J
Jörg Schmiedmayer
Researcher at Vienna University of Technology
Publications - 358
Citations - 21391
Jörg Schmiedmayer is an academic researcher from Vienna University of Technology. The author has contributed to research in topics: Quantum & Ultracold atom. The author has an hindex of 72, co-authored 344 publications receiving 19122 citations. Previous affiliations of Jörg Schmiedmayer include Rowland Institute for Science & University of Innsbruck.
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Journal ArticleDOI
Ramsey Interference in One-Dimensional Systems: The Full Distribution Function of Fringe Contrast as a Probe of Many-Body Dynamics
Takuya Kitagawa,Susanne Pielawa,Adilet Imambekov,Jörg Schmiedmayer,Vladimir Gritsev,Eugene Demler +5 more
TL;DR: It is argued that Ramsey interference experiments provide a powerful tool for analyzing strongly correlated nature of 1D interacting systems.
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Prethermalization Revealed by the Relaxation Dynamics of Full Distribution Functions
David Smith,Michael Gring,Tim Langen,Maximilian Kuhnert,Bernhard Rauer,Remi Geiger,Takuya Kitagawa,Igor Mazets,Eugene Demler,Jörg Schmiedmayer +9 more
TL;DR: In this article, the authors study the dynamics of a rapidly and coherently split one-dimensional Bose gas and show that the system dephases to a prethermalized state rather than undergoing thermalization towards a final thermal equilibrium state.
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Multimode Dynamics and Emergence of a Characteristic Length Scale in a One-Dimensional Quantum System
Maximilian Kuhnert,Remi Geiger,Tim Langen,Michael Gring,Bernhard Rauer,Takuya Kitagawa,Eugene Demler,D. Adu Smith,Jörg Schmiedmayer +8 more
TL;DR: The nonequilibrium dynamics of a coherently split one-dimensional Bose gas is studied by measuring the full probability distribution functions of matter-wave interference and revealing two distinct length-scale-dependent regimes of relaxation.
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Cavity QED with an ultracold ensemble on a chip: Prospects for strong magnetic coupling at finite temperatures
TL;DR: In this paper, the authors studied the nonlinear dynamics of an ensemble of cold trapped atoms with a hyperfine transition magnetically coupled to a resonant microwave cavity mode and obtained strong coupling between collective hyperfine qubits and microwave photons, enabling coherent transfer of an excitation between the long-lived atomic qubit state and the mode.