Your search keyword '"Topological matter"' showing total 225 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. Stability of topological states and crystalline solids

Author

Andrews, Bartholomew, Conduit, Gareth, and Möller, Gunnar

Subjects

530.4, topological matter, crystals, quantum Hall effect, stability

Abstract

From the alignment of magnets to the melting of ice, the transition between different phases of matter underpins our exploitation of materials. Both a quantum and a classical phase can undergo an instability into another state. In this thesis, we study the stability of matter in both contexts: topological states and crystalline solids. We start with the stability of fractional quantum Hall states on a lattice, known as fractional Chern insulators. We investigate, using exact diagonalization, fractional Chern insulators in higher Chern bands of the Harper-Hofstadter model, and examine the robustness of their many-body energy gap in the effective continuum limit. We report evidence of stable states in this regime; comment on two cases associated with a bosonic integer quantum Hall effect; and find a modulation of the correlation function in higher Chern bands. We next examine the stability of molecules using variational and diffusion Monte Carlo. By incorporating the matrix of force constants directly into the algorithms, we find that we are able to improve the efficiency and accuracy of atomic relaxation and eigenfrequency calculation. We test the performance on a diverse selection of case studies, with varying symmetries and mass distributions, and show that the proposed formalism outperforms existing restricted Hartree-Fock and density functional theory methods. Finally, we analyze the stability of three-dimensional crystals. We note that for repulsive Coulomb crystals of point nuclei, cubic systems have a zero matrix of force constants at second order. We investigate this by constructing an analytical model in the tight-binding approximation, and present a phase diagram of the most stable crystal structures, as we tune core and valence orbital radii. We reconcile our results with calculations in the nearly free electron regime, as well as current research in condensed matter and plasma physics.

Published

2019

3. 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

4. Topological semimetals with helicoid surface states

Author

Fu, Liang [Massachusetts Inst. of Technology (MIT), Cambridge, MA (United States). Dept. of Physics]

Published

2016

5. 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

6. Dynamical quantum phase transitions following double quenches: persistence of the initial state vs dynamical phases

Author

Hadi Cheraghi and Nicholas Sedlmayr

Subjects

dynamical quantum phase transitions, topological matter, quantum dynamics, Science, Physics, QC1-999

Abstract

Dynamical quantum phase transitions (DQPTs) can occur following quenches in quantum systems when the rate function, a dynamical analogue of the free energy, becomes non-analytic at critical times. Here we exhaustively investigate in an exemplary model how the dynamically evolving state responds to a second quench. We demonstrate that for quenches where the initial and final Hamiltonian belong to different phases always result in DQPTs, irrespective of the intermediate quench and dynamics or the time of the second quench. However, if the initial and final Hamiltonian belong to the same equilibrium phase then the intermediate Hamiltonian must belong to a different phase. In this case, the second quench time in relation to the critical times of the first quench becomes crucial to the existence of DQPTs.

Published

2023

7. (INVITED) Emerging routes to light-matter interaction in two-dimensional materials

Author

C. Grazianetti, C. Martella, and E. Cinquanta

Subjects

Xenes, Transition metal dichalcogenides, Photonics, Photon harvesting, Light engineering, Topological matter, Applied optics. Photonics, TA1501-1820, Optics. Light, QC350-467

Abstract

Two-dimensional (2D) materials like transition metal dichalcogenides and Xenes are expected to bring exciting advancements in many fields of nanotechnology. The wealth of their electronic properties makes them appealing for a broad range of applications. In particular, in the framework of optics and photonics, three emerging routes where the key role of 2D materials will push forward the current state-of-the-art will be here outlined and discussed. Exerting control over the light-driven generation of spin-polarized dissipationless currents, enhancing the photon harvesting, and engineering the light-matter interaction are three challenges for 2D materials-based optics and photonics.

Published

2021

8. Topological phases of matter, symmetries, and K-theory

Author

Thiang, Guo Chuan and Hannabuss, Keith

Subjects

530.15, Quantum theory (mathematics), Theoretical physics, Algebraic topology, Topological matter, K-theory

Abstract

This thesis contains a study of topological phases of matter, with a strong emphasis on symmetry as a unifying theme. We take the point of view that the "topology" in many examples of what is loosely termed "topological matter", has its origin in the symmetry data of the system in question. From the fundamental work of Wigner, we know that topology resides not only in the group of symmetries, but also in the cohomological data of projective unitary-antiunitary representations. Furthermore, recent ideas from condensed matter physics highlight the fundamental role of charge-conjugation symmetry. With these as physical motivation, we propose to study the topological features of gapped phases of free fermions through a Z2-graded C*-algebra encoding the symmetry data of their dynamics. In particular, each combination of time reversal and charge conjugation symmetries can be associated with a Clifford algebra. K-theory is intimately related to topology, representation theory, Clifford algebras, and Z2-gradings, so it presents itself as a powerful tool for studying gapped topological phases. Our basic strategy is to use various K

Published

2014

9. Enhanced weak superconductivity in trigonal γ -PtBi 2 .

Author

Zabala J, Correa VF, Castro FJ, and Pedrazzini P

Abstract

Electrical resistivity experiments show superconductivity atTc=1.1K in a high-quality single crystal of trigonal γ -PtBi 2 , with an enhanced critical magnetic fieldμ0Hc2(0)≳1.5Tesla and a low critical current-densityJc(0)≈40 A cm -2 at H  = 0. Both T c andHc2(0)are the highest reported values for stoichiometric bulk samples at ambient pressure. We found a weakHc2anisotropy withΓ=Hc2ab/Hc2c<1, which is unusual among superconductors. Under a magnetic field, the superconducting transition becomes broader and asymmetric. Along with the low critical currents, this observation suggests an inhomogeneous superconducting state. In fact, no trace of superconductivity is observed through field-cooling-zero-field-cooling magnetization experiments., (© 2024 IOP Publishing Ltd.)

Published

2024

10. Understanding and Manipulation of Emerging Quantum Phases in Topological Insulators

Author

Zhang, Peng

Subjects

Condensed matter physics, Materials Science, Quantum physics, Magnetism, Quantum transport, Topological matter

Abstract

Topological insulator (TI) is a new class of quantum material with inverted band structure caused by strong spin-orbit coupling (SOC), resulting an insulating bulk and topologically protected surface states. By introducing magnetism to break the time-reversal symmetry, it can host emerging topological quantum phases such as quantum anomalous Hall (QAH) effect, axion insulator quantum phase, and can host chiral Majorana fermion when coupled to superconductors. The goal of this dissertation is to study these quantum phases by material growth and transport measurements.First, we studied the growth condition by molecular beam epitaxy (MBE) and achieved high quality magnetically doped topological insulator (MTI) film growth that can host QAH effect. To understand the different origins of zero Hall conductance plateau in QAH insulators and axion insulators, we carried out the thickness dependent study on MTI sandwiched structures and observed a dimension crossover between 2D QAH and 3D axion insulators by minor loops measurements and scaling analysis. Then, we investigated the QAH insulator and antiferromagnetic heterostructures which offer an additional degree of freedom to manipulate the QAH state in MTI. By proximity coupling the QAH insulator to antiferromagnetic insulator Al-Cr2O3, we observed an exchange biased QAH effect, and the exchange bias can be effectively controlled by a field training process. In addition, chiral Majorana edge modes are reported to exist in QAH insulator and superconductors heterostructures. Aiming to understand the discrepancy of recent experimental reports, we fabricated QAH insulator with superconductor and normal metals hybrid devices, and we found the details of material characteristics, interface conditions play important roles on the experiment observations. Finally, two collaborative works closely related to the main scope of this dissertation are introduced. To probe the size limit and to understand the inter-channel scattering of QAH effect, we fabricated mesoscopic scale sub-micron size QAH insulator devices and carried out size dependent studies. Enabled by the successful growth of QAH film on insulating 2D van-der-Waals substrate MICA, we were able to fabricate dual-gate QAH device by exfoliation and transfer techniques. By applying a vertical electric field, we observe a topological phase transition from QAH to a trivial insulator state. This research will greatly improve the understanding of emerging topological quantum physics, and lead to the new revolution of quantum electronic devices.

Published

2021

11. Circular dichroism of chiral Majorana states

Author

Javier Osca and Llorenç Serra

Subjects

chiral states, circular dichroism, Majorana modes, optical absorption, topological matter, Technology, Chemical technology, TP1-1185, Science, Physics, QC1-999

Abstract

Background: Majorana states in condensed matter devices may be of a localized nature, such as in hybrid semiconductor/superconductor nanowires, or chirally propagating along the edges such as in hybrid 2D quantum-anomalous Hall/superconductor structures.Results: We calculate the circular dichroism due to chiral Majorana states in a hybrid structure made of a quantum-anomalous Hall insulator and a superconductor. The optical absorption of chiral Majorana states is characterized by equally spaced absorption peaks of both positive and negative dichroism. In the limit of a very long structure (a 2D ribbon) peaks of a single sign are favored.Conclusion: Circular-dichroism spectroscopy of chiral Majorana states is suggested as a relevant probe for these peculiar states of topological matter.

Published

2018

12. 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

13. 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

14. Chiral Topological Phases in Designed Mechanical Networks

Author

Henrik Ronellenfitsch and Jörn Dunkel

Subjects

mechanical networks, topological matter, Chern insulator, classical mechanics and quantum mechanics, edge modes, Physics, QC1-999

Abstract

Mass-spring networks (MSNs) have long been used as approximate descriptions of biological and engineered systems, from actomyosin networks to mechanical trusses. In the last decade, MSNs have re-attracted theoretical interest as models for phononic metamaterials with exotic properties such as negative Poisson's ratio, negative effective mass, or gapped vibrational spectra. A numerical advantage of MSNs is their tuneability, which allows the inverse design of materials with pre-specified bandgaps. Building on this fact, we demonstrate here that designed MSNs, when subjected to Coriolis forces, can host topologically protected chiral edge modes at predetermined frequencies, thus enabling robust unidirectional transmission of mechanical waves. Similar to other recently discovered topological materials, the topological phases of MSNs can be classified by a Chern invariant related to time-reversal symmetry breaking.

Published

2019

15. Controllable orbital angular momentum monopoles in chiral topological semimetals.

Author

Yen Y, Krieger JA, Yao M, Robredo I, Manna K, Yang Q, McFarlane EC, Shekhar C, Borrmann H, Stolz S, Widmer R, Gröning O, Strocov VN, Parkin SSP, Felser C, Vergniory MG, Schüler M, and Schröter NBM

Abstract

The emerging field of orbitronics aims to generate and control orbital angular momentum for information processing. Chiral crystals are promising orbitronic materials because they have been predicted to host monopole-like orbital textures, where the orbital angular momentum aligns isotropically with the electron's crystal momentum. However, such monopoles have not yet been directly observed in chiral crystals. Here, we use circular dichroism in angle-resolved photoelectron spectroscopy to image orbital angular momentum monopoles in the chiral topological semimetals PtGa and PdGa. The spectra show a robust polar texture that rotates around the monopole as a function of photon energy. This is a direct consequence of the underlying magnetic orbital texture and can be understood from the interference of local atomic contributions. Moreover, we also demonstrate that the polarity of the monopoles can be controlled through the structural handedness of the host crystal by imaging orbital angular moment monopoles and antimonopoles in the two enantiomers of PdGa, respectively. Our results highlight the potential of chiral crystals for orbitronic device applications, and our methodology could enable the discovery of even more complicated nodal orbital angular momentum textures that could be exploited for orbitronics., Competing Interests: Competing interestsThe authors declare no competing interests., (© The Author(s) 2024.)

Published

2024

16. Probing p -wave superconductivity in UTe 2 via point-contact junctions.

Author

Yoon H, Eo YS, Park J, Horn JA, Dorman RG, Saha SR, Hayes IM, Takeuchi I, Brydon PMR, and Paglione J

Abstract

Uranium ditelluride (UTe 2 ) is the strongest contender to date for a p -wave superconductor in bulk form. Here we perform a spectroscopic study of the ambient pressure superconducting phase of UTe 2 , measuring conductance through point-contact junctions formed by metallic contacts on different crystalline facets down to 250 mK and up to 18 T. Fitting a range of qualitatively varying spectra with a Blonder-Tinkham-Klapwijk (BTK) model for p -wave pairing, we can extract gap amplitude and interface barrier strength for each junction. We find good agreement with the data for a dominant p y -wave gap function with amplitude 0.26 ± 0.06 meV. Our work provides spectroscopic evidence for a gap structure consistent with the proposed spin-triplet pairing in the superconducting state of UTe 2 ., Competing Interests: Competing interestsThe authors declare no competing interests., (© The Author(s) 2024.)

Published

2024

17. Computational Methods for Designing Semiconductor Quantum Dot Devices

Author

Manalo, Jacob

Subjects

quantum, machine learning, matrix product states, quantum dots, topological matter, semiconductors, spin, qubit, quantum computing, tensor networks

Abstract

Quantum computers have the potential to solve certain problems in minutes that would otherwise take classical computers thousands of years due to the exponential speed-up certain quantum algorithms have over classical algorithms. In order to leverage such quantum algorithms, it is necessary for them to run on quantum devices. Examples of such devices include, but are not limited to, semiconductor and superconducting qubits, and semiconductor single and entangled photon emitters. The conventional method of constructing a semiconductor qubit is to apply gates on a semiconductor surface to localize electrons, where the electronic spin states are mapped to a qubit basis. Examples of this include the spin qubit where the spin-1/2 states of a single electron is the qubit basis and the gated singlet-triplet qubit where the states of two coupled electrons are mapped to a qubit basis. In general, gated semiconductor spin qubits are subject to decoherence from the environment which alters the electronic wavefunction by entanglement with the nuclear spins and phonons in the lattice compromising the stability of the qubit. Semiconductor nanostructures can also be designed as photon emitters. Self-assembled quantum dots are an example of such nanostructures and have been shown to emit single photons through exciton recombination and entangled photons through biexciton-exciton cascade. The difficulty in designing photon sources using self-assembled quantum dots is that the size and shape varies from dot to dot, implying that the electronic and magnetic properties also vary. In this thesis, I present the design of a single photon emitter using an InAsP quantum dot embedded in an InP nanowire and the design of a singlet-triplet qubit that is topologically protected from decoherence using an array of such quantum dots embedded in an InP nanowire. The advantage of using quantum dot nanowires over self-assembled quantum dots as photon emitters is that the quantum dot thickness, radius and composition can be controlled deterministically using a technique known as vapour-liquid-solid epitaxy which allows the emission spectrum to be engineered. Using a microscopic model, I simulated an InAsP quantum dot embedded in a nanowire with upwards of millions of atoms and showed that the emission spectrum came in agreement with the actual InAsP/InP quantum dot nanowires that were fabricated at the National Research Council of Canada. Moreover, I showed that altering the distribution of As atoms in the quantum dot can cause dramatic change in the emission spectrum. For the design of the topologically protected singlet-triplet qubit, I demonstrated that the ground state of an array of such quantum dots embedded in an InP nanowire, with four electrons in each dot, is four-fold degenerate and is topologically protected from higher energy states, making the ground state robust against perturbations. This state is known as the Haldane phase and can be understood in terms of two spin-1/2 quasiparticles at each edge of the array. Though the spectral gap in my simulation was of the order of 1 meV, this work provides insight into the potential design of a room temperature operating Haldane qubit where the spectral gap is of the order of room temperature.

Published

2023

18. 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

19. Orbital design of Berry curvature: pinch points and giant dipoles induced by crystal fields

Author

Maria Teresa Mercaldo, Canio Noce, Andrea D. Caviglia, Mario Cuoco, and Carmine Ortix

Subjects

Condensed Matter - Materials Science, Topological Matter, Berry Curvature, Condensed Matter - Mesoscale and Nanoscale Physics, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, Quantum Materials, Condensed Matter Physics, Oxide Electronics, Electronic, Optical and Magnetic Materials

Abstract

The Berry curvature (BC) - a quantity encoding the geometric properties of the electronic wavefunctions in a solid - is at the heart of different Hall-like transport phenomena, including the anomalous Hall and the non-linear Hall and Nernst effects. In non-magnetic quantum materials with acentric crystalline arrangements, local concentrations of BC are generally linked to single-particle wavefunctions that are a quantum superposition of electron and hole excitations. BC-mediated effects are consequently observed in two-dimensional systems with pairs of massive Dirac cones and three-dimensional bulk crystals with quartets of Weyl cones. Here, we demonstrate that in materials equipped with orbital degrees of freedom local BC concentrations can arise even in the complete absence of hole excitations. In these solids, the crystals fields appearing in very low-symmetric structures trigger BCs characterized by hot-spots and singular pinch points. These characteristics naturally yield giant BC dipoles and large non-linear transport responses in time-reversal symmetric conditions., 11 pages, 4 figure and supplemental material (6 pages, figures)

Published

2023

20. Symmetry-protected solitons and bulk-boundary correspondence in generalized Jackiw–Rebbi models

Author

Sang Hoon Han, Chang-geun Oh, and Sangmo Cheon

Subjects

Physics, Multidisciplinary, Fermionic field, Field (physics), Science, Degenerate energy levels, Parity (physics), Fermion, Symmetry (physics), Article, Topological defects, symbols.namesake, Nonlinear Sciences::Exactly Solvable and Integrable Systems, Homogeneous space, symbols, Medicine, Soliton, Theoretical physics, Nonlinear Sciences::Pattern Formation and Solitons, Mathematical physics, Topological matter

Abstract

We investigate the roles of symmetry and bulk-boundary correspondence in characterizing topological edge states in generalized Jackiw–Rebbi (JR) models. We show that time-reversal (T), charge-conjugation (C), parity (P), and discrete internal field rotation ($$Z_n$$ Z n ) symmetries protect and characterize the various types of edge states such as chiral and nonchiral solitons via bulk-boundary correspondence in the presence of the multiple vacua. As two representative models, we consider the JR model composed of a single fermion field having a complex mass and the generalized JR model with two massless but interacting fermion fields. The JR model shows nonchiral solitons with the $$Z_2$$ Z 2 rotation symmetry, whereas it shows chiral solitons with the broken $$Z_2$$ Z 2 rotation symmetry. In the generalized JR model, only nonchiral solitons can emerge with only $$Z_2$$ Z 2 rotation symmetry, whereas both chiral and nonchiral solitons can exist with enhanced $$Z_4$$ Z 4 rotation symmetry. Moreover, we find that the nonchiral solitons have C, P symmetries while the chiral solitons do not, which can be explained by the symmetry-invariant lines connecting degenerate vacua. Finally, we find the symmetry correspondence between multiply-degenerate global vacua and solitons such that T, C, P symmetries of a soliton inherit from global minima that are connected by the soliton, which provides a novel tool for the characterization of topological solitons.

Published

2021

21. 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

22. 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

23. Emergence of topological superconductivity in doped topological Dirac semimetals under symmetry-lowering lattice distortions

Author

Sangmo Cheon, Bohm-Jung Yang, Suk Bum Chung, and Ki Hoon Lee

Subjects

Superconductivity, Physics, Multidisciplinary, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity, Science, Dirac (software), FOS: Physical sciences, Topology, Article, Superconducting properties and materials, Superconductivity (cond-mat.supr-con), Lattice (module), Gapless playback, Pairing, Condensed Matter::Superconductivity, Bound state, Homogeneous space, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), Medicine, Phase diagram, Topological matter

Abstract

Recently, unconventional superconductivity having a zero-bias conductance peak is reported in doped topological Dirac semimetal (DSM) with lattice distortion. Motivated by the experiments, we theoretically study the possible symmetry-lowering lattice distortions and their effects on the emergence of unconventional superconductivity in doped topological DSM. We find four types of symmetry-lowering lattice distortions that reproduce the crystal symmetries relevant to experiments from the group-theoretical analysis. Considering inter-orbital and intra-orbital electron density-density interactions, we calculate superconducting phase diagrams. We find that the lattice distortions can induce unconventional superconductivity hosting gapless surface Andreev bound states (SABS). Depending on the lattice distortions and superconducting pairing interactions, the unconventional inversion-odd-parity superconductivity can be either topological nodal superconductivity hosting a flat SABS or topological crystalline superconductivity hosting a gapless SABS. Remarkably, the lattice distortions increase the superconducting critical temperature, which is consistent with the experiments. Our work opens a pathway to explore and control pressure-induced topological superconductivity in doped topological semimetals., Comment: 26 + 14 pages, 8 + 2 figures

Published

2021

24. Isolated skyrmion, skyrmion lattice and antiskyrmion lattice creation through magnetization reversal in Co/Pd nanostructure

Author

V. Satya Narayana Murthy, Sateesh Kandukuri, and P K Thiruvikraman

Subjects

Information storage, Nanostructure, Science, Rotational symmetry, Article, Engineering, Nanoscience and technology, Magnetic properties and materials, Lattice (order), Electronic devices, Topological matter, Spin-½, Physics, Nanoscale materials, Multidisciplinary, Condensed matter physics, Spintronics, Skyrmion, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, Chirality (electromagnetism), Electrical and electronic engineering, Materials science, Nanoscale devices, Ferromagnetism, Medicine, Condensed Matter::Strongly Correlated Electrons, Current density

Abstract

Skyrmion and antiskyrmion spin textures are axisymmetric inhomogeneous localized objects with distinct chirality in magnetic systems. These spin textures are potential candidates for the next generation energy-efficient spintronic applications due to their unique topological properties. Controlled and effective creation of the spin textures is required to use in conventional and neuromorphic computing applications. Here we show by micromagnetic simulations creating an isolated skyrmion, skyrmion lattice and antiskyrmion lattice through the magnetization reversal in Co/Pd multilayer nanostructure using spin-polarized current. The spin textures' stability depends on the spin-polarized current density, current pulse width, and Dzyaloshinskii–Moriya interaction (DMI). Antiskyrmions are evolved during the formation of a single skyrmion and skyrmion lattice. Skyrmion and antiskyrmion lattices together are observed for lower pulse width, 0.05 ns. Our micromagnetic studies suggest that the two distinct lattice phases' evolution could help to design the topological spin textures-based devices.

Published

2021

25. Evaluation of NMR Knight shifts in metallic nanoparticles and topological matter

Author

Papawassiliou, Wassilios and Papawassiliou, Wassilios

Abstract

Elucidating the surface electron states of transition metal compounds is of primary importance in main heterogeneous catalytic processes, such as the hydrogen and oxygen evolution reactions. Key property in all these processes is the position of the energy of the d-band center relative to the Fermi-level of the catalyst; it must be shifted close to the Fermi level to achieve balance between adsorption and desorption of the catalyst and the adsorbate. Often, these processes involve expensive metals such as Ru or Pt, limiting their applicability. The Nickel Phosphide (NixPy) family has recently emerged as an important catalyst family replacing noble metals; in these systems the surface electronic properties, may be tailored by doping with different transition metals, decreasing size, or by controlling the nanoparticle shape (facet engineering). It is thus crucial to be able to simultaneously monitor the evolution of the morphology as well as the electronic structure of the NP particles while scaling down the size. In most of these materials, surface electron states are extremely sensitive to local disturbances, such as impurities, surface defects, as well as surface termination. In contrast, 3D topological insulators like Bi2Se3, or Bi2Te3, exhibit exceptionally robust metallic surface electron states while the bulk interior is insulating. These extraordinary properties, which become dominant by reducing the system size to the nanometers, have been tied to enhancement of the Seebeck effect, i.e., the conversion of heat into electricity, catalytic activity, and electrochemical performance, the latter of these effects has been pursed in this thesis as well. An important question that has eluded however is the presence of the Dirac electrons themselves and to which extend the Dirac electrons penetrate the nanoparticles, controlling thus the overall electronic properties. In contrast to the TIs, Weyl semimetals (WSMs), another category of topological materials, host prot

Published

2022

26. Topological phase transition between a normal insulator and a topological metal state in a quasi-one-dimensional system

Author

Mir Vahid Hosseini and Milad Jangjan

Subjects

Band gap, Science, Point reflection, 02 engineering and technology, Topology, 01 natural sciences, Article, symbols.namesake, Gapless playback, Phase (matter), 0103 physical sciences, Topological order, Condensed-matter physics, 010306 general physics, Topological matter, Physics, Multidisciplinary, Fermi level, State (functional analysis), 021001 nanoscience & nanotechnology, Homogeneous space, symbols, Medicine, Condensed Matter::Strongly Correlated Electrons, 0210 nano-technology

Abstract

We theoretically report the finding of a new kind of topological phase transition between a normal insulator and a topological metal state where the closing-reopening of bandgap is accompanied by passing the Fermi level through an additional band. The resulting nontrivial topological metal phase is characterized by stable zero-energy localized edge states that exist within the full gapless bulk states. Such states living on a quasi-one-dimensional system with three sublattices per unit cell are protected by hidden inversion symmetry. While other required symmetries such as chiral, particle-hole, or full inversion symmetry are absent in the system.

Published

2021

27. Topological magnon insulator and quantized pumps from strongly-interacting bosons in optical superlattices

Author

Feng Mei, Gang Chen, N Goldman, Liantuan Xiao, and Suotang Jia

Subjects

topological matter, ultracold atoms, optical lattices, magnons, quantum transport, Science, Physics, QC1-999

Abstract

Wepropose a scheme realizing topological insulators and quantized pumps for magnon excitations, based on strongly-interacting two-component ultracold atoms trapped in optical superlattices. Specifically, we show how to engineer the Su–Schrieffer–Heeger model for magnons using state-independent superlattices, and the Rice-Mele model using state-dependent superlattices. We describe realistic experimental protocols to detect the topological signatures of magnon excitations in these two models. In particular, we show that the non-equilibrium dynamics of a single magnon can be exploited to directly detect topological winding numbers and phase transitions. We also describe how topological (quantized) pumps can be realized with magnons, and study how this phenomenon depends on the initial magnon state preparation. Our study opens a new avenue for exploring magnonic topological phases of matter and their potential applications in the context of topological magnon transport.

Published

2019

28. Uniaxial strain-induced phase transition in the 2D topological semimetal IrTe2

Author

Nicholson, Christopher W, Rumo, Maxime, Pulkkinen, Aki, Kremer, Geoffroy, Salzmann, Björn, Mottas, Marie-Laure, Hildebrand, Baptiste, Jaouen, Thomas, Kim, Timur K, Mukherjee, Saumya, Ma, KeYuan, Muntwiler, Matthias, von Rohr, Fabian O, Cacho, Cephise, Monney, Claude, University of Zurich, University of Fribourg, Institut de Physique de Rennes (IPR), Université de Rennes 1 (UR1), Université de Rennes (UNIV-RENNES)-Université de Rennes (UNIV-RENNES)-Centre National de la Recherche Scientifique (CNRS), DIAMOND Light source, Universität Zürich [Zürich] = University of Zurich (UZH), Paul Scherrer Institute (PSI), Université de Fribourg = University of Fribourg (UNIFR), Université de Rennes (UR)-Centre National de la Recherche Scientifique (CNRS), and This project was supported through the Swiss National Science Foundation (SNSF), Grant No. P00P2_170597. We gratefully acknowledge beam time from Diamond light source (proposal SI24880, beamline I05) and the Swiss light source (proposal 20170698, PEARL beamline). A.P. acknowledges the Osk. Huttunen Foundation for financial support, and the CSC–IT Center for Science, Finland, for computational resources. The work at the University of Zurich was supported by the Swiss National Science Foundation under Grant No. PZ00P2_174015.

Subjects

Surfaces, 10120 Department of Chemistry, Condensed Matter::Materials Science, Electronic properties and materials, interfaces and thin films, 540 Chemistry, [PHYS.COND.CM-MS]Physics [physics]/Condensed Matter [cond-mat]/Materials Science [cond-mat.mtrl-sci], TA401-492, 10192 Physics Institute, Two-dimensional materials, Materials of engineering and construction. Mechanics of materials, ComputingMilieux_MISCELLANEOUS, Topological matter

Abstract

International audience; Strain is ubiquitous in solid-state materials, but despite its fundamental importance and technological relevance, leveraging externally applied strain to gain control over material properties is still in its infancy. In particular, strain control over the diverse phase transitions and topological states in two-dimensional transition metal dichalcogenides remains an open challenge. Here, we exploit uniaxial strain to stabilize the long-debated structural ground state of the 2D topological semimetal IrTe2, which is hidden in unstrained samples. Combined angle-resolved photoemission spectroscopy and scanning tunneling microscopy data reveal the strain-stabilized phase has a 6 × 1 periodicity and undergoes a Lifshitz transition, granting unprecedented spectroscopic access to previously inaccessible type-II topological Dirac states that dominate the modified inter-layer hopping. Supported by density functional theory calculations, we show that strain induces an Ir to Te charge transfer resulting in strongly weakened inter-layer Te bonds and a reshaped energetic landscape favoring the 6×1 phase. Our results highlight the potential to exploit strain-engineered properties in layered materials, particularly in the context of tuning inter-layer behavior.

Published

2021

29. Multi-critical topological transition at quantum criticality

Author

S Rahul, Ranjith R Kumar, Y R Kartik, and Sujit Sarkar

Subjects

Quantum phase transition, Science, FOS: Physical sciences, 02 engineering and technology, Topology, 01 natural sciences, Article, Superconducting properties and materials, Condensed Matter - Strongly Correlated Electrons, Gapless playback, Correlation function, Critical line, 0103 physical sciences, 010306 general physics, Topological matter, Physics, Multidisciplinary, Strongly Correlated Electrons (cond-mat.str-el), Winding number, Renormalization group, 021001 nanoscience & nanotechnology, Universality (dynamical systems), Medicine, Ising model, 0210 nano-technology

Abstract

The investigation and characterization of topological quantum phase transition between gapless phases is one of the recent interest of research in topological states of matter. We consider transverse field Ising model with three spin interaction in one dimension and observe a topological transition between gapless phases on one of the critical lines of this model. We study the distinct nature of these gapless phases and show that they belong to different universality classes. The topological invariant number (winding number) characterize different topological phases for the different regime of parameter space. We observe the evidence of two multi-critical points, one is topologically trivial and the other one is topologically active. Topological quantum phase transition between the gapless phases on the critical line occurs through the non-trivial multi-critical point in the Lifshitz universality class. We calculate and analyze the behavior of Wannier state correlation function close to the multi-critical point and confirm the topological transition between gapless phases. We show the breakdown of Lorentz invariance at this multi-critical point through the energy dispersion analysis. We also show that the scaling theories and curvature function renormalization group can also be effectively used to understand the topological quantum phase transitions between gapless phases. The model Hamiltonian which we study is more applicable for the system with gapless excitations, where the conventional concept of topological quantum phase transition fails., 23 pages (including appendices), 13 figures. Recently revised version with modified figures, additional references and discussions

Published

2021

30. Quantum topological phase transitions in skyrmion crystals

Author

Kristian Mæland and Asle Sudbo

Subjects

Strongly Correlated Electrons (cond-mat.str-el), Statistical Mechanics (cond-mat.stat-mech), Condensed Matter - Mesoscale and Nanoscale Physics, Condensed matter physics: 436 [VDP], FOS: Physical sciences, General Physics and Astronomy, Topological phase transitions, Topologisk materie, Condensed Matter - Strongly Correlated Electrons, Classical and quantum mechanical critical phenomena, Kondenserte fasers fysikk: 436 [VDP], Mesoscale and Nanoscale Physics (cond-mat.mes-hall), Topologiske faseoverganger, Klassiske og kvantemekaniske kritiske fenomen, Condensed Matter - Statistical Mechanics, Topological matter

Abstract

Topological order is important in many aspects of condensed matter physics, and has been extended to bosonic systems. In this Letter we report on the nontrivial topology of the magnon bands in two distinct quantum skyrmion crystals appearing in zero external magnetic field. This is revealed by nonzero Chern numbers for some of the bands. As a bosonic analog of the quantum anomalous Hall effect, we show that topological magnons can appear in skyrmion crystals without explicitly breaking time-reversal symmetry with an external magnetic field. By tuning the value of the easy-axis anisotropy at zero temperature, we find eight quantum topological phase transitions signaled by discontinuous jumps in certain Chern numbers. We connect these quantum topological phase transitions to gaps closing and reopening between magnon bands., 6+17 pages, 2+3 figures, includes supplemental material, accepted in Physical Review Research

Published

2022

31. Strategies for braiding and ground state preparation in digital quantum hardware

Author

Herasymenko, Y., Beenakker, C.W.J., O'Brien, T.E., Gefen, Y., Terhal, B.M., Aarts, J., Löffler, W., Zaanen, J., and Leiden University

Subjects

Ground state preparation, NISQ, ComputerSystemsOrganization_MISCELLANEOUS, Quantum computers, Braiding, Topological matter

Abstract

With the help of quantum mechanics, digital quantum hardware may be able to tackle some of the problems that are too difficult for ordinary computers. But despite these expectations and the ongoing effort of the research community, reliable quantum computers are not yet realized in a lab setting. The optimal strategies for early applications of such special hardware are not settled either. The present thesis addresses these issues of implementing and harnessing quantum computers.Firstly, several strategies are introduced to implement and characterize digital quantum hardware using the technique called braiding. Two realizations are considered: the edge modes of topological superconductors and the parafermionic modes in Fractional Quantum Hall materials.Secondly, this work explores applying quantum computers to prepare simulated ground states (lowest-energy configurations) of complex quantum systems. To this end, several new techniques are presented in the context of variational quantum algorithms, simulated cooling, and quantum control theory.

Published

2022

32. 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

33. Bulk and surface topological indices for a skyrmion string: current-driven dynamics of skyrmion string in stepped samples

Author

Naoto Nagaosa and Wataru Koshibae

Subjects

Physics, Surface (mathematics), Multidisciplinary, Texture (cosmology), Skyrmion, lcsh:R, Magnetic monopole, lcsh:Medicine, Charge (physics), Spintronics, 02 engineering and technology, Magnetic skyrmion, 021001 nanoscience & nanotechnology, Topology, Space (mathematics), Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, 01 natural sciences, String (physics), Article, 0103 physical sciences, lcsh:Q, 010306 general physics, 0210 nano-technology, lcsh:Science, Topological matter

Abstract

The magnetic skyrmion is a topological magnetic vortex, and its topological nature is characterized by an index called skyrmion number which is a mapping of the magnetic moments defined on a two-dimensional space to a unit sphere. In three-dimensions, a skyrmion, i.e., a vortex penetrating though the magnet naturally forms a string, which terminates at the surfaces of the magnet or in the bulk. For such a string, the topological indices, which control its topological stability are less trivial. Here, we study theoretically, in terms of numerical simulation, the dynamics of current-driven motion of a skyrmion string in a film sample with the step edges on the surface. In particular, skyrmion–antiskyrmion pair is generated by driving a skyrmion string through the side step with an enough height. We find that the topological indices relevant to the stability are the followings; (1) skyrmion number along the developed surface, and (2) the monopole charge in the bulk defined as the integral over the surface enclosing a singular magnetic configuration. As long as the magnetic configuration is slowly varying, the former is conserved while its changes is associated with nonzero monopole charge. The skyrmion number and the monoplole charge offer a coherent understanding of the stability of the topological magnetic texture and the nontrivial dynamics of skyrmion strings.

Published

2020

34. Particle-size dependent structural transformation of skyrmion lattice

Author

V. Ukleev, Rina Takagi, Shinichiro Seki, Yoshinori Tokura, H. Nakao, Taka-hisa Arima, Yuichi Yamasaki, Tomoyuki Yokouchi, and Yuichi Yokoyama

Subjects

Phase transition, Science, General Physics and Astronomy, 02 engineering and technology, Magnetic skyrmion, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, Topological defect, Magnetic properties and materials, Lattice (order), 0103 physical sciences, lcsh:Science, 010306 general physics, Nonlinear Sciences::Pattern Formation and Solitons, Topological matter, Physics, Condensed Matter::Quantum Gases, Multidisciplinary, Condensed matter physics, Scattering, Skyrmion, High Energy Physics::Phenomenology, General Chemistry, 021001 nanoscience & nanotechnology, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, Magnetic field, Magnet, lcsh:Q, 0210 nano-technology

Abstract

Magnetic skyrmion is a topologically protected particle-like object in magnetic materials, appearing as a nanometric swirling spin texture. The size and shape of skyrmion particles can be flexibly controlled by external stimuli, which suggests unique features of their crystallization and lattice transformation process. Here, we investigated the detailed mechanism of structural transition of skyrmion lattice (SkL) in a prototype chiral cubic magnet Cu2OSeO3, by combining resonant soft X-ray scattering (RSXS) experiment and micromagnetic simulation. This compound is found to undergo a triangular-to-square lattice transformation of metastable skyrmions by sweeping magnetic field (B). Our simulation suggests that the symmetry change of metastable SkL is mainly triggered by the B-induced modification of skyrmion core diameter and associated energy cost at the skyrmion-skyrmion interface region. Such internal deformation of skyrmion particle has further been confirmed by probing the higher harmonics in the RSXS pattern. These results demonstrate that the size/shape degree of freedom of skyrmion particle is an important factor to determine their stable lattice form, revealing the exotic manner of phase transition process for topological soliton ensembles in the non-equilibrium condition., Skyrmions are topological spin textures and are of great interest due to their impressive stability. Here, by sweeping an applied magnetic field, the authors observe a change in the skyrmion lattice structure, shedding light on the relation between skyrmion size and stability.

Published

2020

35. Realization of acoustic spin transport in metasurface waveguides

Author

Danmei Zhang, Chenwen Yang, Yang Long, Jie Ren, Jianmin Ge, and Hong Chen

Subjects

Science, General Physics and Astronomy, Physics::Optics, 02 engineering and technology, 01 natural sciences, Electromagnetic radiation, Article, General Biochemistry, Genetics and Molecular Biology, law.invention, law, 0103 physical sciences, 010306 general physics, Spin (physics), lcsh:Science, Topological matter, Coupling, Physics, Multidisciplinary, Condensed matter physics, Texture (cosmology), Acoustics, General Chemistry, Acoustic wave, 021001 nanoscience & nanotechnology, Reflection (physics), Condensed Matter::Strongly Correlated Electrons, lcsh:Q, 0210 nano-technology, Waveguide, Longitudinal wave

Abstract

Spin angular momentum enables fundamental insights for topological matters, and practical implications for information devices. Exploiting the spin of carriers and waves is critical to achieving more controllable degrees of freedom and robust transport processes. Yet, due to the curl-free nature of longitudinal waves distinct from transverse electromagnetic waves, spin angular momenta of acoustic waves in solids and fluids have never been unveiled only until recently. Here, we demonstrate a metasurface waveguide for sound carrying non-zero acoustic spin with tight spin-momentum coupling, which can assist the suppression of backscattering when scatters fail to flip the acoustic spin. This is achieved by imposing a soft boundary of the π reflection phase, realized by comb-like metasurfaces. With the special-boundary-defined spin texture, the acoustic spin transports are experimentally manifested, such as the suppression of acoustic corner-scattering, the spin-selected acoustic router with spin-Hall-like effect, and the phase modulator with rotated acoustic spin., Spin angular momenta play a crucial role in topological phases of matter, in acoustic waves they have been demonstrated recently. Here, the authors present a symmetry-breaking metasurface waveguide that assists backscattering suppression of acoustic waves, because of tight spin-momentum coupling.

Published

2020

36. Synthetic band-structure engineering in polariton crystals with non-Hermitian topological phases

Author

Lucinda Pickup, Pavlos G. Lagoudakis, Janne Ruostekoski, and Helgi Sigurdsson

Subjects

0301 basic medicine, Science, High Energy Physics::Lattice, General Physics and Astronomy, Polaritons, FOS: Physical sciences, Physics::Optics, 02 engineering and technology, Crystal structure, Topology, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, All optical, Lattice (order), Mesoscale and Nanoscale Physics (cond-mat.mes-hall), Polariton, Electronic band structure, lcsh:Science, Topological matter, Physics, Condensed Matter::Quantum Gases, Multidisciplinary, Condensed Matter - Mesoscale and Nanoscale Physics, Bose-Einstein condensates, General Chemistry, 021001 nanoscience & nanotechnology, Hermitian matrix, 030104 developmental biology, Excited state, lcsh:Q, 0210 nano-technology

Abstract

Synthetic crystal lattices provide ideal environments for simulating and exploring the band structure of solid-state materials in clean and controlled experimental settings. Physical realisations have, so far, dominantly focused on implementing irreversible patterning of the system, or interference techniques such as optical lattices of cold atoms. Here, we realise reprogrammable synthetic band-structure engineering in an all optical exciton-polariton lattice. We demonstrate polariton condensation into excited states of linear one-dimensional lattices, periodic rings, dimerised non-trivial topological phases, and defect modes utilising malleable optically imprinted non-Hermitian potential landscapes. The stable excited nature of the condensate lattice with strong interactions between sites results in an actively tuneable non-Hermitian analogue of the Su-Schrieffer-Heeger system., To simulate band structures of solid state materials synthetic lattices are usually generated by optical lattices or by irreversible patterning the system. Here, the authors present reconfigurable synthetic band-structures in optical exciton-polariton lattices and generate non-Hermitian topological phases.

Published

2020

37. Real-space recipes for general topological crystalline states

Author

Chen Fang, Yang Qi, and Zhida Song

Subjects

0301 basic medicine, Computer science, Science, FOS: Physical sciences, General Physics and Astronomy, 02 engineering and technology, Symmetry group, Space (mathematics), Topology, Article, General Biochemistry, Genetics and Molecular Biology, Condensed Matter - Strongly Correlated Electrons, 03 medical and health sciences, Topological insulators, Wallpaper group, lcsh:Science, Equivalence (measure theory), Topological matter, Boson, Condensed Matter::Quantum Gases, Multidisciplinary, Strongly Correlated Electrons (cond-mat.str-el), General Chemistry, Fermion, 021001 nanoscience & nanotechnology, 030104 developmental biology, Scheme (mathematics), Homogeneous space, lcsh:Q, 0210 nano-technology

Abstract

Topological crystalline states are short-range entangled states jointly protected by onsite and crystalline symmetries. While the non-interacting limit of these states, e.g., the topological crystalline insulators, have been intensively studied in band theory and have been experimentally discovered, the classification and diagnosis of their strongly interacting counterparts are relatively less well understood. Here we present a unified scheme for constructing all topological crystalline states, bosonic and fermionic, free and interacting, from real-space "building blocks" and "connectors". Building blocks are finite-size pieces of lower dimensional topological states protected by onsite symmetries alone, and connectors are "glue" that complete the open edges shared by two or multiple pieces of building blocks. The resulted assemblies are selected against two physical criteria we call the "no-open-edge condition" and the "bubble equivalence", which, respectively, ensure that each selected assembly is gapped in the bulk and cannot be deformed to a product state. The scheme is then applied to obtaining the full classification of bosonic topological crystalline states protected by several onsite symmetry groups and each of the 17 wallpaper groups in two dimensions and 230 space groups in three dimensions. We claim that our real-space recipes give the complete set of topological crystalline states for bosons and fermions, and prove the boson case analytically using a spectral sequence expansion of group cohomology., 17+44 pages, 7+1 figures, 0+2 tables. The content is the same as the published version, but arranged differently

Published

2020

38. Creation of acoustic vortex knots

Author

Yunhong Liao, Gengkai Hu, Junfei Li, Xiaoming Zhou, Xiangdong Zhang, Hongkuan Zhang, and Weixuan Zhang

Subjects

0301 basic medicine, Science, Holography, General Physics and Astronomy, Physics::Optics, 02 engineering and technology, Optical field, Article, General Biochemistry, Genetics and Molecular Biology, Techniques and instrumentation, law.invention, 03 medical and health sciences, Knot (unit), law, Condensed Matter::Superconductivity, lcsh:Science, Topological matter, Trefoil knot, Physics, Multidisciplinary, Computer simulation, Metamaterial, Acoustics, General Chemistry, 021001 nanoscience & nanotechnology, Mathematics::Geometric Topology, Vortex, 030104 developmental biology, Classical mechanics, Hopf link, Computer Science::Sound, lcsh:Q, 0210 nano-technology

Abstract

Knots and links have been conjectured to play a fundamental role in a wide range of scientific fields. Recently, tying isolated vortex knots in the complex optical field has been realized. However, how to construct the acoustic vortex knot is still an unknown problem. Here we propose theoretically and demonstrate experimentally the creation of acoustic vortex knots using metamaterials, with decoupled modulation of transmitted phase and amplitude. Based on the numerical simulation, we find that the knot function can be embedded into the acoustic field by designed metamaterials with only 24 × 24 pixels. Furthermore, using the optimized metamaterials, the acoustic fields with Hopf link and trefoil knot vortex lines have been observed experimentally., Although knots in complex optical fields have been realized experimentally, the realization of acoustic vortex knots is still problematic. Here, the authors have demonstrated the creation of acoustic vortex knots by embedding the knot function into a propagating acoustic field using a metasurface hologram.

Published

2020

39. Observation of Dirac state in half-Heusler material YPtBi

Author

M. Mofazzel Hosen, Christopher Sims, Klauss Dimitri, Firoza Kabir, Piotr Wiśniewski, Hong Chul Choi, Jian-Xin Zhu, Dariusz Kaczorowski, Tomasz Durakiewicz, Madhab Neupane, Gyanendra Dhakal, and Orest Pavlosiuk

Subjects

Electronic properties and materials, Photoemission spectroscopy, Dirac (software), FOS: Physical sciences, lcsh:Medicine, 02 engineering and technology, Computer Science::Digital Libraries, 01 natural sciences, Article, symbols.namesake, 0103 physical sciences, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), Antiferromagnetism, 010306 general physics, Condensed-matter physics, lcsh:Science, Surface states, Topological matter, Physics, Superconductivity, Condensed Matter - Materials Science, Multidisciplinary, Condensed matter physics, Condensed Matter - Mesoscale and Nanoscale Physics, Fermi level, lcsh:R, Materials Science (cond-mat.mtrl-sci), Fermi surface, 021001 nanoscience & nanotechnology, Brillouin zone, Computer Science::Mathematical Software, symbols, Condensed Matter::Strongly Correlated Electrons, lcsh:Q, 0210 nano-technology

Abstract

The prediction of non-trivial topological electronic states hosted by half-Heusler compounds makes them prime candidates for discovering new physics and devices as they harbor a variety of electronic ground states including superconductivity, magnetism, and heavy fermion behavior. Here we report normal state electronic properties of a superconducting half-Heusler compound YPtBi using angle-resolved photoemission spectroscopy (ARPES). Our data reveal the presence of a Dirac state at the zone center of the Brillouin zone at 500 meV below the chemical potential. We observe the presence of multiple Fermi surface pockets including two concentric hexagonal and six half oval shaped pockets at the gamma and K points of the Brillouin zone, respectively. Furthermore, our measurements show Rashba-split bands and multiple surface states crossing the chemical potential which are supported by the first-principles calculations. Our finding of a Dirac state in YPtBi plays a significant role in establishing half-Heusler compounds as a new potential platform for novel topological phases and explore their connection with superconductivity., 6 pages, 4 figures

Published

2020

40. Quantum valley Hall effect in wide-gap semiconductor SiC monolayer

Author

Cheol Eui Lee and Kyu Won Lee

Subjects

Materials science, Quantum Hall, lcsh:Medicine, 02 engineering and technology, 01 natural sciences, Article, Condensed Matter::Materials Science, Gapless playback, Hall effect, 0103 physical sciences, Monolayer, 010306 general physics, lcsh:Science, Topological matter, Multidisciplinary, Condensed matter physics, business.industry, Doping, lcsh:R, 021001 nanoscience & nanotechnology, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, Semiconductor, Charge carrier, Density functional theory, lcsh:Q, Berry connection and curvature, 0210 nano-technology, business

Abstract

We have investigated the valley Chern number and gapless edge states in wide-gap semiconductor SiC and BN monolayers by using the density functional theory calculations. We found that while SiC monolayer has a non-quantized valley Chern number due to a partial mixing of the Berry curvature peaks pertaining to the opposite valleys, there exist topologically protected gapless edge states within the bulk gap, leading to a quantum valley Hall effect. Doping of the opposite charge carriers causes a backscattering-free valley current flowing on the opposite edge, which can be used for experimental confirmation and application at room temperature. BN monolayer, on the other hand, was found to have gapped edge states due to the too large staggered AB-sublattice potentials.

Published

2020

41. Lasing with Topological Weyl Semimetal

Author

Güneş Oktay, Mustafa Sarisaman, and Murat Tas

Subjects

Surface (mathematics), FOS: Physical sciences, Weyl semimetal, Physics::Optics, lcsh:Medicine, 02 engineering and technology, Topology, Quantum mechanics, 01 natural sciences, Article, symbols.namesake, Optical physics, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), 0103 physical sciences, Lasers, LEDs and light sources, 010306 general physics, lcsh:Science, Topological matter, Physics, Quantum optics, Quantum Physics, Multidisciplinary, Birefringence, Condensed Matter - Mesoscale and Nanoscale Physics, lcsh:R, Coherent perfect absorber, 021001 nanoscience & nanotechnology, Transfer matrix, Reflection (mathematics), Maxwell's equations, symbols, lcsh:Q, Quantum Physics (quant-ph), 0210 nano-technology, Lasing threshold, Physics - Optics, Optics (physics.optics)

Abstract

Lasing behavior of optically active planar topological Weyl semimetal (TWS) is investigated in view of the Kerr and Faraday rotations. Robust topological character of TWS is revealed by the presence of Weyl nodes and relevant surface conductivities. We focus our attention on the surfaces where no Fermi arcs are formed, and thus Maxwell equations contain topological terms. We explicitly demonstrate that two distinct lasing modes arise because of the presence of effective refractive indices which lead to the birefringence phenomena. Transfer matrix is constructed in such a way that reflection and transmission amplitudes involve $2\times2$ matrix-valued components describing the bimodal character of the TWS laser. We provide associated parameters of the topological laser system yielding the optimal impacts. We reveal that gain values corresponding to the lasing threshold display a quantized behavior, which occurs due to topological character of the system. Our proposal is supported by the corresponding graphical demonstrations. Our observations and predictions suggest a concrete way of forming TWS laser and coherent perfect absorber; and are awaited to be confirmed by an experimental realization based on our computations., Comment: 17 pages, 9 figures, 3 tables

Published

2020

42. Ground state anomalies in SmB6

Author

Anup Pradhan Sakhya and Kalobaran Maiti

Subjects

Electronic properties and materials, lcsh:Medicine, Angle-resolved photoemission spectroscopy, 02 engineering and technology, 01 natural sciences, Article, symbols.namesake, Magnetic properties and materials, 0103 physical sciences, 010306 general physics, Condensed-matter physics, lcsh:Science, Topological matter, Physics, Theory and computation, Multidisciplinary, Condensed matter physics, Electronic correlation, Exchange interaction, Fermi level, lcsh:R, Quantum oscillations, Fermi surface, 021001 nanoscience & nanotechnology, symbols, Density functional theory, lcsh:Q, 0210 nano-technology, Ground state

Abstract

SmB6 has drawn much attention in recent times due to the discovery of anomalies in its ground state properties as well as prediction of topologically protected gapless surface states. Varied theories have been proposed to capture the ground state anomalies. Here, we studied the electronic structure of SmB6 employing density functional theory using different exchange correlation potentials, spin-orbit coupling and electron correlation strength. We discover that a suitable choice of interaction parameters such as spin-orbit coupling, electron correlation strength and exchange interaction within the generalized gradient approximation provides a good description of the spectral functions observed in the angle-resolved photoemission spectroscopy (ARPES) studies. The Fermi surface plots exhibit electron pockets around X-point and hole pockets around ΓX line having dominant Sm 4f character. These observations corroborate well with the recent experimental results involving quantum oscillation measurements, ARPES, etc. In addition to primarily Sm 4f contributions observed at the Fermi level, the results exhibit significantly large contribution from B 2p states compared to weak Sm 5d contributions. This suggests important role of B 2p - Sm 4f hybridization in the exotic physics of this system.

Published

2020

43. 3D sub-pixel correlation length imaging

Author

Christian Grünzweig, Jan Hovind, R. P. Harti, Jacopo Valsecchi, and Markus Strobl

Subjects

lcsh:Medicine, 02 engineering and technology, computer.software_genre, 01 natural sciences, Article, Neutron wavelength, Optics, Voxel, 0103 physical sciences, Range (statistics), Structure of solids and liquids, Neutron, lcsh:Science, Topological matter, 010302 applied physics, Physics, Multidisciplinary, Scattering, business.industry, Resolution (electron density), lcsh:R, 021001 nanoscience & nanotechnology, Pixel correlation, lcsh:Q, Tomography, 0210 nano-technology, business, computer

Abstract

Quantitative 2D neutron dark-field-imaging with neutron grating interferometry has been used to characterize structures in the size range below the imaging resolution. We present the first 3D quantitative neutron dark-field imaging experiment. We characterize sub-pixel structure sizes below the imaging resolution in tomography by quantitatively analyzing the change in dark-field contrast with varying neutron wavelength. This proof of principle experiment uses a dedicated reference sample with four different solutions of microspheres, each with a different diameter. The result is a 3D tomogram featuring a real space scattering function in each voxel. The presented experiment is expected to mark the path for future material science research through the individual quantification of small-angle scattering structures in each voxel of a volume of a bulk inhomogeneous sample material.

Published

2020

44. Plethora of tunable Weyl fermions in kagome magnet Fe3Sn2 thin films

Author

Zheng Ren, Hong Li, Shrinkhala Sharma, Dipak Bhattarai, He Zhao, Bryan Rachmilowitz, Faranak Bahrami, Fazel Tafti, Shiang Fang, Madhav Prasad Ghimire, Ziqiang Wang, and Ilija Zeljkovic

Subjects

Condensed Matter - Materials Science, Surfaces, interfaces and thin films, Condensed Matter - Mesoscale and Nanoscale Physics, semimetal phase, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), dirac-fermions, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, Condensed Matter Physics, Topological matter, Electronic, Optical and Magnetic Materials

Abstract

Interplay of magnetism and electronic band topology in unconventional magnets enables the creation and fine control of novel electronic phenomena. In this work, we use scanning tunneling microscopy and spectroscopy to study thin films of a prototypical kagome magnet Fe3Sn2. Our experiments reveal an unusually large number of densely-spaced spectroscopic features straddling the Fermi level. These are consistent with signatures of low-energy Weyl fermions and associated topological Fermi arc surface states predicted by theory. By measuring their response as a function of magnetic field, we discover a pronounced evolution in energy tied to the magnetization direction. Electron scattering and interference imaging further demonstrates the tunable nature of a subset of related electronic states. Our experiments provide a direct visualization of how in-situ spin reorientation drives changes in the electronic density of states of the Weyl fermion band structure. Combined with previous reports of massive Dirac fermions, flat bands, and electronic nematicity, our work establishes Fe3Sn2 as an interesting platform that harbors an extraordinarily wide array of topological and correlated electron phenomena.

Published

2022

45. Formal derivation of the Laughlin function and its generalization for other topological phases of FQHE

Author

Janusz Edward Jacak

Subjects

Multidisciplinary, Science, Medicine, Quantum Hall, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, Article, Topological matter

Abstract

Using the braid symmetry we demonstrate the derivation of the Laughlin function for the main hierarchy 1/q of FQHE in the lowest Landau level of two-dimensional electron system with a mathematical rigour. This proves that the derivation of Laughlin function unavoidably requires some topological elements and cannot be completed within a local quantum mechanics, i.e., without global topological constraints imposed. The method shows the way for the generalization of this function onto other fractions from the general quantum Hall hierarchy. A generalization of the Laughlin function is here formulated.

Published

2022

46. Magnetic monopole density and antiferromagnetic domain control in spin-ice iridates

Author

Pearce, MJ, Götze, K, Szabó, A, Sikkenk, TS, Lees, MR, Boothroyd, AT, Prabhakaran, D, Castelnovo, C, Goddard, PA, Götze, K [0000-0001-9108-9490], Lees, MR [0000-0002-2270-2295], Boothroyd, AT [0000-0002-3575-7471], Castelnovo, C [0000-0003-1752-6343], Apollo - University of Cambridge Repository, and Castelnovo, Claudio [0000-0003-1752-6343]

Subjects

639/766/119/995, Electronic properties and materials, Multidisciplinary, Science, 639/766/119, article, General Physics and Astronomy, General Chemistry, General Biochemistry, Genetics and Molecular Biology, Magnetic properties and materials, 639/766/119/2792, Condensed Matter::Strongly Correlated Electrons, ddc:500, cond-mat.str-el, Condensed-matter physics, QC, 639/766/119/997, Topological matter

Abstract

Nature Communications 13(1), 444 (2022). doi:10.1038/s41467-022-27964-y, Magnetically frustrated systems provide fertile ground for complex behaviour, including unconventional ground states with emergent symmetries, topological properties, and exotic excitations. A canonical example is the emergence of magnetic-charge-carrying quasiparticles in spin-ice compounds. Despite extensive work, a reliable experimental indicator of the density of these magnetic monopoles is yet to be found. Using measurements on single crystals of Ho$_2$Ir$_2$O$_7$ combined with dipolar Monte Carlo simulations, we show that the isothermal magnetoresistance is highly sensitive to the monopole density. Moreover, we uncover an unexpected and strong coupling between the monopoles on the holmium sublattice and the antiferromagnetically ordered iridium ions. These results pave the way towards a quantitative experimental measure of monopole density and demonstrate the ability to control antiferromagnetic domain walls using a uniform external magnetic field, a key goal in the design of next-generation spintronic devices., Published by Nature Publishing Group UK, [London]

Published

2022

47. Phase shift in skyrmion crystals

Author

Satoru Hayami, Yukitoshi Motome, and Tsuyoshi Okubo

Subjects

Magnetism, Science, Phase (waves), FOS: Physical sciences, General Physics and Astronomy, Thermal fluctuations, Magnetic skyrmion, Article, General Biochemistry, Genetics and Molecular Biology, Condensed Matter - Strongly Correlated Electrons, Magnetic properties and materials, Nonlinear Sciences::Pattern Formation and Solitons, Computer Science::Databases, Topological matter, Spin-½, Condensed Matter::Quantum Gases, Physics, Multidisciplinary, Strongly Correlated Electrons (cond-mat.str-el), Condensed matter physics, Spins, Texture (cosmology), Skyrmion, High Energy Physics::Phenomenology, Spintronics, General Chemistry, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect

Abstract

The magnetic skyrmion crystal is a periodic array of a swirling topological spin texture. Since it is regarded as an interference pattern by multiple helical spin density waves, the texture changes with the relative phase shifts among the constituent waves. Although such a phase degree of freedom is relevant to not only magnetism but also transport properties, its effect has not been elucidated thus far. We here theoretically show that a phase shift in the skyrmion crystals leads to a tetra-axial vortex crystal and a meron-antimeron crystal, both of which show a staggered pattern of the scalar spin chirality and give rise to nonreciprocal transport phenomena without the spin-orbit coupling. We demonstrate that such a phase shift can be driven by exchange interactions between the localized spins, thermal fluctuations, and long-range chirality interactions in spin-charge coupled systems. Our results provide a further diversity of topological spin textures and open a new field of emergent electromagnetism by the phase shift engineering., Skyrmions are a type of topological spin texture, which can exist as both an isolated state, and as a skyrmion crystal. Here, Hayami et al present a theoretical study of phase shifts in skyrmion crystals, showing how such phase shifts can lead to other crystalline topological spin textures.

Published

2021

48. Nontrivial band geometry in an optically active system

Author

Guillaume Malpuech, Feng Li, Jiahuan Ren, Jiannian Yao, Qing Liao, Dmitry Solnyshkov, Hongbing Fu, O. Bleu, Yiming Li, Institut Pascal (IP), SIGMA Clermont (SIGMA Clermont)-Centre National de la Recherche Scientifique (CNRS)-Université Clermont Auvergne [2017-2020] (UCA [2017-2020]), SIGMA Clermont (SIGMA Clermont)-Université Clermont Auvergne [2017-2020] (UCA [2017-2020])-Centre National de la Recherche Scientifique (CNRS), and ANR-16-CE30-0021,QFL,Fluides Quantiques de Lumière(2016)

Subjects

Science, General Physics and Astronomy, FOS: Physical sciences, Physics::Optics, 02 engineering and technology, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, symbols.namesake, Planar, 0103 physical sciences, Faraday effect, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), 010306 general physics, Quantum, Topological matter, Physics, [PHYS]Physics [physics], Multidisciplinary, Birefringence, Condensed Matter - Mesoscale and Nanoscale Physics, business.industry, Linear polarization, General Chemistry, 021001 nanoscience & nanotechnology, Symmetry (physics), Optics and photonics, symbols, Optoelectronics, Berry connection and curvature, Photonics, 0210 nano-technology, business, Physics - Optics, Optics (physics.optics)

Abstract

Optical activity, also called circular birefringence, is known for two hundred years, but its applications for topological photonics remain unexplored. Unlike the Faraday effect, the optical activity provokes rotation of the linear polarization of light without magnetic effects, thus preserving the time-reversal symmetry. In this work, we report a direct measurement of the Berry curvature and quantum metric of the photonic modes of a planar cavity, containing a birefringent organic microcrystal (perylene) and exhibiting emergent optical activity. This experiment, performed at room temperature and at visible wavelength, establishes the potential of organic materials for implementing non-magnetic and low-cost topological photonic devices., Most work in topological photonics is performed in periodically structured systems. Here, the authors directly measure the nontrivial Berry curvature of the photonic modes of a birefringent continuous organic system exhibiting emergent optical activity.

Published

2021

49. Anisotropic scaling for 3D topological models

Author

Nei Lopes, Mucio A. Continentino, S. Rufo, and M. A. R. Griffith

Subjects

Physics, Multidisciplinary, Science, Weyl semimetal, Lorentz covariance, Topology, Article, symbols.namesake, Phase transitions and critical phenomena, Dirac equation, Quantum critical point, Topological insulator, symbols, Medicine, Hamiltonian (quantum mechanics), Critical exponent, Energy (signal processing), Topological matter

Abstract

A proposal to study topological models beyond the standard topological classification and that exhibit breakdown of Lorentz invariance is presented. The focus of the investigation relies on their anisotropic quantum critical behavior. We study anisotropic effects on three-dimensional (3D) topological models, computing their anisotropic correlation length critical exponent $$\nu$$ ν obtained from numerical calculations of the penetration length of the zero-energy surface states as a function of the distance to the topological quantum critical point. A generalized Weyl semimetal model with broken time-reversal symmetry is introduced and studied using a modified Dirac equation. An approach to characterize topological surface states in topological insulators when applied to Fermi arcs allows to capture the anisotropic critical exponent $$\theta =\nu _{x}/\nu _{z}$$ θ = ν x / ν z . We also consider the Hopf insulator model, for which the study of the topological surface states yields unusual values for $$\nu$$ ν and for the dynamic critical exponent z. From an analysis of the energy dispersions, we propose a scaling relation $$\nu _{\bar{\alpha }}z_{\bar{\alpha }}=2q$$ ν α ¯ z α ¯ = 2 q and $$\theta =\nu _{x}/\nu _{z}=z_{z}/z_{x}$$ θ = ν x / ν z = z z / z x for $$\nu$$ ν and z that only depends on the Hopf insulator Hamiltonian parameters p and q and the axis direction $$\bar{\alpha }$$ α ¯ . An anisotropic quantum hyperscaling relation is also obtained.

Published

2021

50. Investigations of proximity-induced superconductivity in the topological insulator Bi2Te3 by microRaman spectroscopy

Author

Jacek Szade, D. Kiphart, Piotr Kuświk, M. Wiesner, Y. Harkavyi, Stefan Jurga, Katarzyna Balin, and Boguslaw Mroz

Subjects

Materials science, Electronic properties and materials, Science, YBCO, Article, Superconducting properties and materials, symbols.namesake, HTSC, Surfaces, interfaces and thin films, Nanoscience and technology, Condensed Matter::Superconductivity, Bi2Te3, Electronic devices, Spectroscopy, Topological matter, Superconductivity, Multidisciplinary, Condensed matter physics, Hybrid device, Physics, Charge (physics), Topological insulator, symbols, Medicine, TI, Pseudogap, Raman spectroscopy

Abstract

We used the topological insulator (TI) Bi2Te3 and a high-temperature superconductor (HTSC) hybrid device for investigations of proximity-induced superconductivity (PS) in the TI. Application of the superconductor YBa2Cu3O7-δ (YBCO) enabled us to access higher temperature and energy scales for this phenomenon. The HTSC in the hybrid device exhibits emergence of a pseudogap state for T > Tc that converts into a superconducting state with a reduced gap for T c. The conversion process has been reflected in Raman spectra collected from the TI. Complementary charge transport experiments revealed emergence of the proximity-induced superconducting gap in the TI and the reduced superconducting gap in the HTSC, but no signature of the pseudogap. This allowed us to conclude that Raman spectroscopy reveals formation of the pseudogap state but cannot distinguish the proximity-induced superconducting state in the TI from the superconducting state in the HTSC characterised by the reduced gap. Results of our experiments have shown that Raman spectroscopy is a complementary technique to classic charge transport experiments and is a powerful tool for investigation of the proximity-induced superconductivity in the Bi2Te3.

Published

2021