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364. Symmetry protection of topological phases in one-dimensional quantum spin systems.

Author

Poiimann, Frank, Berg, Erez, Turner, Ari M., and Osliikawu, Masaki

Subjects
*SYMMETRY (Physics), *QUANTUM theory, *NUCLEAR spin, *TOPOLOGY, *TIME reversal, *GROUP theory, *NUMERICAL analysis
Abstract

We discuss the characterization and stability of the Haldane phase in integer spin chains on the basis of simple, physical arguments. We find that an odd-5 Haldane phase is a topologically nontrivial phase which is protected by any one of the following three global symmetries: (i) the dihedral group of n rotations about the x, y, and z axes, (ii) time-reversal symmetry Sx,y,z → --Sx,y,z, and (iii) link inversion symmetry (reflection about a bond center), consistent with previous results [Phys. Rev. B 81,064439 (2010)]. On the other hand, an even-5 Haldane phase is not topologically protected (i.e., it is indistinct from a trivial, site-factorizable phase). We show some numerical evidence that supports these claims, using concrete examples. [ABSTRACT FROM AUTHOR]

Published
2012
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365. Frustrated Quantum Ising Spins Simulated by Spinless Bosons in a Tilted Lattice: From a Quantum Liquid to Antiferromagnetic Order

Author

Sachdev, Subir, Pielawa, Susanne, and Berg, Erez

Subjects
quantum gases
Abstract

We study spinless bosons in a decorated square lattice with a near-diagonal tilt. The resonant subspace of the tilted Mott insulator is described by an effective Hamiltonian of frustrated quantum Ising spins on a nonbipartite lattice. This generalizes an earlier proposal for the unfrustrated quantum Ising model in one dimension which was realized in a recent experiment on ultracold \(^{87}Rb\) atoms in an optical lattice. Very close to diagonal tilt, we find a quantum liquid state which is continuously connected to the paramagnet. Frustration can be reduced by increasing the tilt angle away from the diagonal, and the system undergoes a transition to an antiferromagnetically ordered state. Using quantum Monte Carlo simulations and exact diagonalization, we find that for realistic system sizes the antiferromagnetic order appears to be quasi-one-dimensional, however, in the thermodynamic limit the order is two-dimensional., Physics

Published
2012
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366. Topological Characterization of Periodically-Driven Quantum Systems

Author

Rudner, Mark, Kitagawa, Takuya, Berg, Erez, and Demler, Eugene A.

Abstract

Topological properties of physical systems can lead to robust behaviors that are insensitive to microscopic details. Such topologically robust phenomena are not limited to static systems but can also appear in driven quantum systems. In this paper, we show that the Floquet operators of periodically driven systems can be divided into topologically distinct (homotopy) classes, and give a simple physical interpretation of this classification in terms of the spectra of Floquet operators. Using this picture, we provide an intuitive understanding of the well-known phenomenon of quantized adiabatic pumping. Systems whose Floquet operators belong to the trivial class simulate the dynamics generated by time-independent Hamiltonians, which can be topologically classified according to the schemes developed for static systems. We demonstrate these principles through an example of a periodically driven two--dimensional hexagonal lattice model which exhibits several topological phases. Remarkably, one of these phases supports chiral edge modes even though the bulk is topologically trivial., Physics

Published
2010
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367. Exploring Topological Phases With Quantum Walks

Author

Rudner, Mark, Kitagawa, Takuya, Berg, Erez, and Demler, Eugene A.

Abstract

The quantum walk was originally proposed as a quantum mechanical analogue of the classical random walk, and has since become a powerful tool in quantum information science. In this paper, we show that discrete time quantum walks provide a versatile platform for studying topological phases, which are currently the subject of intense theoretical and experimental investigation. In particular, we demonstrate that recent experimental realizations of quantum walks simulate a non-trivial one dimensional topological phase. With simple modifications, the quantum walk can be engineered to realize all of the topological phases which have been classified in one and two dimensions. We further discuss the existence of robust edge modes at phase boundaries, which provide experimental signatures for the non-trivial topological character of the system., Physics

Published
2010
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368. The unreasonable effectiveness of Eliashberg theory for pairing of non-Fermi liquids.

Author

Chowdhury, Debanjan and Berg, Erez

Subjects
*FERMI liquids, *MANY-body problem, *FERMI energy, *QUASIPARTICLES, *SUPERCONDUCTIVITY, *LIQUIDS, *FERMIONS
Abstract

The paradigmatic Migdal–Eliashberg theory of the electron–phonon problem is central to the understanding of superconductivity in conventional metals. This powerful framework is justified by the smallness of the Debye frequency relative to the Fermi energy, and allows an enormous simplification of the full many-body problem. However, superconductivity is found also in many families of strongly-correlated materials, in which there is no a priori justification for the applicability of Eliashberg theory. In these systems, superconductivity emerges out of an anomalous metallic state, calling for a new theoretical framework to describe pairing out of a non-Fermi liquid. In this article, we review two model systems in which such behavior is found: a Fermi sea coupled to gapless bosonic fluctuations, and a system of fermions with local, strongly frustrated interactions. In both models, there is a well-defined limit in which the Eliashberg equations are asymptotically exact even in the strongly coupled regime. These models thus provide tractable examples of how superconductivity can emerge in the absence of coherent electronic quasiparticles; they also demonstrate the surprisingly wide applicability of the Eliashberg formalism, well beyond the conventional regime for which it was originally designed. [ABSTRACT FROM AUTHOR]

Published
2020
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369. Proposal for realizing anomalous Floquet insulators via Chern band annihilation

Author

Zhang, Carolyn, Holder, Tobias, Lindner, Netanel H., Rudner, Mark, and Berg, Erez

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics, Strongly Correlated Electrons (cond-mat.str-el), Mesoscale and Nanoscale Physics (cond-mat.mes-hall), General Physics and Astronomy, FOS: Physical sciences
Abstract

Two-dimensional periodically driven systems can host an unconventional topological phase unattainable for equilibrium systems, termed the Anomalous Floquet-Anderson insulator (AFAI). The AFAI features a quasi-energy spectrum with chiral edge modes and a fully localized bulk, leading to non-adiabatic but quantized charge pumping. Here, we show how such a Floquet phase can be realized in a driven, disordered Quantum Anomalous Hall insulator, which is assumed to have two critical energies where the localization length diverges, carrying states with opposite Chern numbers. Driving the system at a frequency close to resonance between these two energies localizes the critical states and annihilates the Chern bands, giving rise to an AFAI phase. We exemplify this principle by studying a model for a driven, magnetically doped topological insulator film, where the annihilation of the Chern bands and the formation of the AFAI phase is demonstrated using the rotating wave approximation. This is complemented by a scaling analysis of the localization length for two copies of a quantum Hall network model with a tunable coupling between them. We find that by tuning the frequency of the driving close to resonance, the driving strength required to stabilize the AFAI phase can be made arbitrarily small., Comment: 12 pages + appendix, 12 figures

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370. Effects of order parameter self-consistency in a s± - s junction.

Author

Rodríguez-Mota, Rosa, Berg, Erez, and Pereg-Barnea, T.

Subjects
*IRON compounds, *SUPERCONDUCTORS, *JOSEPHSON effect
Abstract

The properties of Josephson tunneling between a single-band s-wave superconductor and a two-band s± superconductor are studied, in relation to recent experiments involving iron-based superconductors. We study both a single junction and a loop consisting of two junctions. In both cases, the relative phase between the order parameters of the two superconductors is tuned and the energy of the system is calculated. In a single junction, we find four types of behaviors characterized by the location of minima in the energy/phase relations. These phases include a newly found double minimum junction, which appears only when the order parameters are treated self-consistently. We analyze the loop geometry setup in light of our results for a single junction, where the phase difference in the junctions is controlled by a threaded flux. We find four types of energy/flux relations. These include states for which the energy is minimized when the threaded flux is an integer or half-integer number of flux quanta, a time reversal broken state and a metastable state. [ABSTRACT FROM AUTHOR]

Published
2016
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371. Fluctuation and strain effects in a chiral p-wave superconductor.

Author

Fischer, Mark H. and Berg, Erez

Subjects
*SUPERCONDUCTORS, *FLUCTUATIONS (Physics), *SYMMETRY breaking
Abstract

For a tetragonal material, order parameters of px and py symmetry are related by rotation and hence have the same Tc at a mean-field level. This degeneracy can be lifted by a symmetry-breaking field, such as (uniaxial) in-plane strain, such that at Tc, the order parameter is only of px or py symmetry. Only at a lower temperature also the respective other order parameter condenses to form a chiral p-wave state. At the mean-field level, the derivative of Tc with strain is discontinuous at zero strain. We analyze the consequences of (thermal) fluctuations on the strain-temperature phase diagram within a Ginzburg-Landau approach. We find that the order-parameter fluctuations can drive the transition to be weakly first order, rounding off this discontinuity. We discuss the possibility of a second-order transition into a nonsuperconducting time-reversal-symmetry-breaking phase and consequences for the spin-triplet superconductor Sr2RuO4. [ABSTRACT FROM AUTHOR]

Published
2016
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372. T-linear resistivity from magneto-elastic scattering: Application to PdCrO2.

Author

Mendez-Valderrama, J. F., Tulipman, Evyatar, Zhakina, Elina, Mackenzie, Andrew P., Berg, Erez, and Chowdhury, Debanjan

Subjects
*ELECTRON-phonon interactions, *PHONON scattering, *MAGNETIC moments
Abstract

An electronic solid with itinerant carriers and localized magnetic moments represents a paradigmatic strongly correlated system. The electrical transport properties associated with the itinerant carriers, as they scatter off these local moments, have been scrutinized across a number of materials. Here, we analyze the transport characteristics associated with ultraclean PdCrO2 —a quasi-two-dimensional material consisting of alternating layers of itinerant Pd-electrons and Mott-insulating CrO2 layers—which shows a pronounced regime of T-linear resistivity over a wide range of intermediate temperatures. By contrasting these observations to the transport properties in a closely related material PdCoO2, where the CoO2 layers are band-insulators, we can rule out the traditional electron–phonon interactions as being responsible for this interesting regime. We propose a previously ignored electron-magneto-elastic interaction between the Pd-electrons, the Cr local moments and an out-of-plane phonon as the main scattering mechanism that leads to the significant enhancement of resistivity and a T-linear regime in PdCrO2 at temperatures far in excess of the magnetic ordering temperature. We suggest a number of future experiments to confirm this picture in PdCrO2 as well as other layered metallic/Mott-insulating materials. [ABSTRACT FROM AUTHOR]

Published
2023
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373. Investigation of Planckian behavior in a high-conductivity oxide: PdCrO2.

Author

Zhakina, Elina, Daou, Ramzy, Maignan, Antoine, McGuinness, Philippa H., König, Markus, Rosner, Helge, Seo-Jin Kim, Seunghyun Khim, Grasset, Romain, Konczykowski, Marcin, Tulipman, Evyatar, Mendez-Valderrama, Juan Felipe, Chowdhury, Debanjan, Berg, Erez, and Mackenzie, Andrew P.

Subjects
*THERMAL conductivity measurement, *FERMI surfaces, *ELASTIC scattering, *HIGH temperatures
Abstract

The layered delafossite metal PdCrO2 is a natural heterostructure of highly conductive Pd layers Kondo coupled to localized spins in the adjacent Mott insulating CrO2 layers. At high temperatures, T, it has a T-linear resistivity which is not seen in the isostructural but nonmagnetic PdCoO2. The strength of the Kondo coupling is known, as-grown crystals are extremely high purity and the Fermi surface is both very simple and experimentally known. It is therefore an ideal material platform in which to investigate “Planckian metal” physics. We do this by means of controlled introduction of point disorder, measurement of the thermal conductivity and Lorenz ratio, and studying the sources of its high-temperature entropy. The T-linear resistivity is seen to be due mainly to elastic scattering and to arise from a sum of several scattering mechanisms. Remarkably, this sum leads to a scattering rate within 10% of the Planckian value of kBT/ℏ. [ABSTRACT FROM AUTHOR]

Published
2023
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374. Phases of the Infinite U Hubbard Model on Square Lattices.

Author

Li Liu, Hong Yao, Berg, Erez, White, Steven R., and Kivelson, Steven A.

Subjects
*HUBBARD model, *LATTICE theory, *DENSITY matrices, *PHASE diagrams, *FERROMAGNETIC materials, *FERMI liquids
Abstract

We apply the density matrix renormalization group to study the phase diagram of the infinite U Hubbard model on 2- to 6-leg ladders. Where the results are largely insensitive to the ladder width, we consider the results representative of the 2D square lattice. We find a fully polarized ferromagnetic Fermi liquid phase when n, the density of electrons per site, is in the range 1 > n ≳ 0.800. For n = 3/4 we find an unexpected insulating checkerboard phase with coexisting bond-density order with 4 sites per unit cell and block-spin antiferromagnetic order with 8 sites per unit cell. For 3/4 > n, all ladders with width >2 have unpolarized ground states. [ABSTRACT FROM AUTHOR]

Published
2012
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375. Strong-coupling expansion of multi-band interacting models: Mapping onto the transverse-field [formula omitted]-[formula omitted] Ising model.

Author

Wang, Xiaoyu, Christensen, Morten H., Berg, Erez, and Fernandes, Rafael M.

Subjects
*ISING model, *MONTE Carlo method, *SPIN exchange, *HEISENBERG model, *HUBBARD model, *DENSITY matrices
Abstract

We investigate a class of two-dimensional two-band microscopic models in which the inter-band repulsive interactions play the dominant role. We first demonstrate three different schemes of constraining the ratios between the three types of inter-band interactions – density-density, spin exchange, and pair-hopping – that render the model free of the fermionic sign-problem for any filling and, consequently, amenable to efficient Quantum Monte Carlo simulations. We then study the behavior of these sign-problem-free models in the strong-coupling regime. In the cases where spin-rotational invariance is preserved or lowered to a planar symmetry, the strong-coupling ground state is a quantum paramagnet. However, in the case where there is only a residual Ising symmetry, the strong-coupling expansion maps onto the transverse-field J 1 - J 2 Ising model, whose pseudospins are associated with local inter-band magnetic order. We show that by varying the band structure parameters within a reasonable range of values, a variety of ground states and quantum critical points can be accessed in the strong-coupling regime, some of which are not realized in the weak-coupling regime. We compare these results with the case of the single-band Hubbard model, where only intra-band repulsion is present, and whose strong-coupling behavior is captured by a simple Heisenberg model. [ABSTRACT FROM AUTHOR]

Published
2021
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378. Signatures of topological Josephson junctions.

Author

Yang Peng, Pientka, Falko, Berg, Erez, Oreg, Yuval, and von Oppen, Felix

Subjects
*ZEEMAN effect, *JOSEPHSON junctions, *ATOMS in external magnetic fields, *JOSEPHSON effect, *SUPERCONDUCTING quantum interference devices
Abstract

Quasiparticle poisoning and diabatic transitions may significantly narrow the window for the experimental observation of the 4p-periodic dc Josephson effect predicted for topological Josephson junctions. Here, we show that switching-current measurements provide accessible and robust signatures for topological superconductivity which persist in the presence of quasiparticle poisoning processes. Such measurements provide access to the phase-dependent subgap spectrum and Josephson currents of the topological junction when incorporating it into an asymmetric SQUID together with a conventional Josephson junction with large critical current. We also argue that pump-probe experiments with multiple current pulses can be used to measure the quasiparticle poisoning rates of the topological junction. The proposed signatures are particularly robust, even in the presence of Zeeman fields and spin-orbit coupling, when focusing on short Josephson junctions. Finally, we also consider microwave excitations of short topological Josephson junctions which may complement switching-current measurements. [ABSTRACT FROM AUTHOR]

Published
2016
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379. Topology and localization out-of-equilibrium

Author

van Nieuwenburg, Evert P.L., Huber, Sebastian D., and Berg, Erez

Subjects
VIELTEILCHENSYSTEME (QUANTENTHEORIE), Physics, PHYSIK DER KONDENSIERTEN MATERIE, NICHTGLEICHGEWICHTSPROBLEME (THERMODYNAMIK), KOHÄRENTE ZUSTÄNDE (QUANTENTHEORIE), MASCHINELLES LERNEN (KÜNSTLICHE INTELLIGENZ), CONDENSED MATTER PHYSICS, NONEQUILIBRIUM PROBLEMS (THERMODYNAMICS), MANY-BODY SYSTEMS (QUANTUM THEORY), COHERENT STATES (QUANTUM MECHANICS), MACHINE LEARNING (ARTIFICIAL INTELLIGENCE), ddc:530
Abstract

A recent trend in condensed matter physics is that of taking systems out-of-equilibrium. In such a setting, physical phenomena are possible that do not have equilibrium counterparts. Two typical scenarios for non-equilibrium physics are that of open systems, i.e. systems that couple to an environment, and that of quenches, where the system is suddenly taken out-of-equilibrium and its relaxation is studied. The present dissertation addresses three questions, two of which deal with these two scenarios of non-equilibrium situations. The third question is slightly orthogonal, and asks about the potential applications of machine learning to condensed matter physics. As the first question, we asked about the fate of one dimensional symmetry protected topological (SPT) states when coupled to an environment. By showing how to extend the concept of entanglement spectra for pure states to that of mixed states, we were able to identify genuine mixed states with the properties of topologically non-trivial states. Additionally, we showed how to extend the classification scheme of SPT states based on projective symmetry representations to open systems. As an example, we have also considered the evolution of initial states that are topologically non-trivial upon coupling them to an environment. We have found that the topological non-trivial nature of the state dissapears on the way to reaching a steady state. As the second question, we asked about the relaxation to equilibrium of a single spin probe coupled to an environment. We showed that the transient behaviour of the de-coherence of this probe spin can be used to investigate an interacting and disordered spin chain. For weak disorder this spin chain is in a thermalizing phase, whereas for strong disorder the system avoids thermalization and instead forms a many-body localized (MBL) phase. We showed that the de-coherence properties of the spin probe provide an unambiguous signal of the MBL phase. This work provides an important experimental probe for investigating the properties of many-body quantum systems further. For the third question, we considered an equilibrium scenario and asked what potential use a machine learning algorithm can be for such cases. We showed that by compressing the information of the wave function in the form of the entanglement spectrum, it is possible to detect phase transitions using an approach based on artificial neural networks. The application of machine learning techniques to condensed matter physics is a very novel trend, and it is a fast-moving subject. Next to developing our own approach in this dissertation, we provide an overview of the recent works, thereby giving an understanding of the potential uses of machine learning in condensed matter physics. These three projects together, each in their own right, address important questions in condensed matter physics. Each of them deals with a recent topic that is of interest to a broad community, and provides non-trivial results that further these communities.

Published
2016
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380. Fragility of Charge Order Near an Antiferromagnetic Quantum Critical Point.

Author

Xiaoyu Wang, Yuxuan Wang, Schattner, Yoni, Berg, Erez, and Fernandes, Rafael M.

Subjects
*ANTIFERROMAGNETISM, *CRITICAL point (Thermodynamics), *QUANTUM Monte Carlo method
Abstract

We investigate the interplay between charge order and superconductivity near an antiferromagnetic quantum critical point using sign-problem-free Quantum Monte Carlo simulations. We establish that, when the electronic dispersion is particle-hole symmetric, the system has an emergent SU(2) symmetry that implies a degeneracy between d-wave superconductivity and charge order with d-wave form factor. Deviations from particle-hole symmetry, however, rapidly lift this degeneracy, despite the fact that the SU(2) symmetry is preserved at low energies. As a result, we find a strong suppression of charge order caused by the competing, leading superconducting instability. Across the antiferromagnetic phase transition, we also observe a shift in the charge order wave vector from diagonal to axial. We discuss the implications of our results to the universal phase diagram of antiferromagnetic quantum-critical metals and to the elucidation of the charge order experimentally observed in the cuprates. [ABSTRACT FROM AUTHOR]

Published
2018
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381. Nematic Metal in a Multivalley Electron Gas: Variational Monte Carlo Analysis and Application to AlAs.

Author

Valenti A, Calvera V, Kivelson SA, Berg E, and Huber SD

Abstract

The two-dimensional electron gas is of fundamental importance in quantum many-body physics. We study a minimal extension of this model with C_{4} (as opposed to full rotational) symmetry and an electronic dispersion with two valleys with anisotropic effective masses. Electrons in our model interact via Coulomb repulsion, screened by distant metallic gates. Using variational Monte Carlo simulations, we find a broad intermediate range of densities with a metallic valley-polarized, spin-unpolarized ground state. Our results are of direct relevance to the recently discovered "nematic" state in AlAs quantum wells. For the effective mass anisotropy relevant to this system, m_{x}/m_{y}≈5.2, we obtain a transition from an anisotropic metal to a valley-polarized metal at r_{s}≈12 (where r_{s} is the dimensionless Wigner-Seitz radius). At still lower densities, we find a (possibly metastable) valley and spin-polarized state with a reduced electronic anisotropy.

Published
2024
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382. Tunable Non-Fermi Liquid Phase from Coupling to Two-Level Systems.

Author

Bashan N, Tulipman E, Schmalian J, and Berg E

Abstract

We study a controlled large-N theory of electrons coupled to dynamical two-level systems (TLSs) via spatially random interactions. Such a physical situation arises when electrons scatter off low-energy excitations in a metallic glass, such as a charge or stripe glass. Our theory is governed by a non-Gaussian saddle point, which maps to the celebrated spin-boson model. By tuning the coupling strength we find that the model crosses over from a Fermi liquid at weak coupling to an extended region of non-Fermi liquid behavior at strong coupling, and realizes a marginal Fermi liquid at the crossover. Our results are valid for generic space dimensions d>1.

Published
2024
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383. Stoner Ferromagnetism in a Momentum-Confined Interacting 2D Electron Gas.

Author

Antebi O, Stern A, and Berg E

Abstract

In this work we investigate the ground state of a momentum-confined interacting 2D electron gas, a momentum-space analog of an infinite quantum well. The study is performed by combining analytical results with a numerical exact diagonalization procedure. We find a ferromagnetic ground state near a particular electron density and for a range of effective electron (or hole) masses. We argue that this observation may be relevant to the generalized Stoner ferromagnetism recently observed in multilayer graphene systems. The collective magnon excitations exhibit a linear dispersion, which originates from a diverging spin stiffness.

Published
2024
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384. Heat conductance of the quantum Hall bulk.

Author

Melcer RA, Gil A, Paul AK, Tiwari P, Umansky V, Heiblum M, Oreg Y, Stern A, and Berg E

Abstract

The quantum Hall effect is a prototypical realization of a topological state of matter. It emerges from a subtle interplay between topology, interactions and disorder 1-9 . The disorder enables the formation of localized states in the bulk that stabilize the quantum Hall states with respect to the magnetic field and carrier density 3 . Still, the details of the localized states and their contribution to transport remain beyond the reach of most experimental techniques 10-31 . Here we describe an extensive study of the bulk's heat conductance. Using a novel 'multiterminal' short device (on a scale of 10 µm), we separate the longitudinal thermal conductance, [Formula: see text] (owing to the bulk's contribution), from the topological transverse value [Formula: see text] by eliminating the contribution of the edge modes 24 . When the magnetic field is tuned away from the conductance plateau centre, the localized states in the bulk conduct heat efficiently ([Formula: see text]), whereas the bulk remains electrically insulating. Fractional states in the first excited Landau level, such as the [Formula: see text] and [Formula: see text], conduct heat throughout the plateau with a finite [Formula: see text]. We propose a theoretical model that identifies the localized states as the cause of the finite heat conductance, agreeing qualitatively with our experimental findings., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published
2024
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385. [Formula: see text]-linear resistivity from magneto-elastic scattering: Application to PdCrO 2 .

Author

Mendez-Valderrama JF, Tulipman E, Zhakina E, Mackenzie AP, Berg E, and Chowdhury D

Abstract

An electronic solid with itinerant carriers and localized magnetic moments represents a paradigmatic strongly correlated system. The electrical transport properties associated with the itinerant carriers, as they scatter off these local moments, have been scrutinized across a number of materials. Here, we analyze the transport characteristics associated with ultraclean PdCrO[Formula: see text]-a quasi-two-dimensional material consisting of alternating layers of itinerant Pd-electrons and Mott-insulating CrO[Formula: see text] layers-which shows a pronounced regime of T -linear resistivity over a wide range of intermediate temperatures. By contrasting these observations to the transport properties in a closely related material PdCoO[Formula: see text], where the CoO[Formula: see text] layers are band-insulators, we can rule out the traditional electron-phonon interactions as being responsible for this interesting regime. We propose a previously ignored electron-magneto-elastic interaction between the Pd-electrons, the Cr local moments and an out-of-plane phonon as the main scattering mechanism that leads to the significant enhancement of resistivity and a T -linear regime in PdCrO[Formula: see text] at temperatures far in excess of the magnetic ordering temperature. We suggest a number of future experiments to confirm this picture in PdCrO[Formula: see text] as well as other layered metallic/Mott-insulating materials.

Published
2023
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386. A criterion for strange metallicity in the Lorenz ratio.

Author

Tulipman E and Berg E

Abstract

The Wiedemann-Franz (WF) law, stating that the Lorenz ratio L  =  κ /( T σ ) between the thermal and electrical conductivities in a metal approaches a universal constant L 0 = π 2 k B 2 / ( 3 e 2 ) at low temperatures, is often interpreted as a signature of fermionic Landau quasi-particles. In contrast, we show that various models of weakly disordered non-Fermi liquids also obey the WF law at T  → 0. Instead, we propose using the leading low-temperature correction to the WF law, L ( T ) -  L 0 (proportional to the inelastic scattering rate), to distinguish different types of strange metals. As an example, we demonstrate that in a solvable model of a marginal Fermi-liquid, L ( T ) -  L 0  ∝ -  T . Using the quantum Boltzmann equation (QBE) approach, we find analogous behavior in a class of marginal- and non-Fermi liquids with a weakly momentum-dependent inelastic scattering. In contrast, in a Fermi-liquid, L ( T ) -  L 0 is proportional to -  T 2 . This holds even when the resistivity grows linearly with T , due to T  - linear quasi-elastic scattering (as in the case of electron-phonon scattering at temperatures above the Debye frequency). Finally, by exploiting the QBE approach, we demonstrate that the transverse Lorenz ratio, L x y  =  κ x y /( T σ x y ), exhibits the same behavior., Competing Interests: Competing interestsThe authors declare no competing interests., (© The Author(s) 2023.)

Published
2023
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387. Inter-valley coherent order and isospin fluctuation mediated superconductivity in rhombohedral trilayer graphene.

Author

Chatterjee S, Wang T, Berg E, and Zaletel MP

Abstract

Superconductivity was recently discovered in rhombohedral trilayer graphene (RTG) in the absence of a moiré potential. Superconductivity is observed proximate to a metallic state with reduced isospin symmetry, but it remains unknown whether this is a coincidence or a key ingredient for superconductivity. Using a Hartree-Fock analysis and constraints from experiments, we argue that the symmetry breaking is inter-valley coherent (IVC) in nature. We evaluate IVC fluctuations as a possible pairing glue, and find that they lead to chiral unconventional superconductivity when the fluctuations are strong. We further elucidate how the inter-valley Hund's coupling determines the spin-structure of the IVC ground state and breaks the degeneracy between spin-singlet and triplet superconductivity. Remarkably, if the normal state is spin-unpolarized, we find that a ferromagnetic Hund's coupling favors spin-singlet superconductivity, in agreement with experiments. Instead, if the normal state is spin-polarized, then IVC fluctuations lead to spin-triplet pairing., (© 2022. The Author(s).)

Published
2022
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388. Theory of the strange metal Sr 3 Ru 2 O 7 .

Author

Mousatov CH, Berg E, and Hartnoll SA

Abstract

The bilayer perovskite Sr 3 Ru 2 O 7 has been widely studied as a canonical strange metal. It exhibits T -linear resistivity and a T log(1/ T ) electronic specific heat in a field-tuned quantum critical fan. Criticality is known to occur in "hot" Fermi pockets with a high density of states close to the Fermi energy. We show that while these hot pockets occupy a small fraction of the Brillouin zone, they are responsible for the anomalous transport and thermodynamics of the material. Specifically, a scattering process in which two electrons from the large, "cold" Fermi surfaces scatter into one hot and one cold electron renders the ostensibly noncritical cold fermions a marginal Fermi liquid. From this fact the transport and thermodynamic phase diagram is reproduced in detail. Finally, we show that the same scattering mechanism into hot electrons that are instead localized near a 2D van Hove singularity explains the anomalous transport observed in strained Sr 2 RuO 4 ., Competing Interests: The authors declare no competing interest.

Published
2020
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389. Phases of the infinite U Hubbard model on square lattices.

Author

Liu L, Yao H, Berg E, White SR, and Kivelson SA

Abstract

We apply the density matrix renormalization group to study the phase diagram of the infinite U Hubbard model on 2- to 6-leg ladders. Where the results are largely insensitive to the ladder width, we consider the results representative of the 2D square lattice. We find a fully polarized ferromagnetic Fermi liquid phase when n, the density of electrons per site, is in the range 1>n≳0.800. For n=3/4 we find an unexpected insulating checkerboard phase with coexisting bond-density order with 4 sites per unit cell and block-spin antiferromagnetic order with 8 sites per unit cell. For 3/4>n, all ladders with width >2 have unpolarized ground states.

Published
2012
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