Your search keyword '"73.43.Cd"' showing total 12 results

1. Stability of fractional quantum Hall states in disordered photonic systems

Author

Wade DeGottardi and Mohammad Hafezi

Subjects

fractional quantum Hall effect, disordered interactions, photonics, 03.65.Vf, 42.25.-p, 73.43.Cd, Science, Physics, QC1-999

Abstract

The possibility of realizing fractional quantum Hall liquids in photonic systems has attracted a great deal of interest of late. Unlike electronic systems, interactions in photonic systems must be engineered from nonlinear elements and are thus subject to positional disorder. The stability of the topological liquid relies on repulsive interactions. In this paper we investigate the stability of fractional quantum Hall liquids to impurities which host attractive interactions. Employing the Bose–Hubbard model with a magnetic field, we find that for sufficiently strong attractive interactions these impurities can destroy the topological liquid. However, we find that the liquid is quite robust to these defects, a fact which bodes well for the realization of topological quantum Hall liquids in photonic systems.

Published

2017

2. Magnetoresistance in quantum Hall metals due to Pancharatnam wavefunction transformation and degenerate Landau levels.

Author

ARULSAMY, ANDREW

Subjects

*QUANTUM Hall effect, *WAVE functions, *CHARGE exchange, *FERMIONS, *PHASE transitions, *LANDAU levels

Abstract

We derive the trial Hall resistance formula for the quantum Hall metals to address both the integer and fractional quantum Hall effects. Within the degenerate (and crossed) Landau levels, and in the presence of changing magnetic field strength, one can invoke two physical processes responsible for the electron conduction and quantum Hall effects in Fermi metals. One of the process requires the Pancharatnam wavefunction transformation, while the second involves electron transfer between two orthogonalized wavefunctions (within the degenerate and crossed Landau levels). We discuss the relevant physical postulates with respect to these physical processes to qualitatively reproduce the measured Hall resistance's zigzag curve for both the integer and the fractional filling factors. Along the way, we give out some evidence to contradict the postulates with experiments. [ABSTRACT FROM AUTHOR]

Published

2015

3. Probing the geometry of the Laughlin state

Author

Sonika Johri, Z Papić, P Schmitteckert, R N Bhatt, and F D M Haldane

Subjects

Laughlin wave function, quantum geometry, fractional quantum Hall effect, 73.43.Cd, 73.43.Lp, Science, Physics, QC1-999

Abstract

It has recently been pointed out that phases of matter with intrinsic topological order, like the fractional quantum Hall states, have an extra dynamical degree of freedom that corresponds to quantum geometry. Here we perform extensive numerical studies of the geometric degree of freedom for the simplest example of fractional quantum Hall states—the filling $\nu =1/3$ Laughlin state. We perturb the system by a smooth, spatially dependent metric deformation and measure the response of the Hall fluid, finding it to be proportional to the Gaussian curvature of the metric. Further, we generalize the concept of coherent states to formulate the bulk off-diagonal long range order for the Laughlin state, and compute the deformations of the metric in the vicinity of the edge of the system. We introduce a ‘pair amplitude’ operator and show that it can be used to numerically determine the intrinsic metric of the Laughlin state. These various probes are applied to several experimentally relevant settings that can expose the quantum geometry of the Laughlin state, in particular to systems with mass anisotropy and in the presence of an electric field gradient.

Published

2016

4. Edge mode velocities in the quantum Hall effect from a dc measurement

Author

P T Zucker and D E Feldman

Subjects

quantum Hall effect, edge mode, point contact, 73.43.Jn, 73.43.Cd, Science, Physics, QC1-999

Abstract

Because of the bulk gap, low energy physics in the quantum Hall effect is confined to the edges of the 2D electron liquid. The velocities of edge modes are key parameters of edge physics. They were determined in several quantum Hall systems from time-resolved measurements and high-frequency ac transport. We propose a way to extract edge velocities from dc transport in a point contact geometry defined by narrow gates. The width of the gates assumes two different sizes at small and large distances from the point contact. The Coulomb interaction across the gates depends on the gate width and affects the conductance of the contact. The conductance exhibits two different temperature dependencies at high and low temperatures. The transition between the two regimes is determined by the edge velocity. An interesting feature of the low-temperature I − V curve is current oscillations as a function of the voltage. The oscillations emerge due to charge reflection from the interface of the regions defined by the narrow and wide sections of the gates.

Published

2015

5. Self-compressed inhomogeneous stabilized jellium model and surface relaxation of simple metal thin films.

Author

Payami, M. and Mahmoodi, T.

Subjects

*INHOMOGENEOUS materials, *MATHEMATICAL models, *THIN films, *SURFACES (Technology), *PHYSICAL constants, *EQUILIBRIUM, *PARAMETER estimation

Abstract

The interlayer spacing near the surface of a crystal is different from that of the bulk. As a result, the value of the ionic density in the normal direction and near to the surface shows some variation from the bulk value, which is oscillatory in shape. To describe this behavior simply, we have formulated the self-compressed inhomogeneous stabilized jellium model and have applied it to simple metal thin films. In this model, for a ν-layered slab, each ionic layer is replaced by a jellium slice of constant density. The equilibrium densities of the slices are determined by minimizing the total energy per electron of the slab with respect to the slice densities. However, to avoid the complications that arise because of the increasing number of independent slice-density parameters for large- ν slabs, we consider a simplified version of the model that consists of only three jellium slices: one inner bulk slice with density and two similar surface slices, each of density . In this simplified model, each slice may contain more than one ionic layer. Application of this model to ν-layered slabs (3 ≤ ν ≤ 10) of Al, Na, and Cs shows that, in the equilibrium state, differs from . The difference is significant in the Al case, and the slab is more stable than that predicted by the homogeneous model with only one density parameter for the whole jellium background. In addition, we have calculated the overall relaxations, the work functions, and the surface energies and compared them with the results of earlier works. [ABSTRACT FROM AUTHOR]

Published

2011

6. Topological metallic phases in spin–orbit coupled bilayer systems

Author

Hui Pan, Xin Li, Zhenhua Qiao, Cheng-Cheng Liu, Yugui Yao, and Shengyuan A Yang

Subjects

topological metallic states, Kane–Mele model, spin-orbit couplings, 73.22.Pr, 73.43.Cd, 75.70.Tj, Science, Physics, QC1-999

Abstract

We investigate the influence of different spin–orbit couplings on topological phase transitions in the bilayer Kane–Mele model. We find that the competition between intrinsic spin–orbit coupling and Rashba spin–orbit coupling can lead to two dimensional topological metallic states with nontrivial topology. Such phases, although having a metallic bulk, still possess edge states with well defined topological invariants. Specifically, we show that with preserved time reversal symmetry the system can exhibit a ${{\mathbb{Z}}_{2}}$ -metallic phase with spin helical edge states and a nontrivial ${{\mathbb{Z}}_{2}}$ invariant. When time reversal symmetry is broken, a Chern metallic phase could appear with chiral edge states and a nontrivial Chern invariant.

Published

2014

7. Impact of the capture time on the series resistance of quantum-well diode lasers

Author

A Boni, Hans-Jürgen Wünsche, Hans Wenzel, and Paul Crump

Subjects

Semiconductor laser, Materials science, GaAs based high-power lasers, 02 engineering and technology, Electron, Heat sink, 01 natural sciences, semiconductor heterostructure, Electrical resistivity and conductivity, 0103 physical sciences, Materials Chemistry, Electrical and Electronic Engineering, 78A60, Quantum well, Diode, 010302 applied physics, 73.21.Fg, experiment, Condensed matter physics, Equivalent series resistance, 73.43.Cd, business.industry, 42.55.Px, Heterojunction, simulation, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 42.65.Sf, five GaAs-based devices, Electronic, Optical and Magnetic Materials, Semiconductor, capture-escape, 0210 nano-technology, business

Abstract

Electrons and holes injected into a semiconductor heterostructure containing quantum wells are captured with a finite time. We show theoretically that this very fact can cause a considerable excess contribution to the series resistivity and this is one of the main limiting factors to higher efficiency for GaAs based high-power lasers. The theory combines a standard microscopic-based model for the capture-escape processes in the quantum well with a drift-diffusion description of current flow outside the quantum well. Simulations of five GaAs-based devices differing in their Al-content reveal the root-cause of the unexpected and until now unexplained increase of the series resistance with decreasing heat sink temperature measured recently. The finite capture time results in resistances in excess of the bulk layer resistances (decreasing with increasing temperature) from 1 mΩ up to 30 mΩ in good agreement with the experiment.

Published

2020

8. Quantum chemical simulation of the silica-anaesthetic, silica-polymer, and polymer-anaesthetic interactions

Author

Payentko, Victoriya, Kulyk, Tetyana, and Kuts, Volodymyr

Published

2015

9. Quantum chemical simulation of the silica-anaesthetic, silica-polymer, and polymer-anaesthetic interactions

Author

Victoriya Payentko, Volodymyr Kuts, and Tetyana Kulyk

Subjects

Quantum chemical, chemistry.chemical_classification, Materials science, Nano Express, 73.43.Cd, 71.10.-w, Nanochemistry, Silica, Nanotechnology, Polymer, Condensed Matter Physics, Adsorption, Materials Science(all), Chemical engineering, chemistry, Anaesthetic, Quantum chemical simulation, General Materials Science, 31.15.bu, 73.20.At

Abstract

Using semiempirical PM3 method, a comparative quantum chemical estimation has been carried out of the energy of articaine adsorption on the surfaces of the following composite materials: silica-anaesthetic, polymer-anaesthetic, and silica-polymer-anaesthetic. It has been found that adsorption on silica surface takes place due to electrostatic and nonspecific interactions. The data of quantum chemical calculations of the structures of composite materials may be useful in the creation of different forms of medicine preparations with adjustment characteristics.

Published

2015

10. Mesoscopic effects in the quantum Hall regime

Author

Bhatt, R N and Xin, Wan

Published

2002

11. Self-consistent calculation of electric potentials in Hall devices

Author

Tobias Kramer, Eric J. Heller, Robert E. Parrott, and Viktor Krueckl

Subjects

Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed matter physics, Bar (music), 73.43.Cd, 71.10.-w, ddc:530, Thermal Hall effect, FOS: Physical sciences, Electron, Quantum Hall effect, Condensed Matter Physics, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, 530 Physik, Electronic, Optical and Magnetic Materials, Quantum spin Hall effect, Hall effect, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), Boundary value problem, Ohmic contact, 73.23.-b

Abstract

Using a first-principles classical many-body simulation of a Hall bar, we study the necessary conditions for the formation of the Hall potential: (i) Ohmic contacts with metallic reservoirs, (ii) electron-electron interactions, and (iii) confinement to a finite system. By propagating thousands of interacting electrons over million time-steps we capture the build-up of the self-consistent potential, which resembles results obtained by conformal-mapping methods. As shown by a microscopic model of the current injection, the Hall effect is linked to specific boundary conditions at the particle reservoirs., Comment: 6 pages, 7 figures

Published

2010

12. Quantum Hall Systems in High Landau Levels

Author

Joas, Christian Benjamin

Subjects

Microwave Irradiation, 05.60.-k, Quantum Hall Effect, 73.43.Cd, 500 Naturwissenschaften und Mathematik::530 Physik::530 Physik, 73.50.Pz

Abstract

Title Page and Front Matter Table of Contents i 1\. Introduction 1 1.1 The Integer Quantum Hall Effect 1 1.2 The Fractional Quantum Hall Effect 2 1.3 High Landau Levels 9 1.4 This Thesis 11 2\. Microwave-Induced Zero Resistance States 15 2.1 Zero Resistance States and Microwave-Induced Resistance Oscillations 15 2.2 Theoretical Explanation of ZRS 17 3\. Classical Model for a Microwave-Irradiated 2DEG in the Presence of Bichromatic Irradiation 27 3.1 Monochromatic Irradiation 28 3.2 Bichromatic Irradiation 31 3.3 Bichromatic Irradiation and Absolute Negative Conductivity 45 3.4 Discussion 46 4\. Microwave Photoconductivity due to Intra-Landau-Level Transitions 49 4.1 Experiment 50 4.2 Model 51 4.3 Mechanisms 60 4.4 Dark Current 66 4.5 Photocurrent 68 4.6 Comparison with Experiment 77 4.7 Polarization Dependence 79 4.8 Discussion 80 5\. In-Plane Magnetic Field 83 5.1 Theory 84 5.2 Results 92 5.3 Discussion 94 6\. Drag in Double-Layer Systems 97 6.1 Conventions 98 6.2 Coulomb Drag 100 6.3 Phonon Drag 102 6.4 Linear Response Theory of Drag 104 7\. Phonon Drag in High Landau Levels 109 7.1 Linear Response Theory of Phonon Drag: Triangle Vertex and Polarization Function 109 7.2 Interaction of 2D Electrons with Bulk Phonons in the Bilayer System 117 7.3 Analytical Results 124 7.4 Numerical Results 131 7.5 Discussion 139 8\. Conclusions 141 Appendix 145 Acknowledgments 175 Bibliography 179 Abstract Citations of previously published work, In recent years, the experimental study of quantum Hall systems in weak magnetic fields has yielded unexpected and interesting discoveries. In this thesis, we focus on the two most interesting phenomena observed in magnetotransport experiments on such systems: (i) zero resistance states in microwave-irradiated high mobility samples and (ii) drag between parallel two- dimensional electron gases (2DEG) in double-layer samples. The diagonal resistivity of a 2DEG in an ultraclean GaAs/AlGaAs heterostructure subjected to microwave radiation exhibits magnetooscillations whose minima, for sufficiently high microwave power, can evolve into zero resistance states (ZRS) within specific ranges of magnetic field. Intriguingly, the zeros in the diagonal resistivity are not accompanied by plateaus in the Hall resistivity, which would be characteristic of a quantum Hall state. The first part of this thesis is devoted to the physics of these ZRS. We first examine the special case of bichromatic irradiation and show that the emergence of ZRS can be explained within a classical model. In addition, we predict interesting novel effects under bichromatic irradiation and present a way to parametrically excite the cyclotron mode by bichromatic irradiation. We argue that bichromatic irradiation can be used as a tool to verify absolute negative local conductivity, which lies at the center of the theoretical explanation of ZRS within a microscopic quantum mechanical model. We then present a microscopic theory for the recently discovered magnetooscillations for microwave frequencies smaller than the cyclotron frequency. We formulate a microscopic model which mimics the effect of a smooth random disorder potential by the introduction of a periodic modulation and calculate the conductivity under microwave irradiation. We are able to explain why no ZRS are observed in this intra-Landau-level regime and explain the experimentally observed suppression of Shubnikov-deHaas oscillations. We reproduce the sign of the photoconductvity, its magnetic field and frequency dependence as well as its filling factor dependence in excellent qualitative agreement with experiment. We also discuss the application of an in-plane magnetic field to a highmobility 2DEG under microwave irradiation, which has been demonstrated experimentally to induce a pronounced suppression or even destruction of the ZRS. We calculate the effect of a tilted magnetic field within a kinetic approach for spin-split Landau bands and estimate the relevance of Zeeman splitting for the suppression of the ZRS. The second part of this work is devoted to the physics of drag phenomena in bilayer quantum Hall systems at weak magnetic fields, more specifically to phonon drag, which, in contrast to the well-studied Coulomb drag, had not been understood within a microscopical theory. We develop the linear response theory for the phonon drag conductivity by extending an established approach for Coulomb drag. The main difference between Coulomb and phonon drag is due to the specific form of the phonon- mediated interlayer interaction, which, in contrast to the Coulomb interlayer interaction, allows for a larger range of momentum transfers between the layers of the bilayer system. We derive the phonon-mediated interlayer interaction in polar semiconductors such as GaAs and calculate the phonon contribution to the drag conductivity in the experimentally relevant regime. We finally present numerical results for the drag resistivity within a variety of parameter ranges., In den letzten Jahren hat die experimentelle Untersuchung von Quanten-Hall- Systemen in schwachen Magnetfeldern unerwartete und interessante Entdeckungen hervorgebracht. In dieser Doktorarbeit wenden wir uns den zwei interessantesten Phänomenen zu, die in Magnetotransportmessungen an solchen Systemen beobachtet werden: (i) den widerstandslosen Zuständen in mikrowellenbestrahlten, hochreinen Systemen und (ii) dem sog. "Drag"-Effekt (Zugeffekt) zwischen zueinander parallelen zweidimensionalen Elektronengasen (2DEG) in Doppelschichtsystemen. Der diagonale relative Widerstand eines 2DEG in einer hochreinen GaAs/ AlGaAs-Heterostruktur zeigt unter Bestrahlung mit Mikrowellen Magnetooszillationen, deren Minima für genügend große Mikrowellenleistung innerhalb bestimmter Magnetfeldbereiche in widerstandslose Zustände, sog. zero resistance states (ZRS), übergehen können. Faszinierenderweise werden diese Nullstellen im diagonalen relativen Widerstand nicht von Plateaus im Hall-Widerstand begleitet, wie es für Quanten-Hall-Zustände charakteristisch wäre. Der erste Teil dieser Arbeit widmet sich der Physik dieser ZRS. Zunächst untersuchen wir den Spezialfall bichromatischer Bestrahlung und zeigen, daß das Auftreten von ZRS im Rahmen eines klassischen Modells erklärt werden kann. Außerdem sagen wir interessante neuartige Effekte voraus, die bei bichromatischer Bestrahlung auftreten und stellen eine Methode vor, mit der die Zyklotronmode mittels bichromatischer Bestrahlung parametrisch angeregt werden kann. Wir zeigen, wie bichromatische Bestrahlung dazu benutzt werden kann, absolut negative Leitfähigkeit nachzuweisen. Diese nimmt in der theoretischen Beschreibung der ZRS im Rahmen eines mikroskopischen quantenmechanischen Modells eine zentrale Rolle ein. Sodann entwickeln wir eine mikroskopische Theorie für das kürzlich unter Bestrahlung mit Mikrowellenfrequenzen unterhalb der Zyklotronfrequenz entdeckte Auftreten von Magnetooszillationen. Wir formulieren ein mikroskopisches Modell, das den Effekt eines glatten Zufalls- Unordnungspotentials mittels einer periodischen Modulation nachahmt und berechnen den Leitwert unter Mikrowellenbestrahlung. Dies ermöglicht uns zu erklären, warum für dieses Intra- Landauniveau-Regime keine ZRS beobachtet werden und wie die experimentell beobachtete Unterdrückung der Shubnikov- deHaas-Oszillationen entsteht. Wir sind in der Lage, das Vorzeichen des Leitwerts, seine Magnetfeld- und Frequenzabhängigkeit sowie den Zusammenhang mit dem Füllfaktor in hervorragender qualitativer Übereinstimmung mit dem Experiment zu bestimmen. Zudem diskutieren wir den Einfluß eines zur Ebene des 2DEG parallelen Magnetfelds auf ein hochreines, mit Mikrowellen bestrahltes 2DEG. Experimentell beobachtet man in diesem Fall eine Unterdrückung oder gar Zerstörung der ZRS. Wir berechnen die Auswirkungen eines gekippten Magnetfeldes im Rahmen einer kinetischen Theorie spinaufgespaltener Landau- Bänder und schätzen die Rolle der Zeeman-Aufspaltung für die Unterdrückung der ZRS ab. Der zweite Teil dieser Arbeit befasst sich mit der Physik von Drag- Phänomenen in Doppelschicht-Quanten-Hall-Systemen bei schwachen Magnetfeldern. Genauer beschäftigen wir uns mit phononenvermitteltem Drag, der bislang im Gegensatz zum weitgehend verstandenen, durch Coulomb-Wechselwirkung vermittelten Drag noch nicht durch eine mikroskopische Theorie beschrieben werden konnte. Wir entwickeln die lineare Antworttheorie für den Phonon- Drag- Leitwert, indem wir eine für Coulomb-Drag bewährte Herangehensweise erweitern. Der Hauptunterschied zwischen Coulomb-Drag und Phonon-Drag liegt in der spezifischen Form der phononenvermittelten Wechselwirkung zwischen den beiden Schichten. Im Gegensatz zur Coulomb-Wechselwirkung gestattet die phonenvermittelte Wechselwirkung einen größeren Bereich von Impulsüberträgen zwischen den Schichten des Doppelschicht-Systems. Wir leiten die phononenvermittelte Wechselwirkung in polaren Halbleitern wie z.B. GaAs her und berechnen den phononenvermittelten Beitrag zum Drag-Leitwert im experimentell relevanten Parameterbereich. Abschließend stellen wir numerische Resultate für den spezifischen Drag-Widerstand in einer Vielzahl weiterer Parameterbereiche vor.

Published

2007