Pinning Mode Resonances of 2D Electron Stripe Phases in High Landau Levels Han Zhu ( 朱涵 ) Physics Department, Princeton University National High Magnetic.

Slides:

Advertisements

Similar presentations

ILCC Edinburgh, July 2002 VAN DER WAALS INTERACTION AND STABILITY OF MULTILAYERED LIQUID-CRYSTALLINE SYSTEMS dr. Andreja [ arlah Univerza v Ljubljani.

Advertisements

Nanostructures on ultra-clean two-dimensional electron gases T. Ihn, C. Rössler, S. Baer, K. Ensslin C. Reichl and W. Wegscheider.

The “normal” state of layered dichalcogenides Arghya Taraphder Indian Institute of Technology Kharagpur Department of Physics and Centre for Theoretical.

Searching for Majorana fermions in semiconducting nano-wires Pedram Roushan Peter O’Malley John Martinis Department of Physics, UC Santa Barbara Borzoyeh.

4 December 2003NYU Colloquium1 Electronic Liquid Crystals Novel Phases of Electrons in Two Dimensions Alan Dorsey University of Florida Collaborators:

SDW Induced Charge Stripe Structure in FeTe

B. Spivak, UW with S. Kivelson, Stanford 2D electronic phases intermediate between the Fermi liquid and the Wigner crystal (electronic micro-emulsions)

Electrical Techniques MSN506 notes. Electrical characterization Electronic properties of materials are closely related to the structure of the material.

Single electron Transport in diluted magnetic semiconductor quantum dots Department of Applied Physics, U. Alicante SPAIN Material Science Institute of.

The Persistent Spin Helix Shou-Cheng Zhang, Stanford University Banff, Aug 2006.

The noise spectra of mesoscopic structures Eitan Rothstein With Amnon Aharony and Ora Entin Condensed matter seminar, BGU.

Magneto-optical study of InP/InGaAs/InP quantum well B. Karmakar, A.P. Shah, M.R. Gokhale and B.M. Arora Tata Institute of Fundamental Research Mumbai,

B.Spivak University of Washington with S. Kivelson, S. Sondhi, S. Parameswaran A typology of quantum Hall liquids. Weakly coupled Pfaffian state as a type.

Fractional Quantum Hall states in optical lattices Anders Sorensen Ehud Altman Mikhail Lukin Eugene Demler Physics Department, Harvard University.

Charge Inhomogeneity and Electronic Phase Separation in Layered Cuprate F. C. Chou Center for Condensed Matter Sciences, National Taiwan University National.

Optical spin transfer in GaAs:Mn Joaquin Fernandez-Rossier, Department of Applied Physics, University of Alicante (SPAIN) CECAM June 2003, Lyon (FR) cond-mat/

Correlated tunneling and the instability of the fractional quantum Hall edge Dror Orgad Oded Agam July 21, 2009 PRL 100, (2008)

Cyclotron Resonance and Faraday Rotation in infrared spectroscopy

Quantum conductance I.A. Shelykh St. Petersburg State Polytechnical University, St. Petersburg, Russia International Center for Condensed Matter Physics,

Superconductivity Characterized by- critical temperature T c - sudden loss of electrical resistance - expulsion of magnetic fields (Meissner Effect) Type.

Nematic Electron States in Orbital Band Systems Congjun Wu, UCSD Collaborator: Wei-cheng Lee, UCSD Feb, 2009, KITP, poster Reference: W. C. Lee and C.

B. Spivak UW S. Kivelson UCLA Electronic transport in 2D micro-emulsions.

Observation of neutral modes in the fractional quantum hall effect regime Aveek Bid Nature (2010) Department of Physics, Indian Institute of Science,

Sergei Studenikin, Geof Aers, and Andy Sachrajda National Research Council of Canada, Ottawa, Canada Electron effective mass in an ultra-high mobility.

Kaiserslautern, April 2006 Quantum Hall effects - an introduction - AvH workshop, Vilnius, M. Fleischhauer.

Frequency dependence of the anomalous Hall effect: possible transition from extrinsic to intrinsic behavior John Cerne, University at Buffalo, SUNY, DMR.

Photoluminescence and lasing in a high-quality T-shaped quantum wires M. Yoshita, Y. Hayamizu, Y. Takahashi, H. Itoh, and H. Akiyama Institute for Solid.

Nonisovalent La substitution in LaySr14-y-xCaxCu24O41: switching the transport from ladders.

STRUCTURE AND MAGNETIC PROPERTIES OF ULTRA-THIN MAGNETIC LAYERS

The world of 2d electrons is exciting: enabling ‘ballistic high mobility transport’ modulation doping enabling ‘ballistic high mobility transport’ modulation.

4. The Nuclear Magnetic Resonance Interactions 4a. The Chemical Shift interaction The most important interaction for the utilization of NMR in chemistry.

University of FLORIDA electron spin resonance study in a wide parabolic quantum well Russ Bowers Associate Professor of Chemistry University of Florida,

Composite Fermion Groundstate of Rashba Spin-Orbit Bosons Alex Kamenev Fine Theoretical Physics Institute, School of Physics & Astronomy, University of.

Dung-Hai Lee U.C. Berkeley Quantum state that never condenses Condense = develop some kind of order.

グラフェン量子ホール系の発光量子ホール系の光学ホール伝導度 1 青木研究室 M2 森本高裕青木研究室 M2 森本高裕.

Edge magnetoplasmons in single two- dimensional electron disks at microwave frequencies : Determination of the lateral depletion length C. Dahl, S. Manus,

Correlated States in Optical Lattices Fei Zhou (PITP,UBC) Feb. 1, 2004 At Asian Center, UBC.

Effects of Interaction and Disorder in Quantum Hall region of Dirac Fermions in 2D Graphene Donna Sheng (CSUN) In collaboration with: Hao Wang (CSUN),

Y. W. Suen ( 孫允武 ), a W. H. Hsieh( 謝文興 ), a,b S. Y. Chang ( 張紓語 ), b L. C. Lee ( 李良箴 ), b C. H. Kuan ( 管傑雄 ), a B. C. Lee ( 李秉奇 ), c and.

1 Unconventional Magnetism: Electron Liquid Crystal State and Dynamic Generation of Spin-orbit Coupling Congjun Wu C. Wu and S. C. Zhang, PRL 93,

Wigner-Mott scaling of transport near the two-dimensional metal-insulator transition Milos Radonjic, D. Tanaskovic, V. Dobrosavljevic, K. Haule, G. Kotliar.

Magnetothermopower in high-mobility 2D electron gas: effect of microwave irradiation Oleg Raichev Department of Theoretical Physics Institute of Semiconductor.

Cold Melting of Solid Electron Phases in Quantum Dots M. Rontani, G. Goldoni INFM-S3, Modena, Italy phase diagram correlation in quantum dots configuration.

Infrared and magneto- optical studies of topological insulators Saša V. Ðorđević Department of Physics.

Detection of current induced Spin polarization with a co-planar spin LED J. Wunderlich (1), B. Kästner (1,2), J. Sinova (3), T. Jungwirth (4,5) (1)Hitachi.

Raman Scattering As a Probe of Unconventional Electron Dynamics in the Cuprates Raman Scattering As a Probe of Unconventional Electron Dynamics in the.

J.P. Eisenstein, Caltech, DMR If it were not for the Coulomb repulsion between electrons, iron would not be ferromagnetic. It would instead be.

Emergent Nematic State in Iron-based Superconductors

First Principle Calculation of Nuclear Magnetic Resonance (NMR) chemical shift Kanchan Sonkar Center of Biomedical Magnetic Resonance SGPGIMS-Campus, Lucknow,

Basics of edge channels in IQHE doing physics with integer edge channels studies of transport in FQHE regime deviations from the ‘accepted’ picture Moty.

Unusual magnetotransport properties of NbSe 3 single crystals at low temperature A.A.Sinchenko MEPhI, Moscow, Russia Yu.I.Latyshev, A.P.Orlov IRE RAS,

Terahertz Charge Dynamics in Semiconductors James N. Heyman Macalester College St. Paul, MN.

SESAPS Terahertz Rotational Spectrum of the v5/2v9 Dyad of Nitric Acid * Paul Helminger, a Douglas T. Petkie, b Ivan Medvedev, b and Frank C. De.

Flat Band Nanostructures Vito Scarola

Institute of Physics, National Chiao Tung University

B. Spivak, UW S. Kivelson, Stanford 2D electronic phases intermediate between the Fermi liquid and the Wigner crystal (electronic micro-emulsions)

Igor Lukyanchuk Amiens University

Circuit QED Experiment

Fractional Berry phase effect and composite particle hole liquid in partial filled LL Yizhi You KITS, 2017.

Spin-orbit interaction in a dual gated InAs/GaSb quantum well

6/25/2018 Nematic Order on the Surface of three-dimensional Topological Insulator[1] Hennadii Yerzhakov1 Rex Lundgren2, Joseph Maciejko1,3 1 University.

COMPLEX ELECTRON ENERGY DISTRIBUTIONS IN ASYMMETRIC RF-DC DISCHARGES

QHE discovered by Von Klitzing in 1980

Correlations of Electrons in Magnetic Fields

Michael Fuhrer Director, FLEET Monash University

Application of BCS-like Ideas to Superfluid 3-He

Sep. 23, 2008 Correlated tunneling and the instability of the fractional quantum Hall edge Dror Orgad Oded Agam PRL 100, (2008)

News from Princeton Flatlands!

FSU Physics Department

Real-space imaging of a nematic quantum liquid

Presentation transcript:

Pinning Mode Resonances of 2D Electron Stripe Phases in High Landau Levels Han Zhu ( 朱涵 ) Physics Department, Princeton University National High Magnetic Field Laboratory, Florida State University G. Sambandamurthy, NHMFL/FSU&Princeton EE, now SUNY buffalo Pei-Hsun Jiang, NHMFL/FSU&Princeton EE R. M. Lewis, NHMFL/FSU, now U Maryland Yong Chen Princeton EE&NHMFL/FSU, now Purdue L. Engel NHMFL/FSU D. C. Tsui, Princeton EE L. N. Pfeiffer and K. W. West Bell Labs, Alcatel-Lucent

2D electron systems Al x Ga 1-x As GaAs 10~50 nm -Late 90’s, 10 m  Integer Quantum Hall Effect  Fractional Quantum Hall Effect  Fractional Quantum Hall Effect of Composite Fermions  Stripes, Bubbles, etc.  Non-Abelian states -1980, 100 k m m -80’-90’, 1 m Electron mobility (cm 2 /Vs)

Lilly et al, ’99... CDW in Quantum Hall systems Landau Level filling ν> 4  Fogler et al. ’96, R. Moessner, and J. T. Chalker, 96’  4 IQHE-Wigner Crsytal hard easy R_yy R_xx

Different viewpoints on the stripe phase Stripe crystal smectic nematic Also, elliptical Fermi surface... Oganesyan, Kivelson, Fradkin’01 A review available by Fogler in cond-mat...

Wigner crystal: Pinning modes B f pk is a measure of average pinning energy per electron; pinning energy lowers overall energy In high B, at low filling factors, electrons form a Wigner crystal

 Microwave/rf measuring technique  Stripe phase: anisotropic pinning mode  Stripe phase in In-plane field: Turns resonances on and off Interpretation: pinning energy measured by resonance frequency Outline

W =78  m Metal-film coplanar waveguide Microwave/Rf spectroscopy Re(  xx ) =  (1/N  Z 0 )ln(P/ P 0 ) E rf

stripe [110], “x”, “hard” [110], “y”, “easy” n = 2.6  cm -2 μ= 2.9  10 7 cm 2 /Vs T ~ 35 mK Predicted ν range: Shibata& Yoshioka, PRL ’01 Spectra 4<ν<5 bubble

[110], “x”, “hard” [110], “y”, “easy” Spectra 4<ν<5 : overview stripe bubble

DC experiments: Pan et al., PRL, ‘99 & PRL, ‘00; Lilly et al., PRL, ’99; Zhu et al., PRL, ‘02; Cooper et al., PRL, ‘04 etc. and more... Lilly et al., PRL, 1999 B ip ν =9/2 in B ip DC transport: R_xx R_yy y, [110] x, [110] (Finite thickness) B ip - induced anisotropy energy  CDW picture  Finite layer thickness  Favors stripe  Bip Jungwirth et al. PRB 99’; Stanescu et al. PRL 00’.

Rotator Probe for Microwave/Rf spectroscopy SampleFlexible transmission lineCoax cable B ip =0 stripes y, [110] x, [110] Four cases:  _xx or  _yy  B ip || x or y

B ip brings up f pk of resonance in  xx B ip =0 stripes x, [11 ̅ 0] y, [110] B ip B ip along y Resonance switches from  xx to  yy around B ip =1 T

B ip B ip along x B ip =0 stripes x, [11 ̅ 0] y, [110]

Peak Conductivity B ip y, [110] x, [110]

B ip Peak Frequency

K B Cooper et al.. Solid State Comm (2001) 30 nm QW, 2.7  /cm 2  Native Anisotropy  not understood, weak, sample dependent  Finite thickness B ip - induced anisotropy energy  Calculated from CDW, finite layer thickness,  Favors stripe  B ip Jungwirth et al. PRB 99’; Stanescu et al. PRL 00’  Measured by us: Pinning energy anisotropy  Disorder-carrier interaction,  B ip dependent: increases with B ip  Favors stripe | | B ip What can be determining the stripe orientation Pinning energy is relevant to determining stripe orientation!

 Stripe phase resonance  Hard direction 100 MHz, pinning mode interpretation  Apply B ip : switches resonance direction f pk increase with B ip measure of pinning energy B ip along x  xx  yy Summary