Your search keyword '"Bergholtz, Emil J."' showing total 80 results

1. Parafermions in moiré minibands.

Author

Liu, Hui, Perea-Causin, Raul, and Bergholtz, Emil J.

Abstract

Moiré materials provide a remarkably tunable platform for topological and strongly correlated quantum phases of matter. Very recently, the first Abelian fractional Chern insulators (FCIs) at zero magnetic field have been experimentally demonstrated, and it has been theoretically predicted that non-Abelian states with Majorana fermion excitations may be realized in the nearly dispersionless minibands of these systems. Here, we provide telltale evidence based on many-body exact diagonalization for the even more exotic possibility of moiré-based non-Abelian FCIs exhibiting Fibonacci parafermion excitations. In particular, we obtain low-energy quantum numbers, spectral flow, many-body Chern numbers, and entanglement spectra consistent with the Z 3 Read–Rezayi parafermion phase in an exemplary moiré system with tunable quantum geometry. Our results hint towards the robustness of moiré-based parafermions and encourage the pursuit in moiré systems of these non-Abelian quasiparticles that are superior candidates for topological quantum computing. Parafermions hold promise as building blocks for topological quantum computers but have remained experimentally elusive. Here, the authors employ numerical calculations to demonstrate that parafermion excitations can emerge in partially filled moiré minibands of twisted multilayer graphene systems. [ABSTRACT FROM AUTHOR]

Published

2025

2. Corner states of light in photonic waveguides

Author

El Hassan, Ashraf, Kunst, Flore K., Moritz, Alexander, Andler, Guillermo, Bergholtz, Emil J., and Bourennane, Mohamed

Published

2019

3. Nodal phases in non-Hermitian wallpaper crystals.

Author

König, J. Lukas K., Herber, Felix, and Bergholtz, Emil J.

Subjects

WALLPAPER, CRYSTALS, SYMMETRY

Abstract

Symmetry and non-Hermiticity play pivotal roles in photonic lattices. While symmetries, such as parity-time (P T) symmetry, have attracted ample attention, more intricate crystalline symmetries have been neglected in comparison. Here, we investigate the impact of the 17 wallpaper space groups of two-dimensional crystals on non-Hermitian band structures. We show that the non-trivial space group representations enforce degeneracies at high symmetry points and dictate their dispersion away from these points. In combination with either T or P T , the symmorphic p4 mm symmetry and the non-symmorphic p2mg, p2gg, and p4gm symmetries protect exceptional chains intersecting at the pertinent high symmetry points. [ABSTRACT FROM AUTHOR]

Published

2024

4. Non-Hermitian extended midgap states and bound states in the continuum.

Author

Zelenayova, Maria and Bergholtz, Emil J.

Subjects

*BOUND states, *BIORTHOGONAL systems, *TOPOLOGY, *SYMMETRY

Abstract

We investigate anomalous localization phenomena in non-Hermitian systems by solving a class of generalized Su–Schrieffer–Heeger/Rice–Mele models and by relating their provenance to fundamental notions of topology, symmetry-breaking, and biorthogonality. We find two types of bound states in the continuum, both stable even in the absence of chiral symmetry: the first being skin bulk states, which are protected by the spectral winding number. The second type is constituted by boundary modes associated with a quantized biorthogonal polarization. Furthermore, we find an extended state stemming from the boundary state that delocalizes while remaining in the gap at bulk critical points. This state may also delocalize within a continuum of localized (skin) states. These results clarify fundamental aspects of topology and symmetry in light of different approaches to the anomalous non-Hermitian bulk-boundary correspondence and are of direct experimental relevance for mechanical, electrical, and photonic systems. [ABSTRACT FROM AUTHOR]

Published

2024

5. Non-Hermitian Boundary State Distillation with Lossy Waveguides

Author

Cherifi, Walid, Carlström, Johan, Bourennane, Mohamed, and Bergholtz, Emil J.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), FOS: Physical sciences, Quantum Physics (quant-ph), Optics (physics.optics), Physics - Optics

Abstract

The hallmark of topological phases is their exotic boundary states. In a series of remarkable experiments it has been shown that classical analogues of these states can be engineered in arrays of coupled optical waveguides given delicately fine-tuned input light. Here, we introduce and experimentally demonstrate a radically different approach in which a pattern of lossy waveguides distills the boundary states for generic, even defocused, input light, thus fully alleviating the need for fine-tuning. Our "topological distillation" approach is remarkably general: the lossy waveguides amount to an effectively non-Hermitian Hamiltonian, and the corresponding time-evolution (propagation of the light in the waveguides) removes the mundane bulk states of any topological (or trivial) band structure while retaining the intriguing boundary states by virtue of being the unique states with the longest life-time. We experimentally demonstrate the power and versatility of our approach by distilling the edge states in photonic graphene, as well as corner and edge states in non-Hermitian Kagome arrays., 15 pages, 4 figures

Published

2023

6. Experimental Simulation of Symmetry-Protected Higher-Order Exceptional Points with Single Photons

Author

Wang, Kunkun, Xiao, Lei, Lin, Haiqing, Yi, Wei, Bergholtz, Emil J., and Xue, Peng

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), FOS: Physical sciences, Quantum Physics (quant-ph), Optics (physics.optics), Physics - Optics

Abstract

Exceptional points (EPs) of non-Hermitian (NH) systems have recently attracted increasing attention due to their rich phenomenology and intriguing applications. Compared to the predominantly studied second-order EPs, higher-order EPs have been assumed to play a much less prominent role since they generically require the tuning of more parameters. Here we experimentally simulate two-dimensional topological NH band structures using single-photon interferometry, and observe topologically stable third-order EPs obtained by tuning only two real parameters in the presence of symmetry. Focusing on two-dimensional NH system, we demonstrate on two types of third-order EPs, respectively protected by parity-time symmetry and chiral symmetry, and four-fold degeneracies, composed by the non-defective two-fold degeneracies and second-order EPs. Our work reveals the abundant and conceptually richer higher-order EPs protected by symmetries, and offers a versatile platform for further research on topological NH systems., 14 pages, 9 figures

Published

2023

7. Braid Protected Topological Band Structures with Unpaired Exceptional Points

Author

König, J. Lukas K., Yang, Kang, Budich, Jan Carl, and Bergholtz, Emil J.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), FOS: Physical sciences, Mathematical Physics (math-ph), Quantum Physics (quant-ph), Mathematical Physics, Optics (physics.optics), Physics - Optics

Abstract

We demonstrate the existence of topologically stable unpaired exceptional points (EPs), and construct simple non-Hermitian (NH) tight-binding models exemplifying such remarkable nodal phases. While Fermion doubling, i.e. the necessity of compensating the topological charge of a stable nodal point by an anti-dote, rules out a direct counterpart of our findings in the realm of Hermitian semimetals, here we derive how non-commuting braids of complex energy levels may stabilize unpaired EPs. Drawing on this insight, we reveal the occurrence of a single, unpaired EP, manifested as a non-Abelian monopole in the Brillouin zone of a minimal three-band model. This third-order degeneracy cannot be fully gapped by any local perturbation. Instead, it may split into simpler (second-order) degeneracies that can only gap out by pairwise annihilation after having moved around inequivalent large circles of the Brillouin zone. Our results imply the incompleteness of a topological classification based on winding numbers, due to non-Abelian representations of the braid group intertwining three or more complex energy levels., 5+6 pages, 3+2 figures

Published

2022

8. Multiferroicity and Topology in Twisted Transition Metal Dichalcogenides

Author

Abouelkomsan, Ahmed, Bergholtz, Emil J., and Chatterjee, Shubhayu

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science, Strongly Correlated Electrons (cond-mat.str-el), Condensed Matter - Mesoscale and Nanoscale Physics, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences

Abstract

Van der Waals heterostructures have recently emerged as an exciting platform for investigating the effects of strong electronic correlations, including various forms of magnetic or electrical orders. Here, we perform an unbiased exact diagonalization study of the effects of interactions on topological flat bands of twisted transition metal dichalcogenides (TMDs) at odd integer fillings. We find that Chern insulator phases, expected from interaction-induced spin and valley polarization of the bare band structure, are quite fragile, and give way to spontaneous multiferroic order -- coexisting ferroelectricity and ferromagnetism, in presence of long-range Coulomb repulsion. We provide a simple real-space picture to understand the phase diagram as a function of interaction range and strength. Our findings establish twisted TMDs as a novel and highly tunable platform for multiferroicity, with potential applications to electrical control of magnetism., 5 + 4 pages, 6 figures

Published

2022

9. Liouvillian Skin Effect in an Exactly Solvable Model

Author

Yang, Fan, Jiang, Qing-Dong, and Bergholtz, Emil J.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Gases (cond-mat.quant-gas), Mesoscale and Nanoscale Physics (cond-mat.mes-hall), FOS: Physical sciences, Quantum Physics (quant-ph), Condensed Matter - Quantum Gases, Optics (physics.optics), Physics - Optics

Abstract

The interplay between dissipation, topology and sensitivity to boundary conditions has recently attracted tremendous amounts of attention at the level of effective non-Hermitian descriptions. Here we exactly solve a quantum mechanical Lindblad master equation describing a dissipative topological Su-Schrieffer-Heeger (SSH) chain of fermions for both open boundary condition (OBC) and periodic boundary condition (PBC). We find that the extreme sensitivity on the boundary conditions associated with the non-Hermitian skin effect is directly reflected in the rapidities governing the time evolution of the density matrix giving rise to a Liouvillian skin effect. This leads to several intriguing phenomena including boundary sensitive damping behavior, steady state currents in finite periodic systems, and diverging relaxation times in the limit of large systems. We illuminate how the role of topology in these systems differs in the effective non-Hermitian Hamiltonian limit and the full master equation framework., 21 pages, 13 figures, published

Published

2022

10. Effective spin chains for fractional quantum Hall states

Author

Bergholtz, Emil J., Nakamura, Masaaki, and Suorsa, Juha

Published

2011

11. Exceptional dynamics of interacting spin liquids

Author

Yang, Kang, Varjas, Daniel, Bergholtz, Emil J., Morampudi, Sid, and Wilczek, Frank

Subjects

High Energy Physics - Theory, Condensed Matter - Strongly Correlated Electrons, Quantum Physics, Strongly Correlated Electrons (cond-mat.str-el), High Energy Physics - Theory (hep-th), FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

We show that interactions in quantum spin liquids can result in non-Hermitian phenomenology that differs qualitatively from mean-field expectations. We demonstrate this in two prominent cases through the effects of phonons and disorder on a Kitaev honeycomb model. Using analytic and numerical calculations, we show the generic appearance of exceptional points and rings depending on the symmetry of the system. Their existence is reflected in dynamical observables including the dynamic structure function measured in neutron scattering. The results point to new phenomenological features in realizable spin liquids that must be incorporated into the analysis of experimental data and also indicate that spin liquids could be generically stable to wider classes of perturbations., 6+10 pages, 3+4 figure, MIT-CTP/5402

Published

2022

12. Synchronization in epidemic growth and the impossibility of selective containment.

Author

Budich, Jan C and Bergholtz, Emil J

Subjects

*COVID-19 pandemic, *SYNCHRONIZATION, *POPULATION dynamics, *EPIDEMICS, *PANDEMICS

Abstract

Containment, aiming to prevent the epidemic stage of community-spreading altogether, and mitigation, aiming to merely 'flatten the curve' of a wide-ranged outbreak, constitute two qualitatively different approaches to combating an epidemic through non-pharmaceutical interventions. Here, we study a simple model of epidemic dynamics separating the population into two groups, namely a low-risk group and a high-risk group, for which different strategies are pursued. Due to synchronization effects, we find that maintaining a slower epidemic growth behaviour for the high-risk group is unstable against any finite coupling between the two groups. More precisely, the density of infected individuals in the two groups qualitatively evolves very similarly, apart from a small time delay and an overall scaling factor quantifying the coupling between the groups. Hence, selective containment of the epidemic in a targeted (high-risk) group is practically impossible whenever the surrounding society implements a mitigated community-spreading. We relate our general findings to the ongoing COVID-19 pandemic. [ABSTRACT FROM AUTHOR]

Published

2021

13. Transport properties of an interacting Majorana chain

Author

Liu, Zhao, Bergholtz, Emil J., Romito, Alessandro, and Meidan, Dganit

Subjects

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

Abstract

We study a one-dimensional (1D) chain of $2N$ Majorana bound states, which interact through a local quartic interaction. This model describes for example the edge physics of a quasi 1D stack of $2N$ Kitaev chains with modified time-reversal symmetry $T\gamma_iT^{-1}=\gamma_i$, which precludes the presence of quadratic coupling. The ground state of our 1D Majorana chain displays a four-fold periodicity in $N$, corresponding to the four distinct topological classes of the stacked Kitaev chains. We analyze the transport properties of the 1D Majorana chain, when probed by local conductors located at its ends. We find that for finite but large $N$, the scattering matrix partially reflects the four-fold periodicity, and the chain exhibits strikingly different transport properties for different chain lengths. In the thermodynamic limit, the 1D Majorana chain hosts a robust many-body zero mode, which indicates that the corresponding stacked two-dimensional bulk system realizes a weak topological phase., Comment: 9 pages, 5 figures

Published

2017

14. Recent developments in fractional Chern insulators

Author

Liu, Zhao and Bergholtz, Emil J.

Published

2015

15. Entanglement Scaling of Fractional Quantum Hall states through Geometric Deformations

Author

Laeuchli, Andreas, Bergholtz, Emil J., and Haque, Masudul

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

We present a new approach to obtaining the scaling behavior of the entanglement entropy in fractional quantum Hall states from finite-size wavefunctions. By employing the torus geometry and the fact that the torus aspect ratio can be readily varied, we can extract the entanglement entropy of a spatial block as a continuous function of the block boundary. This approach allows us to extract the topological entanglement entropy with an accuracy superior to what is possible on the spherical or disc geometry, where no natural continuously variable parameter is available. Other than the topological information, the study of entanglement scaling is also useful as an indicator of the difficulty posed by fractional quantum Hall states for various numerical techniques., 16 pages, 8 figures, published version

Published

2010

16. A simple view on the quantum Hall system

Author

Bergholtz, Emil J. and Karlhede, Anders

Subjects

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

Abstract

The physics of the quantum Hall system becomes very simple when studied on a thin torus. Remarkably, however, the very rich structure still exists in this limit and there is a continuous route to the bulk system. Here we review recent progress in understanding various features of the quantum Hall system in terms of a simple one-dimensional model corresponding to the thin torus., Contribution to the book of the Les Houches school on Quantum Magnetism, 2006

Published

2006

17. Quantum critical exponents for a disordered three-dimensional Weyl node.

Author

Sbierski, Björn, Bergholtz, Emil J., and Brouwer, Piet W.

Subjects

*QUANTUM phase transitions, *ELECTRONIC band structure, *PHOTONIC crystal spectra, *METAL-insulator transitions, *WEYL fermions, *CHEMICAL potential, *CRITICAL point (Thermodynamics)

Abstract

Three-dimensional Dirac and Weyl semimetals exhibit a disorder-induced quantum phase transition between a semimetallic phase at weak disorder and a diffusive-metallic phase at strong disorder. Despite considerable effort, both numerically and analytically, the critical exponents v and z of this phase transition are not known precisely. Here we report a numerical calculation of the critical exponent v = 1.47 ± 0.03 using a minimal single-Weyl node model and a finite-size scaling analysis of conductance. Our high-precision numerical value for v is incompatible with previous numerical studies on tight-binding models and with one- and two-loop calculations in an expansion scheme. We further obtain z = 1.49 ± 0.02 from the scaling of the conductivity with chemical potential. [ABSTRACT FROM AUTHOR]

Published

2015

18. A Simple View on the Quantum Hall System.

Author

Bergholtz, Emil J. and Karlhede, Anders

Abstract

The physics of the quantum Hall system becomes very simple when studied on a thin torus. Remarkably, however, the very rich structure still exists in this limit and there is a continuous route to the bulk system. Here we review recent progress in understanding various features of the quantum Hall system in terms of a simple one-dimensional model corresponding to the thin torus. [ABSTRACT FROM AUTHOR]

Published

2008

19. Non-Abelian fractional Chern insulators from long-range interactions.

Author

Zhao Liu, Bergholtz, Emil J., and Kapit, Eliot

Subjects

*ELECTRIC insulators & insulation, *LATTICE models (Statistical physics), *GROUND state (Quantum mechanics), *ANYONS, *PSEUDOPOTENTIAL method, *HUBBARD model

Abstract

The recent theoretical discovery of fractional Chern insulators (FCIs) has provided an important new way to realize topologically ordered states in lattice models. In earlier works, on-site and nearest-neighbor Hubbard-like interactions have been used extensively to stabilize Abelian FCIs in systems with nearly flat, topologically nontrivial bands. However, attempts to use two-body interactions to stabilize non-Abelian FCIs, where the ground state in the presence of impurities can be massively degenerate and manipulated through anyon braiding, have proven very difficult in uniform lattice systems. Here, we study the remarkable effect of long-range interactions in a lattice model that possesses an exactly flat lowest band with a unit Chern number. When spinless bosons with two-body long-range interactions partially fill the lowest Chern band, we find convincing evidence of gapped, bosonic Read-Rezayi (RR) phases with non-Abelian anyon statistics. We characterize these states through studying topological degeneracies, the overlap between the ground states of two-body interactions and the exact RR ground states of three- and four-body interactions, and state counting in the particle-cut entanglement spectrum. Moreover, we demonstrate how an approximate lattice form of Haldane's pseudopotentials, analogous to that in the continuum, can be used as an efficient guiding principle in the search for lattice models with stable non-Abelian phases. [ABSTRACT FROM AUTHOR]

Published

2013

20. TOPOLOGICAL FLAT BAND MODELS AND FRACTIONAL CHERN INSULATORS.

Author

BERGHOLTZ, EMIL J. and LIU, ZHAO

Subjects

*ELECTRIC insulators & insulation, *HALL effect, *GENERALIZATION, *LATTICE dynamics, *MAGNETIC fields, *LANDAU theory

Abstract

Topological insulators and their intriguing edge states can be understood in a single-particle picture and can as such be exhaustively classified. Interactions significantly complicate this picture and can lead to entirely new insulating phases, with an altogether much richer and less explored phenomenology. Most saliently, lattice generalizations of fractional quantum Hall states, dubbed fractional Chern insulators, have recently been predicted to be stabilized by interactions within nearly dispersionless bands with nonzero Chern number, C. Contrary to their continuum analogues, these states do not require an external magnetic field and may potentially persist even at room temperature, which make these systems very attractive for possible applications such as topological quantum computation. This review recapitulates the basics of tight-binding models hosting nearly flat bands with nontrivial topology, C≠0, and summarizes the present understanding of interactions and strongly correlated phases within these bands. Emphasis is made on microscopic models, highlighting the analogy with continuum Landau level physics, as well as qualitatively new, lattice specific, aspects including Berry curvature fluctuations, competing instabilities as well as novel collective states of matter emerging in bands with |C|>1. Possible experimental realizations, including oxide interfaces and cold atom implementations as well as generalizations to flat bands characterized by other topological invariants are also discussed. [ABSTRACT FROM AUTHOR]

Published

2013

21. Topological equivalence of crystal and quasicrystal band structures.

Author

Madsen, Kevin A., Bergholtz, Emil J., and Brouwer, Piet W.

Subjects

*CRYSTAL lattices, *LATTICE dynamics, *BAND gaps, *ELECTRONIC band structure, *PHOTOCONDUCTIVITY

Abstract

A number of recent articles have reported the existence of topologically nontrivial states and associated end states in one-dimensional incommensurate lattice models that would usually only be expected in higher dimensions. Using an explicit construction, we here argue that the end states have precisely the same origin as their counterparts in commensurate models and that incommensurability does not in fact provide a meaningful connection to the topological classification of systems in higher dimensions. In particular, we show that it is possible to smoothly interpolate between states with commensurate and incommensurate modulation parameters without closing the band gap and without states crossing the band gap. [ABSTRACT FROM AUTHOR]

Published

2013

22. From fractional Chern insulators to Abelian and non-Abelian fractional quantum Hall states: Adiabatic continuity and orbital entanglement spectrum.

Author

Bergholtz, Emil J. and Zhao Liu

Subjects

*CRYSTAL lattices, *QUANTUM Hall effect, *ADIABATIC processes, *SPECTRUM analysis, *THERMODYNAMIC potentials

Abstract

The possibility of realizing lattice analogs of fractional quantum Hall (FQH) states, so-called fractional Chern insulators (FCIs), in nearly flat topological (Chern) bands has attracted a lot of recent interest. Here, we make the connection between Abelian as well as non-Abelian FQH states and FCIs more precise. Using a gauge-fixed version of Qi's Wannier basis representation of a Chern band, we demonstrate that the interpolation between several FCI states, obtained by short-range lattice interactions in a spin-orbit-coupled kagome lattice model, and the corresponding continuum FQH states is smooth: the gap remains approximately constant and extrapolates to a finite value in the thermodynamic limit, while the low-lying part of the orbital entanglement spectrum remains qualitatively unaltered. The orbital entanglement spectra also provide a first glimpse of the edge physics of FCIs via the bulk-boundary correspondence. Corroborating these results, we find that the squared overlaps between the FCI and FQH ground states are as large as 98.7% for the 8-electron Laughlin state at v = 1/3 (consistent with an earlier study) and 97.8% for the 10-electron Moore-Read state at v = ½. For the bosonic analogs of these states, the adiabatic continuity is also shown to hold, albeit with somewhat smaller associated overlaps, etc. Although going between the Chern bands to the Landau-level problem is often smooth, we show that this is not always the case by considering fermions at filling fraction v = 4/5, where the interpolation between Hamiltonians describing the two systems results in a phase transition. [ABSTRACT FROM AUTHOR]

Published

2013

23. Flat bands with higher Chern number in pyrochlore slabs.

Author

Trescher, Maximilian and Bergholtz, Emil J.

Subjects

*PYROCHLORE, *QUANTUM Hall effect, *LATTICE theory, *METALLIC oxides, *PARTICLE size determination

Abstract

A large number of recent works point to the emergence of intriguing analogs of fractional quantum Hall states in lattice models due to effective interactions in nearly flat bands with Chern number C = 1. Here, we provide an intuitive and efficient construction of almost dispersionless bands with higher Chern numbers. Inspired by the physics of quantum Hall multilayers and pyrochlore-based transition-metal oxides, we study a tight-binding model describing spin-orbit coupled electrons in N parallel kagome layers connected by apical sites forming N - 1 intermediate triangular layers (as in the pyrochlore lattice). For each N, we find finite regions in parameter space giving a virtually flat band with C = N. We analytically express the states within these topological bands in terms of single-layer states and thereby explicitly demonstrate that the C = N wave functions have an appealing structure in which layer index and translations in reciprocal space are intricately coupled. This provides a promising arena for new collective states of matter. [ABSTRACT FROM AUTHOR]

Published

2012

24. Fractional Chern Insulators in Topological Flat Bands with Higher Chern Number.

Author

Zhao Liu, Bergholtz, Emil J., Heng Fan, and Läuchli, Andreas M.

Subjects

*ELECTRIC insulators & insulation, *ENERGY bands, *QUANTUM Hall effect, *FERMIONS, *EXISTENCE theorems, *QUANTUM entanglement

Abstract

Lattice models forming bands with higher Chern number offer an intriguing possibility for new phases of matter with no analogue in continuum Landau levels. Here, we establish the existence of a number of new bulk insulating states at fractional filling in flat bands with a Chern number C = Ν > 1, forming in a recently proposed pyrochlore model with strong spin-orbit coupling. In particular, we find compelling evidence for a series of stable states at ν = l/(2N + 1) for fermions as well as bosonic states at ν = l/(N + 1). By examining the topological ground state degeneracies and the excitation structure as well as the entanglement spectrum, we conclude that these states are Abelian. We also explicitly demonstrate that these states are nevertheless qualitatively different from conventional quantum Hall (multilayer) states due to the novel properties of the underlying band structure. [ABSTRACT FROM AUTHOR]

Published

2012

25. Entanglement scaling of fractional quantum Hall states through geometric deformations.

Author

Läuchli, Andreas M., Bergholtz, Emil J., and Haque, Masudul

Subjects

*QUANTUM Hall effect, *TORUS, *MANIFOLDS (Mathematics), *TOPOLOGICAL spaces, *ENTROPY, *TOPOLOGICAL entropy, *THERMODYNAMICS

Abstract

We present a new approach for obtaining the scaling behavior of the entanglement entropy in fractional quantum Hall (FQH) states from finite-size wavefunctions. By employing the torus geometry and the fact that the torus aspect ratio can be readily varied, we can extract the entanglement entropy of a spatial block as a continuous function of the block boundary length. This approach allows us to extract the topological entanglement entropy with an accuracy superior to that possible for the spherical or disc geometry, where no natural continuously variable parameter is available. Other than the topological information, the study of entanglement scaling is also useful as an indicator of the difficulty posed by FQH states for various numerical techniques. [ABSTRACT FROM AUTHOR]

Published

2010

26. Symmetry and Higher-Order Exceptional Points.

Author

Mandal, Ipsita and Bergholtz, Emil J.

Subjects

*SYMMETRY, *EIGENVECTORS, *EIGENVALUES

Abstract

Exceptional points (EPs), at which both eigenvalues and eigenvectors coalesce, are ubiquitous and unique features of non-Hermitian systems. Second-order EPs are by far the most studied due to their abundance, requiring only the tuning of two real parameters, which is less than the three parameters needed to generically find ordinary Hermitian eigenvalue degeneracies. Higher-order EPs generically require more fine-tuning, and are thus assumed to play a much less prominent role. Here, however, we illuminate how physically relevant symmetries make higher-order EPs dramatically more abundant and conceptually richer. More saliently, third-order EPs generically require only two real tuning parameters in the presence of either a parity-time (PT) symmetry or a generalized chiral symmetry. Remarkably, we find that these different symmetries yield topologically distinct types of EPs. We illustrate our findings in simple models, and show how third-order EPs with a generic ~ k 1 / 3 dispersion are protected by PT symmetry, while third-order EPs with a ~ k 1 / 2 dispersion are protected by the chiral symmetry emerging in non-Hermitian Lieb lattice models. More generally, we identify stable, weak, and fragile aspects of symmetry-protected higher-order EPs, and tease out their concomitant phenomenology. [ABSTRACT FROM AUTHOR]

Published

2021

27. Non-Hermitian Topological Sensors.

Author

Budich, Jan Carl and Bergholtz, Emil J.

Subjects

*DETECTORS, *MATERIALS, *QUANTUM communication

Abstract

We introduce and study a novel class of sensors whose sensitivity grows exponentially with the size of the device. Remarkably, this drastic enhancement does not rely on any fine-tuning, but is found to be a stable phenomenon immune to local perturbations. Specifically, the physical mechanism behind this striking phenomenon is intimately connected to the anomalous sensitivity to boundary conditions observed in non-Hermitian topological systems. We outline concrete platforms for the practical implementation of these non-Hermitian topological sensors ranging from classical metamaterials to synthetic quantum materials. [ABSTRACT FROM AUTHOR]

Published

2020

28. Non-Hermitian topology in monitored quantum circuits

Author

Fleckenstein, Christoph, Zorzato, Alberto, Varjas, Daniel, Bergholtz, Emil J., Bardarson, Jens H., and Tiwari, Apoorv

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), FOS: Physical sciences

Abstract

We demonstrate that genuinely non-Hermitian topological phases and corresponding topological phase transitions can be naturally realized in monitored quantum circuits, exemplified by the paradigmatic non-Hermitian Su-Schrieffer-Heeger model. We emulate this model by a 1D chain of spinless electrons evolving under unitary dynamics and subject to periodic measurements that are stochastically invoked. The non-Hermitian topology is visible in topological invariants adapted to the context of monitored circuits. For instance, the topological phase diagram of the monitored realization of the non-Hermitian Su-Schrieffer-Heeger model is obtained from the biorthogonal polarization computed from an effective Hamiltonian of the monitored system. Importantly, our monitored circuit realization allows direct access to steady state biorthogonal expectation values of generic observables, and hence, to measure physical properties of a genuine non-Hermitian model. We expect our results to be applicable more generally to a wide range of models that host non-Hermitian topological phases., Comment: 4.5 pages, 3 figures

29. Interacting Majorana chain: Transport properties and signatures of an emergent two-dimensional weak topological phase.

Author

Zhao Liu, Bergholtz, Emil J., Romito, Alessandro, and Meidan, Dganit

Subjects

*MAJORANA fermions, *TOPOLOGICAL insulators, *PHASE transitions, *QUARTIC fields, *SYMMETRY (Physics)

Abstract

We study a one-dimensional chain of 2N Majorana bound states, which interact through a local quartic interaction. This model describes for example the edge physics of a quasi-one-dimensional (1D) stack of 2N Kitaev chains with modified time-reversal symmetry TγiT-1=γi, which precludes the presence of quadratic coupling. The ground state of our 1D Majorana chain displays a fourfold periodicity in N, corresponding to the four distinct topological classes of the stacked Kitaev chains. We analyze the transport properties of the 1D Majorana chain, when probed by local conductors located at its ends. We find that for finite but large N, the scattering matrix partially reflects the fourfold periodicity, and the chain exhibits strikingly different transport properties for different chain lengths. In the thermodynamic limit, the 1D Majorana chain hosts a robust many-body zero mode, which indicates that the corresponding stacked two-dimensional bulk system realizes a weak topological phase. [ABSTRACT FROM AUTHOR]

Published

2017

30. Charge density wave instabilities of type-II Weyl semimetals in a strong magnetic field.

Author

Trescher, Maximilian, Bergholtz, Emil J., Udagawa, Masafumi, and Knolle, Johannes

Subjects

*WEYL fermions, *CHARGE density waves, *MAGNETIC fields, *ELECTRONIC band structure, *TOPOLOGY, *SURFACE states

Abstract

Shortly after the discovery of Weyl semimetals, properties related to the topology of their bulk band structure have been observed, e.g., signatures of the chiral anomaly and Fermi arc surface states. These essentially single particle phenomena are well understood, but whether interesting many-body effects due to interactions arise in Weyl systems remains much less explored. Here, we investigate the effect of interactions in a microscopic model of a type-II Weyl semimetal in a strong magnetic field. We identify a charge density wave (CDW) instability even for weak interactions stemming from the emergent nesting properties of the type-II Weyl Landau level dispersion. We map out the dependence of this CDW on magnetic field strength. Remarkably, as a function of decreasing temperature, a cascade of CDW transitions emerges and we predict characteristic signatures for experiments. [ABSTRACT FROM AUTHOR]

Published

2017

31. Josephson effect in a Weyl SNS junction.

Author

Madsen, Kevin A., Bergholtz, Emil J., and Brouwer, Piet W.

Subjects

*JOSEPHSON effect, *SUPERCONDUCTORS, *CHEMICAL potential

Abstract

We calculate the Josephson current density j(ϕ) for a Weyl superconductor-normal-metal-superconductor junction for which the outer terminals are superconducting Weyl metals and the normal layer is a Weyl (semi)metal. We describe the Weyl (semi)metal using a simple model with two Weyl points. The model has broken time-reversal symmetry, but inversion symmetry is present. We calculate the Josephson current for both zero and finite temperature for the two pairing mechanisms inside the superconductors that have been proposed in the literature, zero-momentum BCS-like pairing and finite-momentum FFLO-like pairing, and assuming the short-junction limit. For both pairing types we find that the current is proportional to the normal-state junction conductivity, with a proportionality coefficient that shows quantitative differences between the two pairing mechanisms. The current for the BCS-like pairing is found to be independent of the chemical potential, whereas the current for the FFLO-like pairing is not. [ABSTRACT FROM AUTHOR]

Published

2017

32. Experimental simulation of symmetry-protected higher-order exceptional points with single photons.

Author

Kunkun Wang, Lei Xiao, Haiqing Lin, Wei Yi, Bergholtz, Emil J., and Peng Xue

Subjects

*PHOTONS, *POLARIZED photons, *BEAM splitters

Abstract

The article focuses on the study of exceptional points (EPs) in non-Hermitian (NH) systems. It is reported that EPs are branch point singularities in the parameter space and are associated with the dispersion of interface states. It is further reported that these EPs has interesting topological properties and find applications in various areas, including sensing, wave propagation, laser emission, and more.

Published

2023

33. Beyond the Tao-Thouless limit of the fractional quantum Hall effect: spin chains and Fermi surface deformation.

Author

Nakamura, Masaaki, Wang, Zheng-Yuan, and Bergholtz, Emil J.

Published

2011

34. Spin chain description of rotating bosons at ν = 1.

Author

Wikberg, Emma, Bergholtz, Emil J., and Karlhede, Anders

Published

2009

35. Degeneracy of non-Abelian quantum Hall states on the torus: domain walls and conformal field theory.

Author

Ardonne, Eddy, Bergholtz, Emil J., Kailasvuori, Janik, and Wikberg, Emma

Published

2008

36. ‘One-dimensional’ theory of the quantum Hall system.

Author

Bergholtz, Emil J and Karlhede, Anders

Published

2006

37. Quantum Transport of Disordered Weyl Semimetals at the Nodal Point.

Author

Sbierski, Björn, Pohl, Gregor, Bergholtz, Emil J., and Brouwer, Piet W.

Subjects

*QUANTUM theory, *WEYL groups, *SEMIMETALS, *NARROW gap semiconductors, *CHARGE transfer

Abstract

Weyl semimetals are paradigmatic topological gapless phases in three dimensions. We here address the effect of disorder on charge transport in Weyl semimetals. For a single Weyl node with energy at the degeneracy point and without interactions, theory predicts the existence of a critical disorder strength beyond which the density of states takes on a nonzero value. Predictions for the conductivity are divergent, however. In this work, we present a numerical study of transport properties for a disordered Weyl cone at zero energy. For weak disorder, our results are consistent with a renormalization group flow towards an attractive pseudoballistic fixed point with zero conductivity and a scale-independent conductance; for stronger disorder, diffusive behavior is reached. We identify the Fano factor as a signature that discriminates between these two regimes. [ABSTRACT FROM AUTHOR]

Published

2014

38. Bulk-edge correspondence in fractional Chern insulators.

Author

Zhao Liu, Kovrizhin, D. L., and Bergholtz, Emil J.

Subjects

*ELECTRIC insulators & insulation, *QUANTUM Hall effect, *WANNIER-stark effect, *ABELIAN functions, *MATRICES (Mathematics), *LATTICE theory

Abstract

It has been recently realized that strong interactions in topological Bloch bands give rise to the appearance of novel states of matter. Here we study connections between these systems—fractional Chern insulators and the fractional quantum Hall states—via generalization of a gauge-fixed Wannier-Qi construction in the cylinder geometry. Our setup offers a number of important advantages compared to the earlier exact diagonalization studies on a torus. Most notably, it gives access to edge states and to a single-cut orbital entanglement spectrum, hence to the physics of bulk-edge correspondence. It is also readily implemented in the state-of-the-art density matrix renormalization group method that allows for numerical simulations of significantly larger systems. We demonstrate our general approach on examples of flat-band models on ruby and kagome lattices at bosonic filling fractions ν=1/2 and ν=1, which show the signatures of (non)-Abelian phases, and establish the correspondence between the physics of edge states and the entanglement in the bulk. Notably, we find that the non-Abelian ν=1 phase can be stabilized by purely on-site interactions in the presence of a confining potential. [ABSTRACT FROM AUTHOR]

Published

2013

39. Exactly Solvable Fermion Chain Describing a &ngr; = 1/3 Fractional Quantum Hall State.

Author

Nakamura, Masaaki, Zheng-Yuan Wang, and Bergholtz, Emil J.

Subjects

*FERMIONS, *QUANTUM Hall effect, *CENTER of mass, *MATHEMATICAL models, *WAVE functions, *NUCLEAR spin

Abstract

We introduce an exactly solvable fermion chain that describes a &ngr; = 1/3 fractional quantum Hall (FQH) state beyond the thin-torus limit. The ground state of our model is shown to be unique for each center-of mass sector, and it has a matrix product representation that enables us to exactly calculate order parameters, correlation functions, and entanglement spectra. The ground state of our model shows striking similarities with the BCS wave functions and quantum spin-1 chains. Using the variational method with matrix product ansatz, we analytically calculate excitation gaps and vanishing of the compressibility expected in the FQH state. We also show that the above results can be related to a &ngr; = 1/2 bosonic FQH state. [ABSTRACT FROM AUTHOR]

Published

2012

40. Fractional domain walls from on-site softening in dipolar bosons.

Author

Wikberg, Emma, Larson, Jonas, Bergholtz, Emil J., and Karlhede, Anders

Subjects

*BOSONS, *OPTICAL lattices, *CHARGE density waves, *QUANTUM Hall effect, *ELECTRONIC excitation, *FORCE & energy, *SUPERFLUIDITY

Abstract

We study dipolar bosons in a ID optical lattice and identify a region in parameter space--strong coupling but relatively weak on-site repulsion--hosting a series of stable charge-density-wave (CDW) states whose low-energy excitations, built from "fractional domain walls," have remarkable similarities to those of non-Abelian fractional quantum Hall states. Here, a conventional domain wall between translated CDW's may be split by inserting strings of degenerate, but inequivalent, CDW states. Outside these insulating regions, we find numerous supersolids as well as a superfluid regime. The mentioned phases should be accessible experimentally and, in particular, the fractional domain walls can be created in the ground state using single-site addressing, i.e., by locally changing the chemical potential. [ABSTRACT FROM AUTHOR]

Published

2012

41. Exceptional Spin Liquids from Couplings to the Environment.

Author

Kang Yang, Morampudi, Siddhardh C., and Bergholtz, Emil J.

Subjects

*MAJORANA fermions, *SKIN effect, *LIQUIDS, *DISPLAY systems

Abstract

We establish the appearance of a qualitatively new type of spin liquid with emergent exceptional points when coupling to the environment. We consider an open system of the Kitaev honeycomb model generically coupled to an external environment. In extended parameter regimes, the Dirac points of the emergent Majorana fermions from the original model are split into exceptional points with Fermi arcs connecting them. In glaring contrast to the original gapless phase of the honeycomb model that requires time-reversal symmetry, this new phase is stable against all perturbations. The system also displays a large sensitivity to boundary conditions resulting from the non-Hermitian skin effect with telltale experimental consequences. Our results point to the emergence of new classes of spin liquids in open systems that might be generically realized due to unavoidable couplings with the environment. [ABSTRACT FROM AUTHOR]

Published

2021

42. Gate-Tunable Fractional Chern Insulators in Twisted Double Bilayer Graphene.

Author

Zhao Liu, Abouelkomsan, Ahmed, and Bergholtz, Emil J.

Subjects

*GRAPHENE, *PHASES of matter, *HIGH temperatures, *MAGNETIC fields

Abstract

We predict twisted double bilayer graphene to be a versatile platform for the realization of fractional Chern insulators readily targeted by tuning the gate potential and the twist angle. Remarkably, these topologically ordered states of matter, including spin singlet Halperin states and spin polarized states in Chern number C=1 and C=2 bands, occur at high temperatures and without the need for an external magnetic field. [ABSTRACT FROM AUTHOR]

Published

2021

43. Particle-Hole Duality, Emergent Fermi Liquids, and Fractional Chern Insulators in Moiré Flatbands.

Author

Abouelkomsan, Ahmed, Zhao Liu, and Bergholtz, Emil J.

Subjects

*FERMI liquids, *BORON nitride, *ELECTRON density, *HIGH temperatures, *GRAPHENE, *INTUITION

Abstract

Moiré flatbands, occurring, e.g., in twisted bilayer graphene at magic angles, have attracted ample interest due to their high degree of experimental tunability and the intriguing possibility of generating novel strongly interacting phases. Here we consider the core problem of Coulomb interactions within fractionally filled spin and valley polarized Moiré flatbands and demonstrate that the dual description in terms of holes, which acquire a nontrivial hole dispersion, provides key physical intuition and enables the use of standard perturbative techniques for this strongly correlated problem. In experimentally relevant examples such as ABC stacked trilayer and twisted bilayer graphene aligned with boron nitride, it leads to emergent interaction-driven Fermi liquid states at electronic filling fractions down to around 1/3 and 2/3, respectively. At even lower filling fractions, the electron density still faithfully tracks the single-hole dispersion while exhibiting distinct non-Fermi liquid behavior. Most saliently, we provide microscopic evidence that high temperature fractional Chern insulators can form in twisted bilayer graphene aligned with hexagonal boron nitride. [ABSTRACT FROM AUTHOR]

Published

2020

44. Mixed Axial-Torsional Anomaly in Weyl Semimetals.

Author

Ferreiros, Yago, Kedem, Yaron, Bergholtz, Emil J., and Bardarson, Jens H.

Subjects

*FERMIONS, *SEMIMETALS, *SOUND waves

Abstract

We show that Weyl semimetals exhibit a mixed axial-torsional anomaly in the presence of axial torsion, a concept exclusive of these materials with no known natural fundamental interpretation in terms of the geometry of spacetime. This anomaly implies a nonconservation of the axial current--the difference in the current of left- and right-handed chiral fermions--when the torsion of the spacetime in which the Weyl fermions move couples with opposite sign to different chiralities. The anomaly is activated by driving transverse sound waves through a Weyl semimetal with a spatially varying tilted dispersion, which can be engineered by applying strain. This leads to a sizable alternating current in the presence of a magnetic field that provides a clear-cut experimental signature of our predictions. [ABSTRACT FROM AUTHOR]

Published

2019

45. Exotic Non-Abelian Topological Defects in Lattice Fractional Quantum Hall States.

Author

Zhao Liu, Möller, Gunnar, and Bergholtz, Emil J.

Subjects

*QUANTUM Hall effect, *GAUGE field theory, *ABELIAN equations

Abstract

We investigate extrinsic wormholelike twist defects that effectively increase the genus of space in lattice versions of multicomponent fractional quantum Hall systems. Although the original band structure is distorted by these defects, leading to localized midgap states, we find that a new lowest flat band representing a higher genus system can be engineered by tuning local single-particle potentials. Remarkably, once local many-body interactions in this new band are switched on, we identify various Abelian and non-Abelian fractional quantum Hall states, whose ground-state degeneracy increases with the number of defects, i.e, with the genus of space. This sensitivity of topological degeneracy to defects provides a "proof of concept" demonstration that genons, predicted by topological field theory as exotic non-Abelian defects tied to a varying topology of space, do exist in realistic microscopic models. Specifically, our results indicate that genons could be created in the laboratory by combining the physics of artificial gauge fields in cold atom systems with already existing holographic beam shaping methods for creating twist defects. [ABSTRACT FROM AUTHOR]

Published

2017

46. Anatomy of topological surface states: Exact solutions from destructive interference on frustrated lattices.

Author

Kunst, Flore K., Trescher, Maximilian, and Bergholtz, Emil J.

Subjects

*TOPOLOGY, *WEYL fermions, *QUANTUM spin Hall effect

Abstract

The hallmark of topological phases is their robust boundary signature whose intriguing properties--such as the one-way transport on the chiral edge of a Chern insulator and the sudden disappearance of surface states forming open Fermi arcs on the surfaces of Weyl semimetals--are impossible to realize on the surface alone. Yet, despite the glaring simplicity of noninteracting topological bulk Hamiltonians and their concomitant energy spectrum, the detailed study of the corresponding surface states has essentially been restricted to numerical simulation. In this work, however, we show that exact analytical solutions of both topological and trivial surface states can be obtained for generic tight-binding models on a large class of geometrically frustrated lattices in any dimension without the need for fine-tuning of hopping amplitudes. Our solutions derive from local constraints tantamount to destructive interference between neighboring layer lattices perpendicular to the surface and provide microscopic insights into the structure of the surface states that enable analytical calculation of many desired properties including correlation functions, surface dispersion, Berry curvature, and the system size dependent gap closing, which necessarily occurs when the spatial localization switches surface. This further provides a deepened understanding of the bulk-boundary correspondence. We illustrate our general findings on a large number of examples in two and three spatial dimensions. Notably, we derive exact chiral Chern insulator edge states on the spin-orbit-coupled kagome lattice, and Fermi arcs relevant for recently synthesized slabs of pyrochlore-based Eu2Ir2O7 and Nd2Ir2O7, which realize an all-in-all-out spin configuration, as well as for spin-ice-like two-in-two-out and one-in-three-out configurations, which are both relevant for Pr2Ir2O7. Remarkably, each of the pyrochlore examples exhibit clearly resolved Fermi arcs although only the one-in-three-out configuration features bulk Weyl nodes in realistic parameter regimes. Our approach generalizes to symmetry protected phases, e.g., quantum spin Hall systems and Dirac semimetals with time-reversal symmetry, and can furthermore signal the absence of topological surface states, which we illustrate for a class of models akin to the trivial surface of Hourglass materials KHgX where the exact solutions apply but, independently of Hamiltonian details, yield eigenstates delocalized over the entire sample. [ABSTRACT FROM AUTHOR]

Published

2017

47. Disordered double Weyl node: Comparison of transport and density of states calculations.

Author

Sbierski, Björn, Trescher, Maximilian, Bergholtz, Emil J., and Brouwer, Piet W.

Subjects

*WEYL fermions, *TOPOLOGY, *DENSITY

Abstract

Double Weyl nodes are topologically protected band crossing points which carry chiral charge ±2. They are stabilized by C4 point-group symmetry and are predicted to occur in SrSi2 or HgCr2Se4. We study their stability and physical properties in the presence of a disorder potential. We investigate the density of states and the quantum transport properties at the nodal point. We find that, in contrast to their counterparts with unit chiral charge, double Weyl nodes are unstable to any finite amount of disorder and give rise to a diffusive phase, in agreement with the predictions of Goswami and Nevidomskyy [Phys. Rev. B 92, 214504 (2015)] and Bera, Sau, and Roy [Phys. Rev. B 93, 201302 (2016)]. However, for finite system sizes a crossover between pseudodiffusive and diffusive quantum transport can be observed. [ABSTRACT FROM AUTHOR]

Published

2017

48. Model Fractional Chern Insulators.

Author

Behrmann, Jörg, Zhao Liu, and Bergholtz, Emil J.

Subjects

*LATTICE models (Statistical physics), *GENERALIZATION, *SUPERCONDUCTIVITY

Abstract

We devise local lattice models whose ground states are model fractional Chern insulators--Abelian and non-Abelian topologically ordered states characterized by exact ground state degeneracies at any finite size and infinite entanglement gaps. Most saliently, we construct exact parent Hamiltonians for two distinct families of bosonic lattice generalizations of the Zk parafermion quantum Hall states: (i) color-entangled fractional Chern insulators at band filling fractions ν = k/(C+1) and (ii) nematic states at ν = k/2, where C is the Chern number of the lowest band. In spite of a fluctuating Berry curvature, our construction is partially frustration free: the ground states reside entirely within the lowest band and exactly minimize a local (k+1) body repulsion term by term. In addition to providing the first known models hosting intriguing states such as higher Chern number generalizations of the Fibonacci anyon quantum Hall states, the remarkable stability and finite-size properties make our models particularly well suited for the study of novel phenomena involving, e.g., twist defects and proximity induced superconductivity, as well as being a guide for designing experiments. [ABSTRACT FROM AUTHOR]

Published

2016

49. Quantum transport in Dirac materials: Signatures of tilted and anisotropic Dirac and Weyl cones.

Author

Trescher, Maximilian, Sbierski, Björn, Brouwer, Piet W., and Bergholtz, Emil J.

Subjects

*DISCRETE symmetries, *ANISOTROPY, *LATTICE models (Statistical physics), *GRAPHENE, *PYROCHLORE

Abstract

We calculate conductance and noise for quantum transport at the nodal point for arbitrarily tilted and anisotropic Dirac or Weyl cones. Tilted and anisotropic dispersions are generic in the absence of certain discrete symmetries, such as particle-hole and lattice point group symmetries. Whereas anisotropy affects the conductance g, but leaves the Fano factor F (the ratio of shot noise power and current) unchanged, a tilt affects both g and F. Since F is a universal number in many other situations, this finding is remarkable. We apply our general considerations to specific lattice models of strained graphene and a pyrochlore Weyl semimetal. [ABSTRACT FROM AUTHOR]

Published

2015

50. Biorthogonal Bulk-Boundary Correspondence in Non-Hermitian Systems.

Author

Kunst, Flore K., Edvardsson, Elisabet, Budich, Jan Carl, and Bergholtz, Emil J.

Subjects

*BIORTHOGONAL systems, *QUANTUM mechanics, *PHASE transitions

Abstract

Non-Hermitian systems exhibit striking exceptions from the paradigmatic bulk-boundary correspondence, including the failure of bulk Bloch band invariants in predicting boundary states and the (dis)appearance of boundary states at parameter values far from those corresponding to gap closings in periodic systems without boundaries. Here, we provide a comprehensive framework to unravel this disparity based on the notion of biorthogonal quantum mechanics: While the properties of the left and right eigenstates corresponding to boundary modes are individually decoupled from the bulk physics in non-Hermitian systems, their combined biorthogonal density penetrates the bulk precisely when phase transitions occur. This leads to generalized bulk-boundary correspondence and a quantized biorthogonal polarization that is formulated directly in systems with open boundaries. We illustrate our general insights by deriving the phase diagram for several microscopic open boundary models, including exactly solvable non-Hermitian extensions of the Su-Schrieffer-Heeger model and Chern insulators. [ABSTRACT FROM AUTHOR]

Published

2018