Your search keyword '"Klich, Israel"' showing total 217 results

1. SWAP and Transpose by displacements, Stabilizer Renyi entropies for continuous variables and qudits and other applications

Author

Klich, Israel

Subjects

Quantum Physics, Mathematical Physics

Abstract

In this note, I highlight a useful formula for the SWAP operator as an average of anti-correlated Heisenberg-Weyl displacements, valid for arbitrary-dimensional quantum systems. As an application I show how the relation can be used to quickly prove normalization identities for the Weyl function, and apply the result to Weyl magic and Wigner magic as the generalization of the recently suggested Renyi Stabilizer entropy to q-dits and CV.

Published

2024

2. Random walk with horizontal and cyclic currents

Author

Li, Joanna, Gerry, Matthew, Klich, Israel, and Segal, Dvira

Subjects

Condensed Matter - Statistical Mechanics

Abstract

We construct a minimal two-chain random walk model and study the information that fluctuations of the flux and higher cumulants can reveal about the model: its structure, parameters, and whether it operates under nonequilibrium conditions. The two coupled chains allow for both horizontal and cyclic transport. We capture these processes by deriving the cumulant generating function of the system, which characterizes both horizontal and cyclic transport in the long time limit. First, we show that either the horizontal or the cyclic currents, along with their higher-order cumulants, can be used to unravel the intrinsic structure and parameters of the model. Second, we investigate the "zero current" situation, in which the {\it horizontal} current vanishes. We find that fluctuations of the horizontal current reveal the nonequilibrium condition at intermediate bias, while the cyclic current remains nonzero throughout. We also show that in nonequilibrium scenarios close to the zero {\it horizontal} current limit, the entropy production rate is more tightly lower-bounded by the relative noise of the {\it cyclic} current, and vice versa. Finally, simulations of transport before the steady state sets in allow for the extraction of the interchain hopping rate. Our study, illustrating the information concealed in fluctuations, could see applications in chemical networks, cellular processes, and charge and energy transport materials.

Published

2024

3. Confinement and Kink Entanglement Asymmetry on a Quantum Ising Chain

Author

Khor, Brian J. J., Kürkçüoglu, D. M., Hobbs, T. J., Perdue, G. N., and Klich, Israel

Subjects

Quantum Physics, Condensed Matter - Statistical Mechanics, Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Phenomenology

Abstract

In this work, we explore the interplay of confinement, string breaking and entanglement asymmetry on a 1D quantum Ising chain. We consider the evolution of an initial domain wall and show that, surprisingly, while the introduction of confinement through a longitudinal field typically suppresses entanglement, it can also serve to increase it beyond a bound set for free particles. Our model can be tuned to conserve the number of domain walls, which gives an opportunity to explore entanglement asymmetry associated with link variables. We study two approaches to deal with the non-locality of the link variables, either directly or following a Kramers-Wannier transformation that maps bond variables (kinks) to site variables (spins). We develop a numerical procedure for computing the asymmetry using tensor network methods and use it to demonstrate the different types of entanglement and entanglement asymmetry., Comment: Accepted for Quantum Journal

Published

2023

4. Entanglement asymmetry and quantum Mpemba effect in the XY spin chain

Author

Murciano, Sara, Ares, Filiberto, Klich, Israel, and Calabrese, Pasquale

Subjects

Condensed Matter - Statistical Mechanics, Quantum Physics

Abstract

Entanglement asymmetry is a quantity recently introduced to measure how much a symmetry is broken in a part of an extended quantum system. It has been employed to analyze the non-equilibrium dynamics of a broken symmetry after a global quantum quench with a Hamiltonian that preserves it. In this work, we carry out a comprehensive analysis of the entanglement asymmetry at equilibrium taking the ground state of the XY spin chain, which breaks the $U(1)$ particle number symmetry, and provide a physical interpretation of it in terms of superconducting Cooper pairs. We also consider quenches from this ground state to the XX spin chain, which preserves the broken $U(1)$ symmetry. In this case, the entanglement asymmetry reveals that the more the symmetry is initially broken, the faster it may be restored in a subsystem, a surprising and counter-intuitive phenomenon that is a type of a quantum Mpemba effect. We obtain a quasi-particle picture for the entanglement asymmetry in terms of Cooper pairs, from which we derive the microscopic conditions to observe the quantum Mpemba effect in this system, giving further support to the criteria recently proposed for arbitrary integrable quantum systems. In addition, we find that the power law governing symmetry restoration depends discontinuously on whether the initial state is critical or not, leading to new forms of strong and weak Mpemba effects., Comment: 30 pages, 8 figures

Published

2023

5. Measurement Induced Chirality II: Diffusion and Disorder

Author

Khor, Brian J J, Wampler, Matthew, Refael, Gil, and Klich, Israel

Subjects

Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Quantum Gases, Condensed Matter - Statistical Mechanics, Quantum Physics

Abstract

Repeated quantum measurements can generate effective new non-equilibrium dynamics in matter. Here we combine such a measurement driven system with disorder. In particular, we investigate the diffusive behavior in the system and the effect of various types of disorder on the measurement induced chiral transport protocol [1]. We begin by characterizing the diffusive behavior produced by the measurements themselves in a clean system. We then examine the edge flow of particles per measurement cycle for three different types of disorder: site dilution, lattice distortion, and disorder in onsite chemical potential. In the quantum Zeno limit, the effective descriptions for the disordered measurement system with lattice distortions and random onsite potential can be modelled as a classical stochastic model, and the overall effect of increasing these disorders induces a crossover from perfect flow to zero transport. On the other hand if vacancies are present in the lattice the flow of particles per measurement cycle undergoes a percolation phase transition from unity to zero with percolation threshold $p_c \approx 0.26$, with critical exponent $\nu \approx 1.35$. We also present numerical results away from Zeno limit and note that the overall effect of moving away from the Zeno effect is to reduce particle flow per cycle when the measurement frequency in our protocol is reduced., Comment: An extension to the previous work https://journals.aps.org/prx/abstract/10.1103/PhysRevX.12.031031 and the updated version includes more extensive introductions

Published

2023

6. Fragmentation and Novel Prethermal Dynamical Phases in Disordered, Strongly-Interacting Floquet Systems

Author

Wampler, Matthew and Klich, Israel

Subjects

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

Abstract

We explore how disorder and interactions conspire in lattice models with sequentially activated hopping to produce novel k-body (or many-body) localized phases. Specifically, we show that when disorder is added to the set of interacting floquet models considered in [Wampler and Klich arXiv:2209.09180], regions in parameter space near the special points where classical-like dynamics emerge are stabilized prethermally (or via many-body localization in some cases) producing new families of interesting phases. We also find that this disordered system exhibits novel phases in regions of parameter space away from the special, Diophantine points. Furthermore, the regions in parameter space where Hilbert space fragmentation occurs in the clean system (leading to Krylov subspaces exhibiting frozen dynamics, cellular automation, and subspaces exhibiting signs of ergodic behavior) may also be stabilized by the addition of disorder. This leads to the emergence of exotic dynamics within the Krylov subspace.

Published

2022

7. Coupled Fredkin and Motzkin chains from quantum six- and nineteen-vertex models

Author

Zhang, Zhao and Klich, Israel

Subjects

Quantum Physics, Condensed Matter - Statistical Mechanics, Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Lattice, Mathematical Physics

Abstract

We generalize the area-law violating models of Fredkin and Motzkin spin chains into two dimensions by building quantum six- and nineteen-vertex models with correlated interactions. The Hamiltonian is frustration free, and its projectors generate ergodic dynamics within the subspace of height configuration that are non negative. The ground state is a volume- and color-weighted superposition of classical bi-color vertex configurations with non-negative heights in the bulk and zero height on the boundary. The entanglement entropy between subsystems has a phase transition as the $q$-deformation parameter is tuned, which is shown to be robust in the presence of an external field acting on the color degree of freedom. The ground state undergoes a quantum phase transition between area- and volume-law entanglement phases with a critical point where entanglement entropy scales as a function $L\log L$ of the linear system size $L$. Intermediate power law scalings between $L\log L$ and $L^2$ can be achieved with an inhomogeneous deformation parameter that approaches 1 at different rates in the thermodynamic limit. For the $q>1$ phase, we construct a variational wave function that establishes an upper bound on the spectral gap that scales as $q^{-L^3/8}$.

Published

2022

8. Quantum lozenge tiling and entanglement phase transition

Author

Zhang, Zhao and Klich, Israel

Subjects

Quantum Physics, Condensed Matter - Statistical Mechanics, Mathematical Physics

Abstract

While volume violation of area law has been exhibited in several quantum spin chains, the construction of a corresponding ground state in higher dimensions, entangled in more than one direction, has been an open problem. Here we construct a 2D frustration-free Hamiltonian with maximal violation of the area law. We do so by building a quantum model of random surfaces with color degree of freedom that can be viewed as a collection of colored Dyck paths. The Hamiltonian may be viewed as a 2D generalization of the Fredkin spin chain. It relates all the colored random surface configurations subject to a Dirichlet boundary condition and hard wall constraint from below to one another, and the ground state is therefore a superposition of all such classical states and non-degenerate. Its entanglement entropy between subsystems undergoes a quantum phase transition as the deformation parameter is tuned. The area- and volume-law phases are similar to the one-dimensional model, while the critical point scales with the linear size of the system $L$ as $L\log L$. Further it is conjectured that similar models with entanglement phase transitions can be built in higher dimensions with even softer area law violations at the critical point.

Published

2022

9. Arrested Development and Fragmentation in Strongly-Interacting Floquet Systems

Author

Wampler, Matthew and Klich, Israel

Subjects

Quantum Physics

Abstract

We explore how interactions can facilitate classical like dynamics in models with sequentially activated hopping. Specifically, we add local and short range interaction terms to the Hamiltonian, and ask for conditions ensuring the evolution acts as a permutation on initial local number Fock states. We show that at certain values of hopping and interactions, determined by a set of Diophantine equations, such evolution can be realized. When only a subset of the Diophantine equations is satisfied the Hilbert space can be fragmented into frozen states, states obeying cellular automata like evolution and subspaces where evolution mixes Fock states and is associated with eigenstates exhibiting high entanglement entropy and level repulsion.

Published

2022

10. Stirring by Staring: Measurement Induced Chirality

Author

Wampler, Matthew, Khor, Brian J. J., Refael, Gil, and Klich, Israel

Subjects

Quantum Physics, Condensed Matter - Quantum Gases, Condensed Matter - Statistical Mechanics

Abstract

In quantum mechanics, the observer necessarily plays an active role in the dynamics of the system, making it difficult to probe a system without disturbing it. Here, we leverage this apparent difficulty as a tool for driving an initially trivial system into a chiral phase. In particular, we show that by utilizing a pattern of repeated occupation measurements we can produce chiral edge transport of fermions hopping on a Lieb lattice. The procedure is similar in spirit to the use of periodic driving to induce chiral edge transport in Floquet topological insulators, while also exhibiting novel phenomena due to the non-unitary nature of the quantum measurements. We study in detail the dependence of the procedure on measurement frequency, showing that in the Zeno limit the system can be described by a classical stochastic dynamics, yielding protected transport. As the frequency of measurements is reduced, the charge flow is reduced and vanishes when no measurements are done.

Published

2021

11. Freezing of a disorder induced quantum spin liquid

Author

Hu, Xiao, Pajerowski, Daniel M., Zhang, Depei, Podlesnyak, Andrey A., Qiu, Yiming, Huang, Qing, Zhou, Haidong, Klich, Israel, Kolesnikov, Alexander I., Stone, Matthew B., and Lee, Seung-Hun

Subjects

Condensed Matter - Materials Science

Abstract

$\rm{Sr_2CuTe_{0.5}W_{0.5}O_6}$ is a square-lattice magnet with super-exchange between S=1/2 $\rm{Cu^{2+}}$ spins mediated by randomly distributed Te and W ions. Here, using sub-K temperature and 20 $\rm{\mu}$eV energy resolution neutron scattering experiments we show that this system transits from a gapless disorder-induced quantum spin liquid to a new quantum state below $\rm{T_f}$ = 1.7(1) K, exhibiting a weak frozen moment of /S ~ 0.1 and low energy dynamic susceptibility,${\chi}''({\hbar\omega})$ linear in energy which is surprising for such a weak freezing in this highly fluctuating quantum regime.

Published

2021

12. Quantum wakes in lattice fermions

Author

Wampler, Matthew, Schauss, Peter, Kolomeisky, Eugene B, and Klich, Israel

Subjects

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

Abstract

The wake following a vessel in water is a signature interference effect of moving bodies, and, as described by Lord Kelvin, is contained within a constant universal angle. However, wakes may accompany different kinds of moving disturbances in other situations and even in lattice systems. Here, we investigate the effect of moving disturbances on a Fermi lattice gas of ultracold atoms and analyze the novel types of wake patterns that may occur. We show how at half-filling, the wake angles are dominated by the ratio of the hopping energy to the velocity of the disturbance and on the angle of motion relative to the lattice direction. Moreover, we study the difference between wakes left behind a moving particle detector versus that of a moving potential or a moving particle extractor. We show that these scenarios exhibit dramatically different behavior at half-filling, with the "measurement wake" following an idealized detector vanishing, though the motion of the detector does still leaves a trace through a "fluctuation wake." Finally, we discuss the experimental requirements to observe our predictions in ultracold fermionic atoms in optical lattices.

Published

2020

13. Emergent geometry and path integral optimization for a Lifshitz action

Author

Ahmadain, Amr and Klich, Israel

Subjects

High Energy Physics - Theory, Condensed Matter - Statistical Mechanics, Condensed Matter - Strongly Correlated Electrons

Abstract

Extending the background metric optimization procedure for Euclidean path integrals of two-dimensional conformal field theories, introduced by Caputa et al. (Phys. Rev. Lett. 119, 071602 (2017)), to a $z=2$ anisotropically scale-invariant $(2+1)$-dimensional Lifshitz field theory of a free massless scalar field, we find optimal geometries for static and dynamic correlation functions. For the static correlation functions, the optimal background metric is equivalent to an AdS metric on a Poincare patch, while for dynamical correlation functions, we find Lifshitz like metric. This results suggest that a MERA-like tensor network, perhaps without unitarity, would still be considered an optimal background spacetime configuration for the numerical description of this system, even though the classical action we start with is not a conformal field theory., Comment: corrected typos

Published

2020

14. Spatiotemporal graph states from a single optical parametric oscillator

Author

Yang, Rongguo, Zhang, Jing, Klich, Israel, González-Arciniegas, Carlos, and Pfister, Olivier

Subjects

Quantum Physics

Abstract

An experimental scheme is proposed for building massively multipartite entangled states using both the spatial and the frequency modes of an optical parametric oscillator. We provide analytical forms of the entangled states using the squeezed eigenmodes of Heisenberg equations, a.k.a. the nullifiers of the corresponding graph state. This scheme can generate, in parallel, several cluster states described by sparsely connected, bicolorable graph states, usable for one-way quantum computing. We indicate the experimentally accessible quantum graphs, depending on the squeezing parameter.

Published

2019

15. Solution of the Metropolis dynamics on a complete graph with application to the Markov chain Mpemba effect

Author

Klich, Israel and Vucelja, Marija

Subjects

Mathematical Physics, Condensed Matter - Statistical Mechanics

Abstract

We find analytically the complete set of eigenvalues and eigenvectors associated with Metropolis dynamics on a complete graph. As an application, we use this information to study a counter-intuitive relaxation phenomenon, called the Mpemba effect. This effect describes situations when upon performing a thermal quench, a system prepared in equilibrium at high temperatures relaxes faster to the bath temperature than a system prepared at a temperature closer to that of the bath. We show that Metropolis dynamics on a complete graph does not support weak nor strong Mpemba effect, however, when the graph is not complete, the effect is possible.

Published

2018

16. Holographic rainbow networks for colorful Motzkin and Fredkin spin chains

Author

Alexander, Rafael N., Ahmadain, Amr, Zhang, Zhao, and Klich, Israel

Subjects

Quantum Physics, Condensed Matter - Statistical Mechanics

Abstract

We present bulk tensor networks that exactly represent the ground states of a continuous family of one-dimensional frustration-free Hamiltonians. These states, which are known as area-deformed Motzkin and Fredkin states, exhibit a novel quantum phase transition. By tuning a single parameter, they go from a phase obeying an area law to a highly entangled rainbow phase, where the half-chain entropy scales with the volume. Using the representation of these ground states as superpositions of random walks, we introduce tensor networks for these ground states where local and global rules of the walker are baked into bulk tensors, thereby providing an efficient description of the ground states (some of which satisfy a volume law scaling of entanglement entropy)., Comment: 7 pages, 6 figures

Published

2018

17. Exact holographic tensor networks for the Motzkin spin chain

Author

Alexander, Rafael N., Evenbly, Glen, and Klich, Israel

Subjects

Quantum Physics

Abstract

The study of low-dimensional quantum systems has proven to be a particularly fertile field for discovering novel types of quantum matter. When studied numerically, low-energy states of low-dimensional quantum systems are often approximated via a tensor-network description. The tensor network's utility in studying short range correlated states in 1D have been thoroughly investigated, with numerous examples where the treatment is essentially exact. Yet, despite the large number of works investigating these networks and their relations to physical models, examples of exact correspondence between the ground state of a quantum critical system and an appropriate scale-invariant tensor network have eluded us so far. Here we show that the features of the quantum-critical Motzkin model can be faithfully captured by an analytic tensor network that exactly represents the ground state of the physical Hamiltonian. In particular, our network offers a two-dimensional representation of this state by a correspondence between walks and a type of tiling of a square lattice. We discuss connections to renormalization and holography., Comment: (v4) 22 pages, 34 figures; (v3) 20 pages, 34 figures, including tensors for area weighted walks; (v2) 27 pages, 24 figures, alternative tensor network construction included in appendix, extended discussion; (v1) 21 pages, 20 figures

Published

2018

18. The Mpemba index and anomalous relaxation

Author

Klich, Israel, Raz, Oren, Hirschberg, Ori, and Vucelja, Marija

Subjects

Condensed Matter - Statistical Mechanics, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Soft Condensed Matter

Abstract

The Mpemba effect is a counter-intuitive relaxation phenomenon, where a system prepared at a hot temperature cools down faster than an identical system initiated at a cold temperature when both are quenched to an even colder bath. Such non-monotonic relaxations were observed in various systems, including water, magnetic alloys, polymers, and driven granular gases. We analyze the Mpemba effect in Markovian dynamics and discover that a stronger version of the effect often exists for a carefully chosen set of initial temperatures. In this \emph{strong Mpemba effect}, the relaxation time jumps to a smaller value leading to exponentially faster equilibration dynamics. The number of such special initial temperatures defines the \emph{Mpemba index}, whose parity is a topological property of the system. To demonstrate these concepts, we first analyze the different types of Mpemba relaxations in the mean field anti-ferromagnet Ising model, which demonstrates a surprisingly rich Mpemba phase diagram. Moreover, we show that the strong effect survives the thermodynamic limit and that it is tightly connected with thermal overshoot -- in the relaxation process, the temperature of the relaxing system can decay non-monotonically as a function of time. Using the parity of the Mpemba index, we then study the occurrence of the strong Mpemba effect in a large class of thermal quench processes and show that it happens with non-zero probability even in the thermodynamic limit. This is done by introducing the \emph{isotropic} model for which we obtain analytical lower bound estimates for the probability of the strong Mpemba effects. Consequently, we expect that such exponentially faster relaxations can be observed experimentally in a wide variety of systems.

Published

2017

19. Aging, memory, and nonhierarchical energy landscape of spin jam

Author

Samarakoon, Anjana, Sato, Taku J., Chen, Tianran, Chern, Gai-Wei, Yang, Junjie, Klich, Israel, Zhou, Ryan Sinclair Haidong, and Lee, Seung-Hun

Subjects

Condensed Matter - Disordered Systems and Neural Networks

Abstract

The notion of complex energy landscape underpins the intriguing dynamical behaviors in many complex systems ranging from polymers, to brain activity, to social networks and glass transitions. The spin glass state found in dilute magnetic alloys has been an exceptionally convenient laboratory frame for studying complex dynamics resulting from a hierarchical energy landscape with rugged funnels. Here, we show, by a bulk susceptibility and Monte Carlo simulation study, that densely populated frustrated magnets in a spin jam state exhibit much weaker memory effects than spin glasses, and the characteristic properties can be reproduced by a nonhierarchical landscape with a wide and nearly flat but rough bottom. Our results illustrate that the memory effects can be used to probe different slow dynamics of glassy materials, hence opening a window to explore their distinct energy landscapes., Comment: 20 pages, 6 figures

Published

2017

20. Entanglement Hamiltonians and entropy in 1+1D chiral fermion systems

Author

Klich, Israel, Vaman, Diana, and Wong, Gabriel

Subjects

Condensed Matter - Statistical Mechanics, High Energy Physics - Theory

Abstract

In past work we introduced a method which allows for exact computations of entanglement Hamiltonians. The method relies on computing the resolvent for the projected (on the entangling region) Green's function using a solution to the Riemann-Hilbert problem combined with finite rank perturbation theory. Here we analyze in detail several examples involving excited states of chiral fermions (Dirac and Majorana) on a spatial circle. We compute the exact entanglement Hamiltonians and an exact formula for the change in entanglement entropy due to the introduction of a particle above the Dirac sea. For Dirac fermions, we give the first-order temperature correction to the entanglement entropy in the case of a multiple interval entangling region., Comment: 22 pages, 3 Figures

Published

2017

21. Entropy, gap and a multi-parameter deformation of the Fredkin spin chain

Author

Zhang, Zhao and Klich, Israel

Subjects

Condensed Matter - Statistical Mechanics, Mathematical Physics, Quantum Physics

Abstract

We introduce a multi-parameter deformation of the Fredkin spin $1/2$ chain whose ground state is a weighted superposition of Dyck paths, depending on a set of parameters $t_i$ along the chain. The parameters are introduced in such a way to maintain the system frustration-free while allowing to explore a range of possible phases. In the case where the parameters are uniform, and a color degree of freedom is added we establish a phase diagram with a transition between an area law and a volume low. The volume entropy obtained for half a chain is $n \log s$ where $n$ is the half-chain length and $s$ is the number of colors. Next, we prove an upper bound on the spectral gap of the $t>1, s>1$ phase, scaling as $\Delta=O((4s)^nt^{-n^2/2})$, similar to a recent a result about the deformed Motzkin model, albeit derived in a different way. Finally, using an additional variational argument we prove an exponential lower bound on the gap of the model for $t>1, s=1$, which provides an example of a system with bounded entanglement entropy and a vanishing spectral gap., Comment: Added proof for gapless phase of t>1,s=1

Published

2017

22. Deformed Fredkin Spin Chain with Extensive Entanglement

Author

Salberger, Olof, Udagawa, Takuma, Zhang, Zhao, Katsura, Hosho, Klich, Israel, and Korepin, Vladimir

Subjects

Condensed Matter - Statistical Mechanics, High Energy Physics - Theory, Mathematical Physics, Quantum Physics

Abstract

We introduce a new spin chain which is a deformation of the Fredkin spin chain and has a phase transition between bounded and extensive entanglement entropy scaling. In this chain, spins have a local interaction of three nearest neighbors. The Hamiltonian is frustration-free and its ground state can be described analytically as a weighted superposition of Dyck paths. In the purely spin $1/2$ case, the entanglement entropy obeys an area law: it is bounded from above by a constant, when the size of the block $n$ increases (and $t>1$). When a local color degree of freedom is introduced the entanglement entropy increases linearly with the size of the block (and $t>1$). The entanglement entropy of half of the chain is tightly bounded by ${ n}\log s$ where $n$ is the size of the block, and $s$ is the number of colors. Our chain fosters a new example for a significant boost to entropy and for the existence of the associated critical rainbow phase where the entanglement entropy scales with volume that has recently been discovered in Zhang et al. (arXiv:1606.07795)

Published

2016

23. Auxiliary fermion approach to the RIXS spectrum in a doped cuprate

Author

Shi, Yifei, James, Andrew, Demler, Eugene, and Klich, Israel

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity

Abstract

We describe a method for calculating the resonant inelastic X-ray scattering (RIXS) response---including the dynamics of the transient core hole---of many-body systems with non-trivial gap structure encoded in their single particle Green's function. Our approach introduces auxiliary fermions in order to obtain a form amenable to the determinant method of Benjamin et al. [PRL 112 247002 (2014)], and is applicable to systems where interactions are most strongly felt through a renormalization of the single particle propagator. As a test case we consider the Yang Rice Zhang ansatz describing cuprate phenomena in the underdoped `pseudogap' regime, and show that including the core hole dynamics pushes the RIXS peaks towards higher energy transfer, improving agreement with experiments., Comment: Significantly rewritten, including elucidating the connection to previous calculations that do not include the core hole. Figures have also been updated

Published

2016

24. Quantum phase transition from bounded to extensive entanglement entropy in a frustration-free spin chain

Author

Zhang, Zhao, Ahmadain, Amr, and Klich, Israel

Subjects

Quantum Physics, Condensed Matter - Statistical Mechanics, Mathematical Physics

Abstract

We introduce a continuous family of frustration-free Hamiltonians with exactly solvable ground states. We prove that the {ground state of our model is non-degenerate and exhibits} a novel quantum phase transition from bounded entanglement entropy to a massively entangled state with volume entropy scaling. The ground state may be interpreted as a deformation away from the uniform superposition of colored Motzkin paths, showed by Movassagh and Shor to have a large (square-root) but sub-extensive scaling of entanglement into a state with an extensive entropy.

Published

2016

25. Superconducting pairing in resonant inelastic X-ray scattering

Author

Shi, Yifei, Benjamin, David, Demler, Eugene, and Klich, Israel

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Strongly Correlated Electrons

Abstract

We develop a method to study the effect of the superconducting transition on resonant inelastic X-ray scattering (RIXS) signal in superconductors with an order parameter with an arbitrary symmetry within a quasiparticle approach. As an example, we compare the direct RIXS signal below and above the superconducting transition for p-wave type order parameters. For a p-wave order parameter with a nodal line, we show that, counterintuitively, the effect of the gap is most noticeable for momentum transfers in the nodal direction. This phenomenon may be naturally explained as a type of nesting effect.

Published

2015

26. Spin Jam: a quantum-fluctuation-induced glassy state of a frustrated magnet

Author

Yang, Junjie, Samarakoon, Anjana, Dissanayake, Sachith, Ueda, Hiroaki, Klich, Israel, Iida, Kazuki, Pajerowski, Daniel, Butch, Nicholas P., Huang, Q., Copley, John R. D., and Lee, Seung-Hun

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Since the discovery of spin glasses in dilute magnetic systems, their study has been largely focused on understanding randomness and defects as the driving mechanism. The same paradigm has also been applied to explain glassy states found in dense frustrated systems. Recently, however, it has been theoretically suggested that different mechanisms, such as quantum fluctuations and topological features, may induce glassy states in defect-free spin systems, far from the conventional dilute limit. Here we report experimental evidence for the existence of a glassy state, that we call a spin jam, in the vicinity of the clean limit of a frustrated magnet, which is insensitive to a low concentration of defects. We have studied the effect of impurities on SrCr9pGa12-9pO19 (SCGO(p)), a highly frustrated magnet, in which the magnetic Cr3+ (s=3/2) ions form a quasi-two-dimensional triangular system of bi-pyramids. Our experimental data shows that as the nonmagnetic Ga3+ impurity concentration is changed, there are two distinct phases of glassiness: a distinct exotic glassy state, which we call a "spin jam", for high magnetic concentration region (p>0.8) and a cluster spin glass for lower magnetic concentration, (p<0.8). This observation indicates that a spin jam is a unique vantage point from which the class of glassy states in dense frustrated magnets can be understood., Comment: Published as Proc. Natl. Acad. Sci. USA, doi:10.1073/pnas.1503126112

Published

2015

27. Resonant inelastic x-ray scattering as a probe of band structure effects in cuprates

Author

Kanász-Nagy, Márton, Shi, Yifei, Klich, Israel, and Demler, Eugene A.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Other Condensed Matter

Abstract

We analyze within quasi-particle theory a recent resonant inelastic x-ray scattering (RIXS) experiment on $\mathrm{YBa_2Cu_3O_{6+x}}$ with the incoming photon energy detuned at several values from the resonance maximum [Minola et al., Phys. Rev. Lett. 114, 217003 (2015)]. Surprisingly, the data shows much weaker dependence on detuning than expected from recent measurements on a different cuprate superconductor, $\mathrm{Bi_2Sr_2CuO_{6+x}}$ [Guarise et al., Nat. Commun. 5, 5760 (2014)]. We demonstrate here, that this discrepancy, originally attributed to collective magnetic excitations, can be understood in terms of the differences between the band structures of these materials. We find good agreement between theory and experiment over a large range of dopings, both in the underdoped and in the overdoped regime. Moreover, we demonstrate that the RIXS signal depends sensitively on excitations at energies well above the Fermi surface, that are inaccessible to traditionally used band structure probes, such as angle-resolved photemisson spectroscopy. This makes RIXS a powerful probe of band structure, not suffering from surface preparation problems and small sample sizes, making it potentially applicable to a number of cuprate materials.

Published

2015

28. Closed hierarchies and non-equilibirum steady states of driven systems

Author

Klich, Israel

Subjects

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

Abstract

We present a class of tractable non-equilibrium dynamical quantum systems which includes combinations of injection, detection and extraction of particles interspersed by unitary evolution. We show how such operations generate a hierarchy of equations tying lower correlation functions with higher order ones. The hierarchy closes for particular choices of measurements and leads to a rich class of evolutions whose long time behavior can be simulated efficiently. In particular, we use the method to describe the dynamics of current generation through a generalized quantum exclusion process, and exhibit an explicit formula for the long time energy distribution in the limit of weak driving., Comment: final version, additional operation of soft particle injection/extraction added

Published

2015

29. Entanglement Hamiltonians for chiral fermions with zero modes

Author

Klich, Israel, Vaman, Diana, and Wong, Gabriel

Subjects

Condensed Matter - Statistical Mechanics, High Energy Physics - Theory

Abstract

In this Letter we study the effect of topological zero modes on entanglement Hamiltonians and entropy of free chiral fermion systems in (1+1)d. We show how Riemann-Hilbert solutions combined with finite rank perturbation theory allow us to obtain explicit expressions for entanglement Hamiltonians. We consider both chiral Majorana and Dirac fermions, and explore the effects of boundary conditions (periodic/anti-periodic for Majorana and generic for Dirac) and associated zero modes on entanglement. In the periodic sector, we derive explicitly the non-local contribution to the entanglement Hamiltonian due to the zero mode, and show an exact expression for the change in entanglement entropy due to the zero mode., Comment: typos fixed

Published

2015

30. Entanglement asymmetry and quantum Mpemba effect in the XY spin chain

Author

Murciano, Sara, primary, Ares, Filiberto, additional, Klich, Israel, additional, and Calabrese, Pasquale, additional

Published

2024

31. Probing Competing and Intertwined Orders with Resonant Inelastic x-ray Scattering in the Hole-Doped Cuprates

Author

Benjamin, David, Klich, Israel, and Demler, Eugene

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

We develop a formalism to study indirect resonant inelastic x-ray scattering (RIXS) in systems with itinerant electrons, accounting for the attraction between valence electrons and the positively-charged core hole exactly, and apply this formalism to the hole-doped cuprate superconductors. We focus on the relationship between RIXS lineshapes and band structure, including broken symmetries. We show that RIXS is capable of distinguishing between competing order parameters, establishing it as a useful probe of the pseudogap phase., Comment: 8 pages

Published

2014

32. Fluctuations and Entanglement spectrum in quantum Hall states

Author

Petrescu, Alexandru, Song, H. Francis, Rachel, Stephan, Ristivojevic, Zoran, Flindt, Christian, Laflorencie, Nicolas, Klich, Israel, Regnault, Nicolas, and Hur, Karyn Le

Subjects

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

Abstract

The measurement of quantum entanglement in many-body systems remains challenging. One experimentally relevant fact about quantum entanglement is that in systems whose degrees of freedom map to free fermions with conserved total particle number, exact relations hold relating the Full Counting Statistics associated with the bipartite charge fluctuations and the sequence of R\' enyi entropies. We draw a correspondence between the bipartite charge fluctuations and the entanglement spectrum, mediated by the R\' enyi entropies. In the case of the integer quantum Hall effect, we show that it is possible to reproduce the generic features of the entanglement spectrum from a measurement of the second charge cumulant only. Additionally, asking whether it is possible to extend the free fermion result to the $\nu=1/3$ fractional quantum Hall case, we provide numerical evidence that the answer is negative in general. We further address the problem of quantum Hall edge states described by a Luttinger liquid, and derive expressions for the spectral functions of the real space entanglement spectrum at a quantum point contact realized in a quantum Hall sample., Comment: Final Version. Invited Article, for Special Issue of JSTAT on "Quantum Entanglement in Condensed Matter Physics"

Published

2014

33. A note on the Full Counting Statistics of paired fermions

Author

Klich, Israel

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Mathematical Physics

Abstract

We study the trace of the exponentials of general fermion bi-linears, including pairing terms, and including non Hermitian forms. In particular, we give elementary derivations for determinant and pfaffian formulae for such traces, and use these to obtain general expressions for the full counting statistics in states associated with quadratic Hamiltonians including BCS-like pairing terms and fermion parity in a prescribed region or set of modes. We also derive pfaffian expressions for state overlaps and counting statistics in states built out of the vacuum by creation of pairs of particles.

Published

2014

34. Quasiparticle Theory of Resonant Inelastic X-ray Scattering in high-T$_c$ cuprates

Author

Benjamin, David, Klich, Israel, and Demler, Eugene

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Strongly Correlated Electrons

Abstract

We develop a formalism for calculating resonant inelastic x-ray scattering (RIXS) spectra in systems of itinerant electrons with arbitrary band structures, accounting for the effect of the positively-charged core hole exactly. We apply this formalism to the cuprate superconductors and obtain quantitative agreement with experimental data over a wide range of dopings. We reproduce the dispersing peaks and non-trivial polarization dependence found in RIXS experiments on several materials. Thus we demonstrate that features previously attributed to collective magnetic modes can be explained by band structure alone., Comment: 6 pages, 3 figures, 2 supplements

Published

2013

35. Hermitian and non-Hermitian thermal Hamiltonians

Author

Feiguin, Adrian E. and Klich, Israel

Subjects

Condensed Matter - Statistical Mechanics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Computational Physics

Abstract

Thermal density matrices can be described by a pure quantum state within the thermofield formalism. Here we show how to construct a class of Hamiltonians realizing a thermofield state as their ground state. These Hamiltonians are frustration-free, and can be Hermitian or non-Hermitian, allowing one to use ground-state methods to understand the thermodynamic properties of the system. In particular this approach gives an explicit mapping of thermal phase transitions into quantum phase transitions. In the non-Hermitian case, the quantum phase transition is not accompanied by a change in the spectrum of the Hamiltonian, which remains gapped. We illustrate these ideas for the classical 2D Ising model.

Published

2013

36. A non-perturbative expression for the transmission through a leaky chiral edge mode

Author

Kim, Kun W., Klich, Israel, and Refael, Gil

Subjects

Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Chiral edge modes of topological insulators and Hall states exhibit non-trivial behavior of conductance in the presence of impurities or additional channels. We will present a simple formula for the conductance through a chiral edge mode coupled to a disordered bulk. For a given coupling matrix between the chiral mode and bulk modes, and a Green function matrix of bulk modes in real space, the renormalized Green function of the chiral mode is expressed in closed form as a ratio of determinants. We demonstrate the usage of the formula in two systems: i) a 1d wire with random onsite impurity potentials for which we found the disorder averaging is made simpler with the formula, and ii) a quantum Hall fluid with impurities in the bulk for which the phase picked up by the chiral mode due to the scattering with the impurities can be conveniently estimated.

Published

2013

37. Entanglement Temperature and Entanglement Entropy of Excited States

Author

Wong, Gabriel, Klich, Israel, Zayas, Leopoldo A. Pando, and Vaman, Diana

Subjects

High Energy Physics - Theory, Condensed Matter - Statistical Mechanics, Quantum Physics

Abstract

We derive a general relation between the ground state entanglement Hamiltonian and the physical stress tensor within the path integral formalism. For spherical entangling surfaces in a CFT, we reproduce the \emph{local} ground state entanglement Hamiltonian derived by Casini, Huerta and Myers. The resulting reduced density matrix can be characterized by a spatially varying "entanglement temperature." Using the entanglement Hamiltonian, we calculate the first order change in the entanglement entropy due to changes in conserved charges of the ground state, and find a local first law-like relation for the entanglement entropy. Our approach provides a field theory derivation and generalization of recent results obtained by holographic techniques. However, we note a discrepancy between our field theoretically derived results for the entanglement entropy of excited states with a non-uniform energy density and current holographic results in the literature. Finally, we give a CFT derivation of a set of constraint equations obeyed by the entanglement entropy of excited states in any dimension. Previously, these equations were derived in the context of holography., Comment: 17 pages, 3 figures. Typo fixed in eq. (III.12) and constraint equation (VI.18) added generalizing previous result to higher dimensions.Some references added

Published

2013

38. Closed hierarchies and non-equilibrium steady states of driven systems

Author

Klich, Israel

Published

2019

39. Full counting statistics and the Edgeworth series for matrix product states

Author

Shi, Yifei and Klich, Israel

Subjects

Condensed Matter - Statistical Mechanics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We consider full counting statistics of spin in matrix product states. In particular, we study the approach to gaussian distribution for magnetization. We derive the asymptotic corrections to the central limit theorem for magnetization distribution for finite but large blocks in analogy to the Edgeworth series. We also show how central limit theorem like behavior is modified for certain states with topological characteristics such as the AKLT state.

Published

2012

40. Radiation matter entanglement

Author

Klich, Israel

Subjects

Quantum Physics, Condensed Matter - Statistical Mechanics, High Energy Physics - Theory

Abstract

The quantization of the electromagnetic field in the presence of material bodies, at zero temperature is considered. It is shown that a dielectric does not act as thermal bath for the field and yields a non-trivial non-thermal mixed state of the field. The properties of this state and its entropy are studied. The dependence of the second Renyi entropy of the field on the distance between dispersive objects is shown to decay as R^{-4} for generic bodies., Comment: arXiv admin note: text overlap with arXiv:1109.2610

Published

2012

41. On the entanglement of a quantum field with a dispersive medium

Author

Klich, Israel

Subjects

Quantum Physics, Condensed Matter - Statistical Mechanics, High Energy Physics - Theory

Abstract

In this Letter we study the entanglement of a quantum radiation field interacting with a dielectric medium. In particular, we describe the quantum mixed state of a field interacting with a dielectric through plasma and Drude models and show that these generate very different entanglement behavior, as manifested in the entanglement entropy of the field. We also present a formula for a "Casimir" entanglement entropy, i.e., the distance dependence of the field entropy. Finally, we study a toy model of the interaction between two plates. In this model, the field entanglement entropy is divergent; however, as in the Casimir effect, its distance-dependent part is finite, and the field matter entanglement is reduced when the objects are far., Comment: Final published PRL version

Published

2011

42. Bipartite Fluctuations as a Probe of Many-Body Entanglement

Author

Song, H. Francis, Rachel, Stephan, Flindt, Christian, Klich, Israel, Laflorencie, Nicolas, and Hur, Karyn Le

Subjects

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

Abstract

We investigate in detail the behavior of the bipartite fluctuations of particle number $\hat{N}$ and spin $\hat{S}^z$ in many-body quantum systems, focusing on systems where such U(1) charges are both conserved and fluctuate within subsystems due to exchange of charges between subsystems. We propose that the bipartite fluctuations are an effective tool for studying many-body physics, particularly its entanglement properties, in the same way that noise and Full Counting Statistics have been used in mesoscopic transport and cold atomic gases. For systems that can be mapped to a problem of non-interacting fermions we show that the fluctuations and higher-order cumulants fully encode the information needed to determine the entanglement entropy as well as the full entanglement spectrum through the R\'{e}nyi entropies. In this connection we derive a simple formula that explicitly relates the eigenvalues of the reduced density matrix to the R\'{e}nyi entropies of integer order for any finite density matrix. In other systems, particularly in one dimension, the fluctuations are in many ways similar but not equivalent to the entanglement entropy. Fluctuations are tractable analytically, computable numerically in both density matrix renormalization group and quantum Monte Carlo calculations, and in principle accessible in condensed matter and cold atom experiments. In the context of quantum point contacts, measurement of the second charge cumulant showing a logarithmic dependence on time would constitute a strong indication of many-body entanglement., Comment: 30 pages + 25 pages supplementary material

Published

2011

43. Edge modes in band topological insulators

Author

Fidkowski, Lukasz, Jackson, T. S., and Klich, Israel

Subjects

Condensed Matter - Strongly Correlated Electrons, Quantum Physics

Abstract

We characterize gapless edge modes in translation invariant topological insulators. We show that the edge mode spectrum is a continuous deformation of the spectrum of a certain gluing function defining the occupied state bundle over the Brillouin zone (BZ). Topologically non-trivial gluing functions, corresponding to non-trivial bundles, then yield edge modes exhibiting spectral flow. We illustrate our results for the case of chiral edge states in two dimensional Chern insulators, as well as helical edges in quantum spin Hall states., Comment: 4 pages, 2 figures; v4 minor changes

Published

2011

44. Entanglement from Charge Statistics: Exact Relations for Many-Body Systems

Author

Song, H. Francis, Flindt, Christian, Rachel, Stephan, Klich, Israel, and Hur, Karyn Le

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

We present exact formulas for the entanglement and R\'{e}nyi entropies generated at a quantum point contact (QPC) in terms of the statistics of charge fluctuations, which we illustrate with examples from both equilibrium and non-equilibrium transport. The formulas are also applicable to groundstate entanglement in systems described by non-interacting fermions in any dimension, which in one dimension includes the critical spin-1/2 XX and Ising models where conformal field theory predictions for the entanglement and R\'{e}nyi entropies are reproduced from the full counting statistics. These results may play a crucial role in the experimental detection of many-body entanglement in mesoscopic structures and cold atoms in optical lattices.

Published

2010

45. Birman-Schwinger and the number of Andreev states in BCS superconductors

Author

Klich, Israel

Subjects

Condensed Matter - Superconductivity, Mathematical Physics

Abstract

The number of bound states due to inhomogeneities in a BCS superconductor is usually established either by variational means or via exact solutions of particularly simple, symmetric perturbations. Here we propose estimating the number of sub-gap states using the Birman-Schwinger principle. We show how to obtain upper bounds on the number of sub-gap states for small normal regions and derive a suitable Cwikel-Lieb-Rozenblum inequality. We also estimate the number of such states for large normal regions using high dimensional generalizations of the Szego theorem. The method works equally well for local inhomogeneities of the order parameter and for external potentials., Comment: Final version to appear in Phys Rev B

Published

2010

46. Lieb-Robinson bounds for commutator-bounded operators

Author

Prémont-Schwarz, Isabeau, Hamma, Alioscia, Klich, Israel, and Markopoulou-Kalamara, Fotini

Subjects

Quantum Physics, Condensed Matter - Strongly Correlated Electrons, Mathematical Physics

Abstract

We generalize the Lieb-Robinson theorem to systems whose Hamiltonian is the sum of local operators whose commutators are bounded., Comment: 5 pages, minor editorial changes

Published

2009

47. On the stability of topological phases on a lattice

Author

Klich, Israel

Subjects

Quantum Physics, Condensed Matter - Other Condensed Matter, Mathematical Physics

Abstract

We study the stability of anyonic models on lattices to perturbations. We establish a cluster expansion for the energy of the perturbed models and use it to study the stability of the models to local perturbations. We show that the spectral gap is stable when the model is defined on a sphere, so that there is no ground state degeneracy. We then consider the toric code Hamiltonian on a torus with a class of abelian perturbations and show that it is stable when the torus directions are taken to infinity simultaneously, and is unstable when the thin torus limit is taken.

Published

2009

48. Dispersion interaction between crossed conducting wires

Author

Dobson, John F., Gould, Timothy, and Klich, Israel

Subjects

Condensed Matter - Other Condensed Matter

Abstract

We compute the $T=0K$ Van der Waals (nonretarded Casimir) interaction energy $E$ between two infinitely long, crossed conducting wires separated by a minimum distance $D$ much greater than their radius. We find that, up to a logarithmic correction factor, $E\propto -D^{-1}| \sin \theta | ^{-1}f(\theta)$ where $f(\theta)$ is a smooth bounded function of the angle $\theta$ between the wires. We recover a conventional result of the form $E\propto -D^{-4}|\sin\theta | ^{-1}g(\theta)$ when we include an electronic energy gap in our calculation. Our prediction of gap-dependent energetics may be observable experimentally for carbon nanotubes, either via AFM detection of the vdW force or torque, or indirectly via observation of mechanical oscillations. This shows that strictly parallel wires, as assumed in previous predictions, are not needed to see a novel effect of this type., Comment: 4 pp, 1 fig, 1 table

Published

2009

49. Many-Body Entanglement: a New Application of the Full Counting Statistics

Author

Klich, Israel and Levitov, Leonid

Subjects

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

Abstract

Entanglement entropy is a measure of quantum correlations between separate parts of a many-body system, which plays an important role in many areas of physics. Here we review recent work in which a relation between this quantity and the Full Counting Statistics description of electron transport was established for noninteracting fermion systems. Using this relation, which is of a completely general character, we discuss how the entanglement entropy can be directly measured by detecting current fluctuations in a driven quantum system such as a quantum point contact., Comment: 8 pgs, 4 fgs

Published

2009

50. Measurement-induced chirality: Diffusion and disorder

Author

Khor, Brian J. J., primary, Wampler, Matthew, additional, Refael, Gil, additional, and Klich, Israel, additional

Published

2023