, Mechanical, Biopolymers chemistry, Cross-Linking Reagents chemistry, Models, Biological

Abstract

Recent experiments show that networks of stiff biopolymers cross-linked by transient linker proteins exhibit complex stress relaxation, enabling network flow at long times. We present a model for the dynamics controlled by cross-links in such networks. We show that a single microscopic time scale for cross-linker unbinding leads to a broad spectrum of macroscopic relaxation times and a shear modulus G ∼ ω(1/2) for low frequencies ω. This model quantitatively describes the measured rheology of actin networks cross-linked with α-actinin-4 over more than four decades in frequency.

Published

2010

32. Origins of elasticity in intermediate filament networks.

Author

Lin YC, Yao NY, Broedersz CP, Herrmann H, Mackintosh FC, and Weitz DA

Subjects

Animals, Cattle, Humans, Vimentin chemistry, Elasticity, Intermediate Filaments chemistry

Abstract

Intermediate filaments are common structural elements found in abundance in all metazoan cells, where they form networks that contribute to the elasticity. Here, we report measurements of the linear and nonlinear viscoelasticity of networks of two distinct intermediate filaments, vimentin and neurofilaments. Both exhibit predominantly elastic behavior with strong nonlinear strain stiffening. We demonstrate that divalent ions behave as effective cross-linkers for both networks, and that the elasticity of these networks is consistent with the theory for that of semiflexible polymers.

Published

2010