Your search keyword '"Topological matter"' showing total 14 results

1. Topology of 2D Dirac operators with variable mass and an application to shallow-water waves.

Author

Rossi, Sylvain and Tarantola, Alessandro

Subjects

DIRAC operators, BRILLOUIN zones, SHALLOW-water equations, TOPOLOGY, WATER waves, WATER depth

Abstract

A Dirac operator on the plane with constant (positive) mass is a Chern insulator, sitting in class D of the Kitaev table. Despite its simplicity, this system is topologically ill-behaved: the non-compact Brillouin zone prevents definition of a bulk invariant, and naively placing the model on a manifold with boundary results in violations of the bulk-edge correspondence (BEC). We overcome both issues by letting the mass spatially vary in the vertical direction, interpolating between the original model and its negative-mass counterpart. Proper bulk and edge indices can now be defined. They are shown to coincide, thereby embodying BEC. The shallow-water model exhibits the same illnesses as the 2D massive Dirac. Identical problems suggest identical solutions, and indeed extending the approach above to this setting yields proper indices and another instance of BEC. [ABSTRACT FROM AUTHOR]

Published

2024

2. On the ℤ2 topological invariant.

Author

Drissi, L. B. and Saidi, E. H.

Subjects

TOPOLOGICAL property, TIME reversal, MOLECULAR connectivity index, GENERALIZATION

Abstract

We develop a complex fermionic field-based method to model the properties of the filled bands of topological two-dimensional (2D) matter with time reversal (TR)-symmetry. Using this fermionic representation, we give an explicit calculation of the ℤ 2 index for 2D topological matter invariant under TR and comment on the emergence of Majorana states at the TR-fix points. Moreover, motivated by recent theoretical results on possible signatures of topological supersymmetric matter, we also give the supersymmetric generalization of our TR-invariant construction and calculate the underlying topological ℤ 2 index. Other features such as the topological obstruction of basis sections in the fermionic determinant bundle are also investigated. Applications for the calculations of the supersymmetric charge Q ̂ susy operator and the super-Hamiltonian Ĥ susy for the three-dimensional topological class AII are undertaken; these operators are given by Eqs. (5.48)–(5.51). [ABSTRACT FROM AUTHOR]

Published

2023

3. Topological aspects of antiferromagnets.

Author

Bonbien, V, Zhuo, Fengjun, Salimath, A, Ly, O, Abbout, A, and Manchon, A

Subjects

SPIN Hall effect, ANTIFERROMAGNETIC materials, SPINTRONICS, SCIENTIFIC community, MAGNETS, SKYRMIONS

Abstract

The long fascination that antiferromagnetic materials has exerted on the scientific community over about a century has been entirely renewed recently with the discovery of several unexpected phenomena, including various classes of anomalous spin and charge Hall effects and unconventional magnonic transport, and also homochiral magnetic entities such as skyrmions. With these breakthroughs, antiferromagnets stand out as a rich playground for the investigation of novel topological behavior, and as promising candidate materials for disruptive low-power microelectronic applications. Remarkably, the newly discovered phenomena are all related to the topology of the magnetic, electronic or magnonic ground state of the antiferromagnets. This review exposes how non-trivial topology emerges at different levels in antiferromagnets and explores the novel mechanisms that have been discovered recently. We also discuss how novel classes of quantum magnets could enrich the currently expanding field of antiferromagnetic spintronics and how spin transport can in turn favor a better understanding of exotic quantum excitations. [ABSTRACT FROM AUTHOR]

Published

2022

4. Exotic Quantum States of Circuit Quantum Electrodynamics in the Ultra‐Strong Coupling Regime.

Author

Choi, Mahn‐Soo

Abstract

The quantum coherent behaviors of superconducting devices at macroscopic scales and recent technical advances in fine tunability have brought the conventional cavity quantum electrodynamics (QED) to superconducting circuits. With an ultra‐strong cavity photon–artificial atom coupling and the inherent nonlinearity of the Josephson junctions, the so‐called circuit QED offers new opportunities to explore new realms of physics that have remained a challenge for conventional cavity QED. Circuit QED has even attracted public attention as the leading architecture for quantum computation. In this article, a pedagogical review of recent studies and activities on exotic quantum states that can be attributed to ultra‐strong coupling is provided. A progress report on attempts to seek the smallest unit of the topological matter and its fundamental interaction with light is also provided. [ABSTRACT FROM AUTHOR]

Published

2020

5. High-Chern-number and high-temperature quantum Hall effect without Landau levels.

Author

Ge, Jun, Liu, Yanzhao, Li, Jiaheng, Li, Hao, Luo, Tianchuang, Wu, Yang, Xu, Yong, and Wang, Jian

Subjects

LANDAU levels, QUANTUM Hall effect, QUANTUM states, LOW temperatures, HIGH temperatures, PHYSICS

Abstract

The quantum Hall effect (QHE) with quantized Hall resistance of h / νe 2 started the research on topological quantum states and laid the foundation of topology in physics. Since then, Haldane proposed the QHE without Landau levels, showing nonzero Chern number | C | = 1, which has been experimentally observed at relatively low temperatures. For emerging physics and low-power-consumption electronics, the key issues are how to increase the working temperature and realize high Chern numbers (C > 1). Here, we report the experimental discovery of high-Chern-number QHE (C = 2) without Landau levels and C = 1 Chern insulator state displaying a nearly quantized Hall resistance plateau above the Néel temperature in MnBi2Te4 devices. Our observations provide a new perspective on topological matter and open new avenues for exploration of exotic topological quantum states and topological phase transitions at higher temperatures. [ABSTRACT FROM AUTHOR]

Published

2020

6. Spin, Orbital, Weyl and Other Glasses in Topological Superfluids.

Author

Volovik, G. E., Rysti, J., Mäkinen, J. T., and Eltsov, V. B.

Subjects

SUPERFLUIDITY, NANOSTRUCTURED materials, GLASS, SKYRMIONS, TORSION

Abstract

One of the most spectacular discoveries made in superfluid 3 He confined in a nanostructured material like aerogel or nafen was the observation of the destruction of the long-range orientational order by a weak random anisotropy. The quenched random anisotropy provided by the confining material strands produces several different glass states resolved in NMR experiments in the chiral superfluid 3 He-A and in the time-reversal-invariant polar phase. The smooth textures of spin and orbital order parameters in these glasses can be characterized in terms of the randomly distributed topological charges, which describe skyrmions, spin vortices and hopfions. In addition, in these skyrmion glasses the momentum-space topological invariants are randomly distributed in space. The Chern mosaic, Weyl glass, torsion glass and other exotic topological states are examples of close connections between the real-space and momentum-space topologies in superfluid 3 He phases in aerogel. [ABSTRACT FROM AUTHOR]

Published

2019

7. Topological quantum matter with cold atoms.

Author

Zhang, Dan-Wei, Zhu, Yan-Qing, Zhao, Y. X., Yan, Hui, and Zhu, Shi-Liang

Subjects

ULTRACOLD molecules, CONDENSED matter physics, OPTICAL lattices, COLD gases, ATOMS, QUANTUM mechanics

Abstract

This is an introductory review of the physics of topological quantum matter with cold atoms. Topological quantum phases, originally discovered and investigated in condensed matter physics, have recently been explored in a range of different systems, which produced both fascinating physics findings and exciting opportunities for applications. Among the physical systems that have been considered to realize and probe these intriguing phases, ultracold atoms become promising platforms due to their high flexibility and controllability. Quantum simulation of topological phases with cold atomic gases is a rapidly evolving field, and recent theoretical and experimental developments reveal that some toy models originally proposed in condensed matter physics have been realized with this artificial quantum system. The purpose of this article is to introduce these developments. The article begins with a tutorial review of topological invariants and the methods to control parameters in the Hamiltonians of neutral atoms. Next, topological quantum phases in optical lattices are introduced in some detail, especially several celebrated models, such as the Su-Schrieffer-Heeger model, the Hofstadter-Harper model, the Haldane model and the Kane-Mele model. The theoretical proposals and experimental implementations of these models are discussed. Notably, many of these models cannot be directly realized in conventional solid-state experiments. The newly developed methods for probing the intrinsic properties of the topological phases in cold-atom systems are also reviewed. Finally, some topological phases with cold atoms in the continuum and in the presence of interactions are discussed, and an outlook on future work is given. [ABSTRACT FROM AUTHOR]

Published

2018

8. Two Topologically Distinct Dirac-Line Semimetal Phases and Topological Phase Transitions in Rhombohedrally Stacked Honeycomb Lattices.

Author

Hyart, T., Ojajärvi, R., and Heikkilä, T. T.

Subjects

PHASE transitions, BRILLOUIN zones, SURFACE states, GRAPHITE, TOPOLOGICAL defects (Physics)

Abstract

Three-dimensional topological semimetals can support band crossings along one-dimensional curves in the momentum space (nodal lines or Dirac lines) protected by structural symmetries and topology. We consider rhombohedrally (ABC) stacked honeycomb lattices supporting Dirac lines protected by time-reversal, inversion and spin rotation symmetries. For typical band structure parameters there exists a pair of nodal lines in the momentum space extending through the whole Brillouin zone in the stacking direction. We show that these Dirac lines are topologically distinct from the usual Dirac lines which form closed loops inside the Brillouin zone. In particular, an energy gap can be opened only by first merging the Dirac lines going through the Brillouin zone in a pairwise manner so that they turn into closed loops inside the Brillouin zone, and then by shrinking these loops into points. We show that this kind of topological phase transition can occur in rhombohedrally stacked honeycomb lattices by tuning the ratio of the tunneling amplitudes in the directions perpendicular and parallel to the layers. We also discuss the properties of the surface states in the different phases of the model. [ABSTRACT FROM AUTHOR]

Published

2018

9. Predicted Weyl fermions in magnetic GdBi and GdSb.

Author

Li, Zhi, Xu, Dan-Dan, Ning, Shu-Yu, Su, Haibin, Iitaka, Toshiaki, Tohyama, Takami, and Zhang, Jiu-Xing

Subjects

MAGNETORESISTANCE, MAGNETIC fields, PARAMAGNETISM, FERROMAGNETISM, ANTIFERROMAGNETISM

Abstract

Motivated by the chiral anomaly steering negative longitudinal magnetoresistance in GdBiPt under external magnetic field, we studied the electronic structures of GdBi with paramagnetism, antiferromagnetism and ferromagnetism by first-principles calculations with modified Becke and Johnson local density approximation plus Hubbard . Our calculated results reveal that paramagnetic GdBi is semiconducting, while the antiferromagnetic GdBi is a topological nontrivial compensation metal. We also predict the presence of a pair of Weyl fermions in ferromagnetic GdBi and GdSb. The band crossing along the direction of magnetization is protected by the fourfold rotation symmetry, and the topological charge associating with each band crossing point is . [ABSTRACT FROM AUTHOR]

Published

2017

10. Classification of topological phonons in linear mechanical metamaterials.

Author

Süsstrunk, Roman and Huber, Sebastian D.

Subjects

PHONONS, METAMATERIALS, PHONONIC crystals, TOPOLOGICAL spaces, ELECTRONS

Abstract

Topological phononic crystals, alike their electronic counterparts, are characterized by a bulk-edge correspondence where the interior of a material dictates the existence of stable surface or boundary modes. In the mechanical setup, such surface modes can be used for various applications such as wave guiding, vibration isolation, or the design of static properties such as stable floppy modes where parts of a system move freely. Here, we provide a classification scheme of topological phonons based on local symmetries. We import and adapt the classification of noninteracting electron systems and embed it into the mechanical setup. Moreover, we provide an extensive set of examples that illustrate our scheme and can be used to generate models in unexplored symmetry classes. Our work unifies the vast recent literature on topological phonons and paves the way to future applications of topological surface modes in mechanical metamaterials. [ABSTRACT FROM AUTHOR]

Published

2016

11. AN OPTICAL PLAQUETTE: MINIMUM EXPRESSIONS OF TOPOLOGICAL MATTER.

Author

Paredes, B.

Subjects

TOPOLOGY, PARADIGMS (Social sciences), PLAQUETTE bindings, OPTICAL lattices, VALENCE bonds

Published

2009

12. Nonlinear conduction via solitons in a topological mechanical insulator.

Author

Gin-ge Chen, Bryan, Upadhyaya, Nitin, and Vitelli, Vincenzo

Subjects

SOLITONS, TOPOLOGICAL insulators, METAMATERIALS, ROBOT design & construction, MECHANICAL behavior of materials, ELASTICITY

Abstract

Networks of rigid bars connected by joints, termed linkages, provide a minimal framework to design robotic arms and mechanical metamaterials built of folding components. Here, we investigate a chain-like linkage that, according to linear elasticity, behaves like a topological mechanical insulator whose zero-energy modes are localized at the edge. Simple experiments we performed using prototypes of the chain vividly illustrate how the soft motion, initially localized at the edge, can in fact propagate unobstructed all of the way to the opposite end. Using real prototypes, simulations, and analytical models, we demonstrate that the chain is a mechanical conductor, whose carriers are nonlinear solitary waves, not captured within linear elasticity. Indeed, the linkage prototype can be regarded as the simplest example of a topological metamaterial whose protected mechanical excitations are solitons, moving domain walls between distinct topological mechanical phases. More practically, we have built a topologically protected mechanism that can perform basic tasks such as transporting a mechanical state from one location to another. Our work paves the way toward adopting the principle of topological robustness in the design of robots assembled from activated linkages as well as in the fabrication of complex molecular nanostructures. [ABSTRACT FROM AUTHOR]

Published

2014

13. Topological Matter: Graphene and Superfluid $$^3$$ He.

Author

Katsnelson, M. and Volovik, G.

Subjects

HELIUM, GRAPHENE, FERMIONS, SUPERFLUIDITY, ENERGY transfer

Abstract

The physics of graphene and of the superfluid phases of $$^3$$ He have many common features. Both systems are topological materials where quasiparticles behave as relativistic massless (Weyl, Majorana or Dirac) fermions. We formulate the points where these features are overlapping. This will allow us to use graphene to study the properties of superfluid $$^3$$ He, to use superfluid $$^3$$ He to study the properties of graphene, and to use both of them in combination to study the physics of topological quantum vacuum. We suggest also some particular experiments with superfluid $$^3$$ He using graphene as an atomically thin membrane impenetrable for He atoms but allowing for spin, momentum and energy transfer. [ABSTRACT FROM AUTHOR]

Published

2014

14. Detection of topological matter with quantum gases.

Author

Spielman, I. B.

Subjects

QUANTUM gases, ULTRACOLD molecules, DEGREES of freedom, PHASE transitions, QUANTUM Hall effect, NEUTRON stars

Abstract

Creating and measuring topological matter - with non-local order deeply embedded in the global structure of its quantum mechanical eigenstates - presents unique experimental challenges. Since this order has no signature in local correlation functions, it might seem experimentally inaccessible in any macroscopic system; however, as the precisely quantized Hall plateaux in integer and fractional quantum Hall systems show, topology can have macroscopic signatures at the system's edges. Ultracold atoms provide new experimental platforms where both the intrinsic topology and the edge behavior can be directly measured. This article reviews, using specific examples, how non-interacting topological matter may be created and measured in quantum gases. [ABSTRACT FROM AUTHOR]

Published

2013