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Q: Fachverband Quantenoptik und Photonik
Q 20: Quantum Gases: Bosons III
Q 20.4: Vortrag
Dienstag, 24. März 2015, 11:45–12:00, P/H2
Measuring the Chern number of Hofstadter bands with ultracold bosonic atoms — •Michael Lohse1,2, Monika Aidelsburger1,2, Christian Schweizer1,2, Marcos Atala1,2, Julio Barreiro1,2, Sylvain Nascimbène3, Nigel Cooper4, Immanuel Bloch1,2, and Nathan Goldman3,5 — 1Fakultät für Physik, LMU München, Germany — 2MPQ Garching, Germany — 3Collège de France & LKB, CNRS, UPMC, ENS, Paris, France — 4T.C.M. Group, Cavendish Laboratory, Cambridge, UK — 5CENOLI, Faculté des Sciences, Université Libre de Bruxelles, Belgium
Sixty years ago, Karplus and Luttinger pointed out that quantum particles moving on a lattice could acquire an anomalous transverse velocity in response to a force, providing an explanation for the unusual Hall effect in ferromagnetic metals. A striking manifestation of this transverse transport was then revealed in the quantum Hall effect, where the plateaus depicted by the Hall conductivity were attributed to a topological invariant characterizing Bloch bands: the Chern number. Until now, topological transport associated with non-zero Chern numbers has only been revealed in electronic systems. Here we use studies of an atomic cloud’s transverse deflection in response to an optical gradient, in combination with the determination of the band populations to measure the Chern number ν of artificially generated Hofstadter bands; for the lowest band we obtain an experimental value of νexp=0.99(5). This result, which constitutes the first Chern-number measurement in an atomic system, is facilitated by an all-optical artificial gauge field scheme, generating uniform flux in optical superlattices.