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16:15 |
Q 62.1 |
Creating Homogeneous Two-Dimensional Fermi Gases — •Fynn Förger, Lennart Sobirey, Niclas Luick, Klaus Hueck, Jonas Siegl, Thomas Lompe, and Henning Moritz
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16:15 |
Q 62.2 |
Exploring the doped Fermi-Hubbard model in low dimensions — •Jayadev Vijayan, Timon Hilker, Guillaume Salomon, Joannis Koepsell, Michael Höse, Immanuel Bloch, and Christian Gross
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16:15 |
Q 62.3 |
Detecting correlations in deterministically prepared quantum states with single-atom imaging — •Andrea Bergschneider, Vincent M. Klinkhamer, Jan Hendrik W. Becher, Ralf Klemt, Gerhard Zürn, Philipp M. Preiss, and Selim Jochim
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16:15 |
Q 62.4 |
Correlations of strongly attractive few-fermion systems — •Philipp M. Preiss, Vincent Klinkhamer, Ralf Klemt, Andrea Bergschneider, Jan Hendrik Becher, Gerhard Zürn, and Selim Jochim
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16:15 |
Q 62.5 |
Towards a lithium quantum gas microscope for small quantum systems — •Andreas Kerkmann, Michael Hagemann, Mathis Fischer, Benno Rem, Christof Weitenberg, and Klaus Sengstock
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16:15 |
Q 62.6 |
An experiment for the study of small Hubbard models with rapid repetition rate — •Martin Schlederer, Phillip Wieburg, Alexandra Mozdzen, Thomas Lompe, and Henning Moritz
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16:15 |
Q 62.7 |
Coherent Manipulation of Spin Correlations in the Hubbard Model — •Nicola Wurz, Chun Fai Chan, Marcell Gall, Jan Henning Drewes, Eugenio Cocchi, Luke Alexander Miller, Daniel Pertot, Ferdinand Brennecke, and Michael Köhl
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16:15 |
Q 62.8 |
The Bose Polaron in an ultracold Bose-Fermi mixture of 133Cs and 6Li — •Melina Filzinger, Binh Tran, Manuel Gerken, Markus Neiczer, Stephan Häfner, Bing Zhu, Matthias Weidemüller, Moritz Drescher, and Tilman Enss
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16:15 |
Q 62.9 |
Towards double degeneracy of a Bose-Fermi mixture of 133Cs and 6Li — •Markus Neiczer, Manuel Gerken, Binh Tran, Melina Filzinger, Stephan Häfner, Bing Zhu, and Matthias Weidemüller
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16:15 |
Q 62.10 |
Higher partial wave Feshbach resonances in an ultracold mixture of 6Li and 133Cs atoms — •Manuel Gerken, Stephan Häfner, Bing Zhu, Binh Tran, Juris Ulmanis, Eberhard Tiemann, and Matthias Weidemüller
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16:15 |
Q 62.11 |
Interacting Rydberg Polaritons for Photonic Quantum Logic — •Thomas Stolz, Steffen Schmidt-Eberle, Daniel Tiarks, Stephan Dürr, and Gerhard Rempe
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16:15 |
Q 62.12 |
Towards an efficient on-demand single-photon source based on atomic microcells — •Florian Christaller, Fabian Ripka, Hao Zhang, Annika Belz, Harald Kübler, Robert Löw, and Tilman Pfau
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16:15 |
Q 62.13 |
Surface Plasmon Enhanced Multipole Transitions of Rydberg Atoms — •Yijia Zhou and Weibin Li
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16:15 |
Q 62.14 |
Rydberg excitations of cold atoms inside a hollow-core fiber — •Parvez Islam, Maria Langbecker, Mohammad Noaman, Chantal Voss, Ronja Wirtz, Wei Li, and Patrick Windpassinger
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16:15 |
Q 62.15 |
3D image reconstruction using symmetries applied to cold Rydberg gases — •Henrik Zahn, Renato Ferracini Alves, Miguel Ferreira Cao, Titus Franz, Adrien Signoles, Nithiwadee Thaicharoen, Gerhard Zürn, and Matthias Weidemüller
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16:15 |
Q 62.16 |
Measuring non-linear susceptibility in a Rydberg EIT medium — •Clément Hainaut, Annika Tebben, Valentin Walther, Renato Ferracini Alves, Yongchang Zhang, Andre Salzinger, Nithiwadee Thaicharoen, Gerhard Zürn, Thomas Pohl, and Matthias Weidemüller
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16:15 |
Q 62.17 |
Relaxation of an isolated Rydberg-spin system in an external field — •Nithiwadee Thaicharoen, Adrien Signoles, Miguel Ferreira-Cao, Renato Ferracini Alves, Titus Franz, Andre Salzinger, Asier Piñeiro Orioli, Martin Gärttner, Jürgen Berges, Shannon Whitlock, Gerhard Zürn, and Matthias Weidemüller
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16:15 |
Q 62.18 |
The contribution has been withdrawn.
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16:15 |
Q 62.19 |
Proposal to identify Thermal and Non-Thermal fixed points in a strongly interacting Rydberg gas. — •Titus Franz, Renato Ferracini Alves, Miguel Ferreira Cao, Adrien Signoles, Nithiwadee Thaicharoen, Shannon Whitlock, Gerhard Zuern, Jürgen Berges, and Matthias Weidemüller
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16:15 |
Q 62.20 |
Measuring Spin Magnetization in a Two-Level Rydberg System Using State Selective Field Ionization — •Alexander Müller, Renato Ferracini Alves, Titus Franz, Clément Hainaut, Nithiwadee Thaicharoen, Gerhard Zürn, and Matthias Weidemüller
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16:15 |
Q 62.21 |
High resolution microscopy of cold atoms — Lea Steinert, •Raphael Nold, Markus Stecker, József Fortágh, and Andreas Günther
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16:15 |
Q 62.22 |
Tailoring ionization of highly Stark shifted Rubidium Rydberg states — •Jens Grimmel, Markus Stecker, Manuel Kaiser, Peter Zwissler, Florian Karlewski, Andreas Günther, and József Fortágh
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16:15 |
Q 62.23 |
Design and characterization of a low-cost cateye laser for scientific applications — •Shubha Deutschle, Simon Schuster, Philip Wolf, Max Eisele, Sonja Lorenz, Claus Zimmermann, József Fortágh, and Andreas Günther
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16:15 |
Q 62.24 |
Optical transport of ultracold atoms for the production of groundstate RbYb — •Tobias Franzen, Bastian Pollklesener, Alexander Mietke, and Axel Görlitz
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16:15 |
Q 62.25 |
Cavity-controlled chemical reactions of ultracold atoms — Tobias Kampschulte, •Simon Rupp, Jan Schnabel, Andreas Köhn, and Johannes Hecker Denschlag
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16:15 |
Q 62.26 |
Formation of ultracold 6Li133Cs Feshbach molecules — •Jonas Matthies, Manuel Gerken, Binh Tran, Stephan Häfner, Melina Filzinger, Markus Neiczer, Bing Zhu, and Matthias Weidemüller
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16:15 |
Q 62.27 |
Feshbach resonances and degenerate quantum mixtures of bosonic sodium and potassium — •Philipp Gersema, Torben Schulze, Torsten Hartmann, Kai Voges, Jannis Schnars, Matthias Gempel, Eberhard Tiemann, Alessandro Zenesini, and Silke Ospelkaus
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16:15 |
Q 62.28 |
A magic 1D lattice for ultracold, polar NaK molecules — •Frauke Seeßelberg, Xin-Yu Luo, Ming Li, Scott Eustice, Svetlana Kotochigova, Immanuel Bloch, and Christoph Gohle
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16:15 |
Q 62.29 |
A 3D Optical Lattice for the Creation of a Dense, Ultracold 23Na40K Gas — •Scott Eustice, Xin-Yu Luo, Frauke Seeßelberg, Immanuel Bloch, and Christoph Gohle
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16:15 |
Q 62.30 |
Atom-chip-based interferometry with Bose-Einstein condensates — •Martina Gebbe, Matthias Gersemann, Sven Abend, Sven Herrmann, Claus Lämmerzahl, Ernst M. Rasel, and The QUANTUS Team
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16:15 |
Q 62.31 |
Autonomous control of a laser system for dual-species atom interferometry on board a sounding rocket — •Benjamin Wiegand, Klaus Döringshoff, Oliver Anton, Simon Kanthak, Markus Krutzik, Achim Peters, and The Maius team
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16:15 |
Q 62.32 |
A robust laser system for atom interferometry with rubidium on very long baselines — •Dorothee Tell, Christian Meiners, Etienne Wodey, Dennis Schlippert, Christian Schubert, Wolfgang Ertmer, and Ernst M. Rasel
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16:15 |
Q 62.33 |
Quantum optics on the ISS — •Kai Frye, Dennis Becker, Christian Schubert, Thijs Wendrich, Ernst Maria Rasel, and BECCAL Team
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16:15 |
Q 62.34 |
Novel techniques for atom interferometry — •Dennis Schlippert, Henning Albers, Claus Braxmaier, Felipe Guzmán, Lee Kumanchik, Dipankar Nath, Logan Richardson, Simon Roßmann, Christian Schubert, Ashwin Thennadil, Wolfgang Ertmer, and Ernst Rasel
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16:15 |
Q 62.35 |
Gravity sensing with Very Long Baseline Atom Interferometry — •Etienne Wodey, Manuel Schilling, Christian Meiners, Dorothee Tell, Dennis Schlippert, Christian Schubert, Ludger Timmen, Wolfgang Ertmer, Jürgen Müller, and Ernst M. Rasel
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16:15 |
Q 62.36 |
Automated control-electronics for a dual species atom interferometer on a sounding rocket. — Wolfgang Bartosch, Thijs Wendrich, Ernst Maria Rasel, Wolfgang Ertmer, and •Tobias Panzier
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16:15 |
Q 62.37 |
Operating a mobile Gravimetric Atom Interferometer GAIN at the fundamental station Wettzell — •Anne Stiekel, Bastian Leykauf, Vladimir Schkolnik, Christian Freier, Hartmut Wziontek, Axel Rülke, Markus Krutzik, and Achim Peters
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16:15 |
Q 62.38 |
Tackling leading order uncertainties in atom gravimetry — •Nina Grove, Maral Sahelgozin, Jonas Matthias, Jan Philipp Barbey, Sven Abend, Waldemar Herr, and Ernst M. Rasel
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16:15 |
Q 62.39 |
Coherent beam combination and power actuation of high power lasers for gravitational wave detectors — Nina Bode and •Benno Willke
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16:15 |
Q 62.40 |
Progress Towards an Al+ Quantum Logic Optical Clock — Nils Scharnhorst, •Johannes Kramer, Ian D. Leroux, Nicolas Spethmann, and Piet O. Schmidt
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16:15 |
Q 62.41 |
Towards a transportable 27Al+ quantum logic optical clock — •Lennart Pelzer, Stephan Hannig, Mariia Stepanova, Johannes Kramer, Nils Scharnhorst, Nicolas Spethmann, and Piet O. Schmidt
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16:15 |
Q 62.42 |
Towards a test of Local Lorentz Symmetry with 172Yb+ ions — •Chih-Han Yeh, André P. Kulosa, Alexandre Didier, Dimitri Kalincev, Jan Kiethe, Tabea Nordmann, Nimrod Hausser, and Tanja E. Mehlstäubler
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16:15 |
Q 62.43 |
48 cm long ultra-stable glass resonator with crystalline mirror coatings — •Steffen Sauer, Steffen Rühmann, Dominika Fim, Klaus Zipfel, Nandan Jha, Waldemar Friesen-Piepenbrink, Rasmus Holst, Sebastian Häfner, Thomas Legero, Wolfgang Ertmer, Uwe Sterr, and Ernst Rasel
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16:15 |
Q 62.44 |
An optical lattice clock based on Magnesium — •Waldemar Friesen-Piepenbrink, Dominika Fim, Klaus Zipfel, Steffen Rühmann, Nandan Jha, Steffen Sauer, Wolfgang Ertmer, and Ernst Rasel
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16:15 |
Q 62.45 |
Operating a high-accuracy lattice optical clock with a filtered tapered amplifier lattice laser — •Pramod Mysore Srinivas, Stefano Origlia, Stephen Schiller, Christian Lisdat, Uwe Sterr, Jürgen Stuhler, Stefan Baumgärtner, and Rudolf Neuhaus
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16:15 |
Q 62.46 |
Non-magnetic setup for an Indium multi-ion clock — •Tabea Nordmann, Hartmut Nimrod Hausser, Alexandre Didier, Jan Kiethe, and Tanja E. Mehlstäubler
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16:15 |
Q 62.47 |
Interrogating optical clocks beyond the coherence limit of the clock laser — •Roman Schwarz, Ali Al-Masoudi, Sören Dörscher, Marcin Bober, Richard Hobson, Uwe Sterr, and Christian Lisdat
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16:15 |
Q 62.48 |
Twisted-light--ion interaction: the role of longitudinal fields — Guillermo. F. Quinteiro, Christian. T. Schmiegelow, and •Ferdinand Schmidt-Kaler
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16:15 |
Q 62.49 |
Dynamics in quantum metrology — •Lukas J. Fiderer and Daniel Braun
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16:15 |
Q 62.50 |
Setup for the measurement of stress-induced optical birefringence — •Jan Meyer, Johannes Dickmann, Rene Glaser, Carol Bibiana Rojas Hurtado, Walter Dickmann, and Stefanie Kroker
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16:15 |
Q 62.51 |
High frequency precision quantum metrology — •Nicolas Staudenmaier, Simon Schmitt, Liam P. McGuinness, and Fedor Jelezko
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16:15 |
Q 62.52 |
Towards ultrasensitive mass sensing using single spins in diamond — •Tetyana Shalomayeva, Thomas Oeckinghaus, Ali Momenzadeh, Dominik Schmid-Lorch, Durga Dasari, Amit Finkler, Rainer Stöhr, and Jörg Wrachtrup
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16:15 |
Q 62.53 |
Coarse-grained master equation for an optical dense atomic ensemble — •Aleksei Konovalov, Andreas Alexander Buchheit, and Giovanna Morigi
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16:15 |
Q 62.54 |
Collective hyperfine splitting in resonant x-rays scattering — •Xiangjin Kong and Adriana Pálffy
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16:15 |
Q 62.55 |
Polaritonic Contribution to the Casimir Interaction in Graphene Systems — •Christoph Egerland, Francesco Intravaia, and Kurt Busch
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16:15 |
Q 62.56 |
Proximity force approximation and specular reflection: application of WKB Mie scattering to the Casimir effect — •Benjamin Spreng, Michael Hartmann, Vinicius Henning, Paulo A. Maia Neto, and Gert-Ludwig Ingold
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16:15 |
Q 62.57 |
Towards chiral cavity quantum electrodynamics with ensembles of atoms around an optical nanofiber — •Aisling Johnson, Martin Blaha, Alexander Ulanov, Philipp Schneeweiss, and Arno Rauschenbeutel
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16:15 |
Q 62.58 |
Optical Heterodyne Detection of a Cross-Phase Modulation Mediated by a Single Atom — •Jonas Neumeier, Nicolas Tolazzi, Bo Wang, Gang Li, Tatjana Wilk, and Gerhard Rempe
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16:15 |
Q 62.59 |
Fiber-cavity-based single-photon single-atom interface — •Elvira Keiler, Wolfgang Alt, Jose Gallego, Tobias Macha, Deepak Pandey, Eduardo Urunuela, Jian Wang, and Dieter Meschede
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16:15 |
Q 62.60 |
Strong Coupling between Photons via a four-level N-type atom — •Bo Wang, Nicolas Tolazzi, Jonas Neumeier, Christoph Hamsen, Gang Li, Tatjana Wilk, and Gerhard Rempe
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16:15 |
Q 62.61 |
Correlations between two coherently driven atoms in a cavity — •Marc-Oliver Pleinert, Joachim von Zanthier, and Girish Agarwal
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16:15 |
Q 62.62 |
Phases of cold atoms interacting via photon-mediated long-range forces — •Francesco Rosati, Tim Keller, Simon B. Jäger, and Giovanna Morigi
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16:15 |
Q 62.63 |
CO2 laser fabrication of mirrors for cavity QED — •Riccardo Cipolletti, Stefan Häussler, Andrea B. Filipovski, Max Deisböck, and Alexander Kubanek
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16:15 |
Q 62.64 |
High- quality- fiber- based microcavity for SiV− color centers in diamond. — •Richard Waltrich, Stefan Häussler, Kerem Bray, Fedor Jelezko, Igor Aharonovich, and Alexander Kubanek
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16:15 |
Q 62.65 |
Adiabatic flux insertion: growing quantum Hall states of cavity Rydberg polaritons — •David Dzsotjan, Peter Ivanov, Fabian Letscher, Jonathan Simon, and Michael Fleischhauer
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16:15 |
Q 62.66 |
X-ray cavity QED beyond the input-output formalism — •Dominik Lentrodt, Kilian P. Heeg, Christoph H. Keitel, and Jörg Evers
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16:15 |
Q 62.67 |
Coupling Silicon Vacancy centers in nanodiamond to open acess micro cavities — Andrea Filipovski, •Gregor Bayer, Olaf Zimmermann, and Alexander Kubanek
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16:15 |
Q 62.68 |
Towards the realisation of an atom trap in the evanescent field of a microresonator — •Luke Masters, Elisa Will, Michael Scheucher, Adele Hilico, Jürgen Volz, and Arno Rauschenbeutel
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16:15 |
Q 62.69 |
Classicalization of a scalar quantum field — •Marduk Bolaños, Benjamin A. Stickler, and Klaus Hornberger
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16:15 |
Q 62.70 |
Bunching and antibunching from a single light source — •Stefan Richter, Sebastian Wolf, Joachim von Zanthier, and Ferdinand Schmidt-Kaler
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16:15 |
Q 62.71 |
N00N-like Interferences from two Thermal Light Souces — •Daniel Bhatti, Anton Classen, Steffen Oppel, Raimund Schneider, and Joachim von Zanthier
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16:15 |
Q 62.72 |
Machine Learning to tackle the Entanglement Separability Problem in the Bloch Space — •Klaus Kades, Benjamin Claßen, Matthias Weidemüller, and Zhen-Sheng Yuan
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16:15 |
Q 62.73 |
Measurement of Quantum Memory Effects and its Fundamental Limitations — •Matthias Wittemer, Jan-Philipp Schröder, Govinda Clos, Ulrich Warring, Heinz-Peter Breuer, and Tobias Schaetz
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16:15 |
Q 62.74 |
Quantum non-Markovianity with single spins in diamond — •Philipp Vetter, Jan Haase, Thomas Unden, Andrea Smirne, Susana Huelga, and Fedor Jelezko
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16:15 |
Q 62.75 |
Rotational Decoherence of Molecular Superrotors — •Benjamin A. Stickler, Farhad Taher Ghahramani, and Klaus Hornberger
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16:15 |
Q 62.76 |
Describing a quantum eraser experiment with a symbolic in-out formalism — •Nico Klein, Manuel Daiber, Lutz Kasper, and Matthias Freyberger
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16:15 |
Q 62.77 |
Collective light-matter interaction in the presence of spin-orbit coupling of light — •Zaneta Kurpias, Stefan Walser, Jürgen Volz, and Arno Rauschenbeutel
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16:15 |
Q 62.78 |
Coupling cold atoms to a cryogenically cooled optomechanical device — •Philipp Christoph, Tobias Wagner, Felix Klein, Hai Zhong, Alexander Schwarz, Roland Wiesendanger, Klaus Sengstock, and Christoph Becker
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16:15 |
Q 62.79 |
Capillary Electrophoresis of Single Proteins via Interferometric Scattering Microscopy — •Mahyar Dahmardeh, Matthew P. McDonald, and Vahid Sandoghdar
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16:15 |
Q 62.80 |
Physics and Medicine — •Vahid Sandoghdar
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16:15 |
Q 62.81 |
Continuously frequency-tunable diode laser phase locked to an optical frequency comb — •Maximilian Ammenwerth, Lukas Ahlheit, Wolfgang Alt, Deepak Pandey, and Dieter Meschede
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16:15 |
Q 62.82 |
SHG in periodically poled crystals for cooling of relativistic ion beams — •Janika Schwalbach, Daniel Kiefer, and Thomas Walther
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16:15 |
Q 62.83 |
High Power SHG Laser System for 671nm — •Manuel Jäger, Daniel Hoffmann, Thomas Paintner, Wladimir Schoch, Wolfgang Limmer, and Johannes Hecker Denschlag
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16:15 |
Q 62.84 |
Investigations on a compact low cost molecular iodine laser — Bernd Wellegehausen, •Walter Luhs, and Mukul Goyal
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16:15 |
Q 62.85 |
Phase lock between diode lasers — Stefan Baumgärtner, Manfred Hager, Christoph Raab, Stephan Ritter, and •Stephan Falke
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16:15 |
Q 62.86 |
Quantitative analysis of a chemical reaction in a microfluidic device using stimulated Raman scattering microscopy — •Peter Fimpel, Martin Josef Winterhalter, and Andreas Zumbusch
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16:15 |
Q 62.87 |
Two-color coherent control at a nanotip: from above-threshold photoemission to spectroscopy on a metallic surface — •Ang Li, Timo Paschen, Michael Förster, Michael Krüger, Florian Libisch, Chritoph Lemell, Georg Wachter, Thomas Madlener, Joachim Burgdörfer, and Peter Hommelhoff
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16:15 |
Q 62.88 |
The contribution has been withdrawn.
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16:15 |
Q 62.89 |
Towards high spatial resolution temperature sensing in an optical fiber amplifier — •Alexandra Popp, Florian Sedlmeir, Atiyeh Zarifi, Birgit Stiller, Christian R. Müller, Ulrich Vogl, Victor Bock, Thomas Schreiber, Benjamin J. Eggleton, Andreas Tünnermann, Christoph Marquardt, and Gerd Leuchs
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16:15 |
Q 62.90 |
Optical modules for dual-species atom interferometry on sounding rockets — •Moritz Mihm, Jean Pierre Marburger, André Wenzlawski, Ortwin Hellmig, Klaus Doeringshoff, Markus Krutzik, Achim Peters, Patrick Windpassinger, and the MAIUS Team
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16:15 |
Q 62.91 |
Brillouin and Raman Measurements of Water for Temperature and Salinity Prediction — •Erik Fitzke, Andreas Zipf, David Rupp, and Thomas Walther
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16:15 |
Q 62.92 |
An XUV and soft X-ray split-and-delay unit for FLASH II — •Dennis Eckermann, Sebastian Roling, Matthias Rollnik, Marion Kuhlmann, Elke Plönjes, Frank Wahlert, and Helmut Zachairas
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16:15 |
Q 62.93 |
A split-and-delay unit for the European XFEL: Enabling hard x-ray pump/probe experiments at the HED instrument — •Sebastian Roling, Karen Appel, Peter Gawlitza, Harald Sinn, Frank Wahlert, Ulf Zastrau, and Helmut Zachairas
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16:15 |
Q 62.94 |
Wavefront propagation study concerning the influence of non-ideal mirror surfaces inside a split-and- delay unit on the focusability of XFEL-pulses — •Victor Kaercher, Sebastian Roling, Liobov Samoylova, Karen Appel, Harald Sinn, Frank Siewert, Ulf Zastrau, and Helmut Zacharias
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16:15 |
Q 62.95 |
A rapidly tunable (520−680 nm) narrow-bandwidth ps-laser pulse source based on a 1030 nm 80 MHz oscillator — •Lukas Ebner, Martin Josef Winterhalder, and Andreas Zumbusch
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16:15 |
Q 62.96 |
Accurate ultra-broadband amplitude andphase shaping in the visible — •Philipp Hillmann, Alexander Kastner, Jens Köhler, Cristian Sarpe, Hendrike Braun, Arne Senftleben, and Thomas Baumert
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16:15 |
Q 62.97 |
Towards sub-two-cycle optical pulse compression from Ti:sapphire oscillators — •Philip Dienstbier, Takuya Higuchi, Francesco Tani, Michael Frosz, John Travers, Philip St. J. Russell, and Peter Hommelhoff
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16:15 |
Q 62.98 |
Compression of femtosecond laser pulses using self-phase modulation in dielectric media — •Torben Purz, Sergey Zayko, Ofer Kfir, and Claus Ropers
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16:15 |
Q 62.99 |
Novel laser-driven photonic structures for high efficiency electron acceleration — •Peyman Yousefi, Joshua McNeur, Martin Kozák, Norbert Schönenberger, and Peter Hommelhoff
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16:15 |
Q 62.100 |
Numerical studies of electron pulse broadening in laser-triggered sources — •Johannes Illmer, Joshua McNeur, Martin Kozák, Norbert Schönenberger, and Peter Hommelhoff
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16:15 |
Q 62.101 |
Spatiotemporal characterization of laser filaments in noble gases — •Christoph Jusko, Lana Neoricic, Shiyang Zhong, Miguel Miranda, Cord Arnold, and Milutin Kovacev
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