Your search keyword '"Goerbig MO"' showing total 16 results

1. Cascade of Multielectron Bubble Phases in Monolayer Graphene at High Landau Level Filling.

Author

Yang F, Bai R, Zibrov AA, Joy S, Taniguchi T, Watanabe K, Skinner B, Goerbig MO, and Young AF

Abstract

The phase diagram of an interacting two-dimensional electron system in a high magnetic field is enriched by the varying form of the effective Coulomb interaction, which depends strongly on the Landau level index. While the fractional quantum Hall states that dominate in the lower-energy Landau levels have been explored experimentally in a variety of two-dimensional systems, much less work has been done to explore electron solids owing to their subtle transport signatures and extreme sensitivity to disorder. Here, we use chemical potential measurements to map the phase diagram of electron solid states in N=2, N=3, and N=4 Landau levels in monolayer graphene. Direct comparison between our data and theoretical calculations reveals a cascade of density-tuned phase transitions between electron bubble phases up to two, three, or four electrons per bubble in the N=2, 3, and 4 Landau levels, respectively. Finite-temperature measurements are consistent with melting of the solids for T≈1  K.

Published

2023

2. Lorentz-Boost-Driven Magneto-Optics in a Dirac Nodal-Line Semimetal.

Author

Wyzula J, Lu X, Santos-Cottin D, Mukherjee DK, Mohelský I, Le Mardelé F, Novák J, Novak M, Sankar R, Krupko Y, Piot BA, Lee WL, Akrap A, Potemski M, Goerbig MO, and Orlita M

Abstract

Optical response of crystalline solids is to a large extent driven by excitations that promote electrons among individual bands. This allows one to apply optical and magneto-optical methods to determine experimentally the energy band gap -a fundamental property crucial to our understanding of any solid-with a great precision. Here it is shown that such conventional methods, applied with great success to many materials in the past, do not work in topological Dirac semimetals with a dispersive nodal line. There, the optically deduced band gap depends on how the magnetic field is oriented with respect to the crystal axes. Such highly unusual behavior is explained in terms of band-gap renormalization driven by Lorentz boosts which results from the Lorentz-covariant form of the Dirac Hamiltonian relevant for the nodal line at low energies., (© 2022 The Authors. Advanced Science published by Wiley-VCH GmbH.)

Published

2022

3. Magneto-Optics of a Weyl Semimetal beyond the Conical Band Approximation: Case Study of TaP.

Author

Polatkan S, Goerbig MO, Wyzula J, Kemmler R, Maulana LZ, Piot BA, Crassee I, Akrap A, Shekhar C, Felser C, Dressel M, Pronin AV, and Orlita M

Abstract

Landau-level spectroscopy, the optical analysis of electrons in materials subject to a strong magnetic field, is a versatile probe of the electronic band structure and has been successfully used in the identification of novel states of matter such as Dirac electrons, topological materials or Weyl semimetals. The latter arise from a complex interplay between crystal symmetry, spin-orbit interaction, and inverse ordering of electronic bands. Here, we report on unusual Landau-level transitions in the monopnictide TaP that decrease in energy with increasing magnetic field. We show that these transitions arise naturally at intermediate energies in time-reversal-invariant Weyl semimetals where the Weyl nodes are formed by a partially gapped nodal-loop in the band structure. We propose a simple theoretical model for electronic bands in these Weyl materials that captures the collected magneto-optical data to great extent.

Published

2020

4. Origin of the Flat Band in Heavily Cs-Doped Graphene.

Author

Ehlen N, Hell M, Marini G, Hasdeo EH, Saito R, Falke Y, Goerbig MO, Di Santo G, Petaccia L, Profeta G, and Grüneis A

Abstract

A flat energy dispersion of electrons at the Fermi level of a material leads to instabilities in the electronic system and can drive phase transitions. Here we show that the flat band in graphene can be achieved by sandwiching a graphene monolayer by two cesium (Cs) layers. We investigate the flat band by a combination of angle-resolved photoemission spectroscopy experiment and the calculations. Our work highlights that charge transfer, zone folding of graphene bands, and the covalent bonding between C and Cs atoms are the origin of the flat energy band formation. Analysis of the Stoner criterion for the flat band suggests the presence of a ferromagnetic instability. The presented approach is an alternative route for obtaining flat band materials to twisting bilayer graphene which yields thermodynamically stable flat band materials in large areas.

Published

2020

5. Competing Fractional Quantum Hall and Electron Solid Phases in Graphene.

Author

Chen S, Ribeiro-Palau R, Yang K, Watanabe K, Taniguchi T, Hone J, Goerbig MO, and Dean CR

Abstract

We report experimental observation of the reentrant integer quantum Hall effect in graphene, appearing in the N=2 Landau level. Similar to high-mobility GaAs/AlGaAs heterostructures, the effect is due to a competition between incompressible fractional quantum Hall states, and electron solid phases. The tunability of graphene allows us to measure the B-T phase diagram of the electron solid phase. The hierarchy of reentrant states suggests spin and valley degrees of freedom play a role in determining the ground state energy. We find that the melting temperature scales with magnetic field, and construct a phase diagram of the electron liquid-solid transition.

Published

2019

6. Landau Velocity for Collective Quantum Hall Breakdown in Bilayer Graphene.

Author

Yang W, Graef H, Lu X, Zhang G, Taniguchi T, Watanabe K, Bachtold A, Teo EHT, Baudin E, Bocquillon E, Fève G, Berroir JM, Carpentier D, Goerbig MO, and Plaçais B

Abstract

Breakdown of the quantum Hall effect (QHE) is commonly associated with an electric field approaching the inter-Landau-level (LL) Zener field, the ratio of the Landau gap and the cyclotron radius. Eluded in semiconducting heterostructures, in spite of extensive investigation, the intrinsic Zener limit is reported here using high-mobility bilayer graphene and high-frequency current noise. We show that collective excitations arising from electron-electron interactions are essential. Beyond a noiseless ballistic QHE regime a large super-Poissonian shot noise signals the breakdown via inter-LL scattering. The breakdown is ultimately limited by collective excitations in a regime where phonon and impurity scattering are quenched. The breakdown mechanism can be described by a Landau critical velocity as it bears strong similarities with the roton mechanism of superfluids. In addition, we show that breakdown is a precursor of an electric-field induced QHE-metal transition.

Published

2018

7. Model Prediction of Self-Rotating Excitons in Two-Dimensional Transition-Metal Dichalcogenides.

Author

Trushin M, Goerbig MO, and Belzig W

Abstract

Using the quasiclassical concept of Berry curvature we demonstrate that a Dirac exciton-a pair of Dirac quasiparticles bound by Coulomb interactions-inevitably possesses an intrinsic angular momentum making the exciton effectively self-rotating. The model is applied to excitons in two-dimensional transition metal dichalcogenides, in which the charge carriers are known to be described by a Dirac-like Hamiltonian. We show that the topological self-rotation strongly modifies the exciton spectrum and, as a consequence, resolves the puzzle of the overestimated two-dimensional polarizability employed to fit earlier spectroscopic measurements.

Published

2018

8. Magneto-Optical Signature of Massless Kane Electrons in Cd_{3}As_{2}.

Author

Akrap A, Hakl M, Tchoumakov S, Crassee I, Kuba J, Goerbig MO, Homes CC, Caha O, Novák J, Teppe F, Desrat W, Koohpayeh S, Wu L, Armitage NP, Nateprov A, Arushanov E, Gibson QD, Cava RJ, van der Marel D, Piot BA, Faugeras C, Martinez G, Potemski M, and Orlita M

Abstract

We report on optical reflectivity experiments performed on Cd_{3}As_{2} over a broad range of photon energies and magnetic fields. The observed response clearly indicates the presence of 3D massless charge carriers. The specific cyclotron resonance absorption in the quantum limit implies that we are probing massless Kane electrons rather than symmetry-protected 3D Dirac particles. The latter may appear at a smaller energy scale and are not directly observed in our infrared experiments.

Published

2016

9. Magnetic-Field-Induced Relativistic Properties in Type-I and Type-II Weyl Semimetals.

Author

Tchoumakov S, Civelli M, and Goerbig MO

Abstract

We investigate Weyl semimetals with tilted conical bands in a magnetic field. Even when the cones are overtilted (type-II Weyl semimetal), Landau-level quantization can be possible as long as the magnetic field is oriented close to the tilt direction. Most saliently, the tilt can be described within the relativistic framework of Lorentz transformations that give rise to a rich spectrum, displaying new transitions beyond the usual dipolar ones in the optical conductivity. We identify particular features in the latter that allow one to distinguish between semimetals of different types.

Published

2016

10. SU(4) Skyrmions in the ν=±1 Quantum Hall State of Graphene.

Author

Lian Y, Rosch A, and Goerbig MO

Abstract

We explore different Skyrmion types in the lowest Landau level of graphene at a filling factor ν=±1. In addition to the formation of spin and valley pseudospin Skyrmions, we show that another type of spin-valley entangled Skyrmions can be stabilized in graphene due to an approximate SU(4) spin-valley symmetry that is affected by sublattice symmetry-breaking terms. These Skyrmions have a clear signature in spin-resolved density measurements on the lattice scale, and we discuss the expected patterns for the different Skyrmion types.

Published

2016

11. Magnetoplasmons in quasineutral epitaxial graphene nanoribbons.

Author

Poumirol JM, Yu W, Chen X, Berger C, de Heer WA, Smith ML, Ohta T, Pan W, Goerbig MO, Smirnov D, and Jiang Z

Abstract

We present an infrared transmission spectroscopy study of the inter-Landau-level excitations in quasineutral epitaxial graphene nanoribbon arrays. We observed a substantial deviation in energy of the L(0(-1)) → L(1(0)) transition from the characteristic square root magnetic-field dependence of two-dimensional graphene. This deviation arises from the formation of an upper-hybrid mode between the Landau-level transition and the plasmon resonance. In the quantum regime, the hybrid mode exhibits a distinct dispersion relation, markedly different from that expected for conventional two-dimensional systems and highly doped graphene.

Published

2013

12. Atypical fractional quantum Hall effect in graphene at filling factor 1/3.

Author

Papić Z, Goerbig MO, and Regnault N

Abstract

We study, with the help of exact-diagonalization calculations, a four-component trial wave function that may be relevant for the recently observed graphene fractional quantum Hall state at a filling factor ν(G) = 1/3. Although it is adiabatically connected to a 1/3 Laughlin state in the upper spin branch, with SU(2) valley-isospin ferromagnetic ordering and a completely filled lower spin branch, it reveals physical properties beyond such a state that is the natural ground state for a large Zeeman effect. Most saliently, it possesses at experimentally relevant values of the Zeeman gap low-energy spin-flip excitations that may be unveiled in inelastic light-scattering experiments.

Published

2010

13. Bridge between Abelian and non-Abelian fractional quantum Hall states.

Author

Regnault N, Goerbig MO, and Jolicoeur T

Abstract

We propose a scheme to construct the most prominent Abelian and non-Abelian fractional quantum Hall states from K-component Halperin wave functions. In order to account for a one-component quantum Hall system, these SU(K) colors are distributed over all particles by an appropriate symmetrization. Numerical calculations corroborate the picture that K-component Halperin wave functions may be a common basis for both Abelian and non-Abelian trial wave functions in the study of one-component quantum Hall systems.

Published

2008

14. High-energy limit of massless Dirac fermions in multilayer graphene using magneto-optical transmission spectroscopy.

Author

Plochocka P, Faugeras C, Orlita M, Sadowski ML, Martinez G, Potemski M, Goerbig MO, Fuchs JN, Berger C, and de Heer WA

Abstract

We have investigated the absorption spectrum of multilayer graphene in high magnetic fields. The low-energy part of the spectrum of electrons in graphene is well described by the relativistic Dirac equation with a linear dispersion relation. However, at higher energies (>500 meV) a deviation from the ideal behavior of Dirac particles is observed. At an energy of 1.25 eV, the deviation from linearity is approximately 40 meV. This result is in good agreement with the theoretical model, which includes trigonal warping of the Fermi surface and higher-order band corrections. Polarization-resolved measurements show no observable electron-hole asymmetry.

Published

2008

15. Filling-factor-dependent magnetophonon resonance in graphene.

Author

Goerbig MO, Fuchs JN, Kechedzhi K, and Fal'ko VI

Subjects

Electrons, Phonons, Vibration, Graphite chemistry, Spectrum Analysis, Raman

Abstract

We describe a peculiar fine structure acquired by the in-plane optical phonon at the Gamma point in graphene when it is brought into resonance with one of the inter-Landau-level transitions in this material. The effect is most pronounced when this lattice mode (associated with the G band in graphene Raman spectrum) is in resonance with inter-Landau-level transitions 0 --> +, 1 and -, 1 --> 0, at a magnetic field B{0} approximately 30 T. It can be used to measure the strength of the electron-phonon coupling directly, and its filling-factor dependence can be used experimentally to detect circularly polarized lattice vibrations.

Published

2007

16. Possible reentrance of the fractional quantum Hall effect in the lowest Landau level.

Author

Goerbig MO, Lederer P, and Morais Smith C

Abstract

In the framework of a recently developed model of interacting composite fermions, we calculate the energy of different solid and Laughlin-type liquid phases of spin-polarized composite fermions. The liquid phases have a lower energy than the competing solids around the electronic filling factors nu = 4/11,6/17, and 4/19 and may thus be responsible for the fractional quantum Hall effect at nu = 4/11. The alternation between solid and liquid phases when varying the magnetic field may lead to reentrance phenomena in analogy with the observed reentrant integral quantum Hall effect.

Published

2004