Your search keyword '"L. Patthey"' showing total 4 results

1. Spin-orbital separation in the quasi-one-dimensional Mott insulator Sr2CuO3

Author

K.J. Zhou, J.E. van den Brink, Henrik M. Rønnow, Maurits W. Haverkort, L. Patthey, Martin Mourigal, Surjeet Singh, Vladimir N. Strocov, J. Schlappa, Claude Monney, Satoshi Nishimoto, Jean-Sébastien Caux, Liviu Hozoi, Krzysztof Wohlfeld, A. Revcolevschi, T. Schmitt, and Quantum Condensed Matter Theory (ITFA, IoP, FNWI)

Subjects

Physics, Multidisciplinary, Orbiton, Condensed matter physics, Mott insulator, 02 engineering and technology, Electron, Mott scattering, X-Ray-Scattering, 021001 nanoscience & nanotechnology, Quantum number, 01 natural sciences, Spinon, Azimuthal quantum number, Srcuo2, Atomic orbital, spin orbital separation, orbitons, RIXS, resonant inelastic x ray scattering, Excitations, 0103 physical sciences, Condensed Matter::Strongly Correlated Electrons, Atomic physics, 010306 general physics, 0210 nano-technology, Charge Separation

Abstract

When viewed as an elementary particle, the electron has spin and charge. When binding to the atomic nucleus, it also acquires an angular momentum quantum number corresponding to the quantized atomic orbital it occupies. Even if electrons in solids form bands and delocalize from the nuclei, in Mott insulators they retain their three fundamental quantum numbers spin, charge and orbital. The hallmark of one dimensional physics is a breaking up of the elementary electron into its separate degrees of freedom. The separation of the electron into independent quasiparticles that carry either spin spinons or charge holons was first observed fifteen years ago. Here we report observation of the separation of the orbital degree of freedom orbiton using resonant inelastic X ray scattering on the one dimensional Mott insulator Sr2CuO3. We resolve an orbiton separating itself from spinons and propagating through the lattice as a distinct quasiparticle with a substantial dispersion in energy over momentum, of about 0.2 electronvolts, over nearly one Brillouin zone

Published

2012

2. Spin-orbital separation in the quasi-one-dimensional Mott insulator Sr2CuO3.

Author

Schlappa J, Wohlfeld K, Zhou KJ, Mourigal M, Haverkort MW, Strocov VN, Hozoi L, Monney C, Nishimoto S, Singh S, Revcolevschi A, Caux JS, Patthey L, Rønnow HM, van den Brink J, and Schmitt T

Abstract

When viewed as an elementary particle, the electron has spin and charge. When binding to the atomic nucleus, it also acquires an angular momentum quantum number corresponding to the quantized atomic orbital it occupies. Even if electrons in solids form bands and delocalize from the nuclei, in Mott insulators they retain their three fundamental quantum numbers: spin, charge and orbital. The hallmark of one-dimensional physics is a breaking up of the elementary electron into its separate degrees of freedom. The separation of the electron into independent quasi-particles that carry either spin (spinons) or charge (holons) was first observed fifteen years ago. Here we report observation of the separation of the orbital degree of freedom (orbiton) using resonant inelastic X-ray scattering on the one-dimensional Mott insulator Sr2CuO3. We resolve an orbiton separating itself from spinons and propagating through the lattice as a distinct quasi-particle with a substantial dispersion in energy over momentum, of about 0.2 electronvolts, over nearly one Brillouin zone.

Published

2012

3. A tunable topological insulator in the spin helical Dirac transport regime.

Author

Hsieh D, Xia Y, Qian D, Wray L, Dil JH, Meier F, Osterwalder J, Patthey L, Checkelsky JG, Ong NP, Fedorov AV, Lin H, Bansil A, Grauer D, Hor YS, Cava RJ, and Hasan MZ

Abstract

Helical Dirac fermions-charge carriers that behave as massless relativistic particles with an intrinsic angular momentum (spin) locked to its translational momentum-are proposed to be the key to realizing fundamentally new phenomena in condensed matter physics. Prominent examples include the anomalous quantization of magneto-electric coupling, half-fermion states that are their own antiparticle, and charge fractionalization in a Bose-Einstein condensate, all of which are not possible with conventional Dirac fermions of the graphene variety. Helical Dirac fermions have so far remained elusive owing to the lack of necessary spin-sensitive measurements and because such fermions are forbidden to exist in conventional materials harbouring relativistic electrons, such as graphene or bismuth. It has recently been proposed that helical Dirac fermions may exist at the edges of certain types of topologically ordered insulators-materials with a bulk insulating gap of spin-orbit origin and surface states protected against scattering by time-reversal symmetry-and that their peculiar properties may be accessed provided the insulator is tuned into the so-called topological transport regime. However, helical Dirac fermions have not been observed in existing topological insulators. Here we report the realization and characterization of a tunable topological insulator in a bismuth-based class of material by combining spin-imaging and momentum-resolved spectroscopies, bulk charge compensation, Hall transport measurements and surface quantum control. Our results reveal a spin-momentum locked Dirac cone carrying a non-trivial Berry's phase that is nearly 100 per cent spin-polarized, which exhibits a tunable topological fermion density in the vicinity of the Kramers point and can be driven to the long-sought topological spin transport regime. The observed topological nodal state is shown to be protected even up to 300 K. Our demonstration of room-temperature topological order and non-trivial spin-texture in stoichiometric Bi(2)Se(3).M(x) (M(x) indicates surface doping or gating control) paves the way for future graphene-like studies of topological insulators, and applications of the observed spin-polarized edge channels in spintronic and computing technologies possibly at room temperature.

Published

2009

4. Experimental evidence for sub-3-fs charge transfer from an aromatic adsorbate to a semiconductor.

Author

Schnadt J, Brühwiler PA, Patthey L, O'Shea JN, Södergren S, Odelius M, Ahuja R, Karis O, Bässler M, Persson P, Siegbahn H, Lunell S, and Mårtensson N

Abstract

The ultrafast timescale of electron transfer processes is crucial to their role in many biological systems and technological devices. In dye-sensitized solar cells, the electron transfer from photo-excited dye molecules to nanostructured semiconductor substrates needs to be sufficiently fast to compete effectively against loss processes and thus achieve high solar energy conversion efficiencies. Time-resolved laser techniques indicate an upper limit of 20 to 100 femtoseconds for the time needed to inject an electron from a dye into a semiconductor, which corresponds to the timescale on which competing processes such as charge redistribution and intramolecular thermalization of excited states occur. Here we use resonant photoemission spectroscopy, which has previously been used to monitor electron transfer in simple systems with an order-of-magnitude improvement in time resolution, to show that electron transfer from an aromatic adsorbate to a TiO(2) semiconductor surface can occur in less than 3 fs. These results directly confirm that electronic coupling of the aromatic molecule to its substrate is sufficiently strong to suppress competing processes.

Published

2002