People of FOMO
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Invited Talk: Helmut Rauch and matter wave interferometry
Wolfgang P. Schleich1 Institut für Quantenphysik and Center for Integrated Quantum Science and Technology(IQST), Universität Ulm, Albert-Einstein-Allee 11, D-89081 Ulm, Germany2 Hagler Institute for Advanced Study and Department of Physics and Astronomy, Institutefor Quantum Science and Engineering (IQSE), Texas A&M AgriLife Research, Texas A&MUniversity, College Station, Texas 77843-4242, USA In this talk we pay respect to the impressive achievements of Helmut Rauch not only in the field of neutron optics but also his paving the way of matter wave interferometry. His numerous discoveries and deep insight into the inner workings of quantum mechanics have been a guidance to all of us.The superposition principle is a cornerstone of quantum mechanics and…
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Invited Talk: Persistent currents for ultracold fermions on a ring
Anna MinguzziCNRS and Universite Grenoble Alpes, LPMMC, Grenoble France We study the persistent currents of an interacting Fermi gas confined in a tightly confining ring trap and subjected to an artificial gauge field. For attractive interactions, we study the currents all through the BCS-BEC crossover. At weak attractions, on the BCS side, fermions display a parity effect in the persistent currents, i.e. their response to the gauge field is paramagnetic or diamagnetic depending on the number of pairs on the ring. At resonance and on the BEC side of the crossover, we find a halving of the periodicity of the ground-state energy as a function of the artificial gauge field…
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Invited Talk: One-minute coherence in an optical-lattice based atom interferometer
Holger MuellerUC Berkeley In quantum metrology and quantum information processing, a nonclassical state must undergo a quantum process before unwanted interactions with the environment lead to decoherence. In atom interferometry, the nonclassical state is a coherent spatial superposition of partial wave packets and the process might be, e.g., accumulation of sufficient phase shift to allow detection of extremely weak interactions, such as the gravitational field of a small proof mass. The coherence in atomic fountains is limited by the available free-fall time in Earth’s gravitational field. This can be overcome by suspending the wave packets in an optical lattice, which has so far reached up to 20 s of coherence,…
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Invited Talk: Neutron interferometry for studies of experimental quantum mechanics
Yuji Hasegawa1,21Atominstitut, TU-Wien, Stadionallee 2, A-1020 Vienna, AUSTRIA2Division of Applied Physics, Hokkaido University, Sapporo, Hokkaido, 060-0808, JAPAN Neutron interferometers provide ideal situations of experimental observations of interference between coherently split, well-separated beams of matter waves, in this case neutron de Broglie waves. Interferometers made of perfect silicon crystal was invented for x-rays in 1964 and first performance with neutrons was confirmed by Rauch, Treimer and Bonse at the Atominstitut, Vienna in 1974. The Atominstitut was distinguished as an European-Physical-Society (EPS) Historic Site on 22 May 2019. Over the past almost half century, neutron interferometer experiments are bringing impact on fundamental quantum and neutron physics [1-3].Since the time-independent Schrödinger equation, i.e.,…
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Invited Talk: Superfluid quantum Bose gas on a shell
Hélène PerrinUniversité Sorbonne, France Quantum gases provide us with a very convenient and widely tunable system for the study of superfluidity. In particular, they can be confined in a large variety of geometries (harmonic traps, optical lattices, box traps, lower dimensional traps…), enabling the study of superfluid dynamics with specific constrains. In this talk I will present the behaviour of a superfluid quantum gas confined at the surface of an ellipsoid: the atoms can move freely in directions parallel to the surface and are strongly confined in the transverse direction. In a first series of experiments, the atoms initially at rest at the bottom of the shell -because of gravity-…
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Invited Talk: Determination of the fine-structure constant using atom interferometry
Léo Morel1, Zhibin Yao1, P. Cladé1 and S. Guellati-Khelifa1,21Laboratoire Kastler Brossel, Sorbonne University, CNRS, ENS-PSL University, College de France, 4 place Jussieu, 75005 Paris, France2Conservatoire National des Arts est Métiers, 292 rue Saint Martin, 75003 Paris, France To test the standard model, we need to know the parameters that scale the fundamental interactions. Among them, the fine structure constant which characterizes the strength of the electromagnetic interaction and thus plays a crucial role in quantum electrodynamics calculations. Using atom interferometry to measure the quotient ħ/mRb of the reduced Planck’s constant and the mass of a rubidium-87 atom, we obtained the most accurate determination of the fine structure constant α=1/137.035999206(11) with…
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Invited Talk: Quantum control of an array of optically levitated nanoparticles
Uros DelicUniversity of Vienna The field of quantum optomechanics aims to exploit light-matter interaction in order to realize macroscopic quantum states of massive solid-state mechanical objects. Within optomechanics, optically levitated dielectric nanoparticles have emerged as a promising platform for tests of fundamental physics, development of novel sensing techniques or investigation of complex non-equilibrium physics. Optical trapping provides unique possibilities for quantum state preparation, for example through engineering of dynamic and nonlinear optical potentials. I will discuss recent experimental advances in levitated optomechanics, such as the motional quantum ground state preparation [1] and the observation of non-reciprocal optical interactions between two nanoparticles [2]. The rapidly developing control toolbox allows us to…
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Invited Talk: From new ways of free electron control to the coherence of multi-electron pulses
Peter HommelhoffUniversity of Erlangen, Germany Electric and magnetic fields generated from microstructures allow complex field configurations. We use this approach to build chip-based guides, i.e. two-dimensional Paul traps, for free low-energy electrons (1 eV to keV level). In addition, we have demonstrated guided electron beamsplitters and other elements, ideally suited for matter wave experiments with electrons. In the second part of the talk, I will show that fully coherent electron beams can be easily generated from needle tip emitters, including coherent electron pulses with femtosecond time resolution. Because of the charged nature of the electrons, their coherence is reduced even for a mean number of 1 electron per pulse due…
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Invited Talk: Cold Atom Quantum Technology to Explore Fundamental Physics
Oliver BuchmuellerImperial College London I will outline in the presentation the scientific opportunities of a multi-stage programme based on cold atom quantum technology. The central goals of the programme are to search for ultra-light dark matter, to explore gravitational waves in the mid-frequency range between the peak sensitivities of LISA and LIGO/Virgo/ KAGRA/INDIGO/Einstein Telescope/Cosmic Explorer experiments, and to probe other frontiers in fundamental physics. This programme would complement other planned searches for dark matter, as well as probe mergers involving intermediate-mass black holes and explore early-universe cosmology.I will especially focus on key activities in the field: the recently funded AION project [1] in the UK, the proposed space mission proposal…
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Invited Talk: Strapdown Quantum Inertial Measurement Unit
B. Battelier, Q. d’Armagnac de Castanet, and P. BouyerLP2N, Laboratoire Photonique, Numérique et Nanosciences,Université Bordeaux–IOGS–CNRS:UMR 5298, 1 rue Francois Mitterrand, 33400 Talence, France S. Templier, P. Cheiney, B. Gouraud, V. Jarlaud, V. Menoret, B. Desruelle, H. Porte, and F. NapolitanoiXblue, 34 rue de la Croix de Fer, 78105 Saint-Germain-en-Laye, France B. BarrettDepartment of Physics, University of New Brunswick,8 Bailey Dr., Fredericton NB, E3B 5A3, Canada Since their first demonstration in the early 1990s, atom interferometers have proven to be excellent absolute inertial sensors—having been exploited as ultra-high sensitivity instruments for fundamental tests of physics and as state-of-the-art atomic gravimeters. As a result, they have been proposed as next generation sensors…
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Invited Talk: Dark matter searches with matter wave interferometry
Invited Talk by Andrei Derevianko: Dark matter searches with matter wave interferometry
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Invited Talk: Multi-photon Atom Interferometry via cavity-enhanced Bragg Diffraction
D. O. Sabulsky1, J. Junca 1, X. Zou1, A. Bertoldi1, M. Prevedelli2, Q. Beaufils3, R. Geiger3, A. Landragin3, P. Bouyer1, and B. Canuel1 (MIGA Consortium) 1 LP2N, Laboratoire Photonique, Numérique et Nanosciences, Université Bordeaux-IOGS-CNRS:UMR 5298, rue F. Mitterrand, F-33400 Talence, France2 Dipartimento di Fisica e Astronomia, Universita di Bologna, Via Berti-Pichat 6/2, I-40126 Bologna, Italy3 LNE-SYRTE, Observatoire de Paris, Université PSL, CNRS, Sorbonne Université, 61 avenue de l´Observatoire, F-75014 Paris, France(Dated: August 22, 2022) We present our horizontal multi-photon atom interferometer driven via Bragg diffraction enhanced in an optical resonator. A large interrogation mode (4 mm 1/e2 diameter) is necessary in such a system, as the atoms cross the interrogation…
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Andrei Derevianko
Andrei Derevianko is teaching quantum physics and related subjects at the University of Nevada, Reno (UNR). He has authored over 100 refereed publications in theoretical physics. He is a fellow of the American Physical Society, Simons fellow in theoretical physics, and a Fulbright scholar. Among a variety of research topics, he has contributed to the development of several novel classes of atomic clocks and precision tests of fundamental symmetries with atoms and molecules. Recent interests include detection of ultralight dark matter with GPS. Upon graduating from FizTech, he was involved with a computer startup in Moscow and then moved to the United States. He earned his Ph.D. at Auburn and did…
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Stefan Gerlich
Stefan Gerlich is a Senior Scientist at the Quantumnanophysics Group at the University of Vienna.
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Holger Mueller
Holger Mueller has been advancing the physics of matter waves to probe nature at the utmost sensitivity. Examples are atom interferometry to measure gravity and the fine structure constant, phase-contrast electron microscopy, and optical recording of biological signals. He is a member of the Berkeley Physics Department, of Berkeley’s quantitative biology center QB3 as well as a faculty scientist at Lawrence Berkeley National Laboratory LBNL.
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Invited Talk: Matter-Waves lensing in Dynamic Wave-Guides
We have recently demonstrated smooth and controllable matter-wave guides by transporting Bose-Einstein condensates (BECs) over macroscopic distances without any heating or decohering their internal quantum states [9]. A neutral-atom accelerator ring was utilized to bring BECs to very high speeds (up to 16 times their sound velocity) and transport them in a magnetic matter-wave guide for 15 centimetres whilst fully preserving their internal coherence. We then use a magnetogravitational matter-wave lens to collimate and focus matterwaves in ring-shaped time-averaged adiabatic potentials. This “Delta-kick cooling” sequence of Bose-Einstein condensates reduces their expansion energies by a factor of 46 down to 800 pK. Compared to the state-of-the-art experiments, requiring zero gravity or large…
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Anton Zeilinger
Anton Zeilinger, born in 1945 in Austria, received his PhD from the University of Vienna in 1971. After a postdoctoral position with Helmut Rauch, one of the pioneers of neutron interferometry, at the Technical University of Vienna, Zeilinger joined the Neutron Diffraction Laboratory at MIT under Clifford G. Shull (Nobel Prize 1994). He held visiting appointments at Institut Laue-Langevin Grenoble, Collège de France, Oxford University, Technical University Munich and Humboldt University Berlin. In 1990, he became Chair of Experimental Physics at the University of Innsbruck and in 1999 Chair of Experimental Physics at the University of Vienna. He is presently Professor Emeritus at the University of Vienna and Senior Scientist…
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Dylan O Sabulsky
Dylan Sabulsky is an experimental atomic physicist working on the Matter-Wave laser Interferometer Gravitation Antenna (MIGA) project at the Laboratoire Souterrain à Bas Bruit (LSBB), with an attachment to the Institut d’Optique in Bordeaux. He oversees the construction, operation, and upgrade of MIGA at LSBB. His research interests focus on new high precision atomic physics experiments to test fundamental theories from the Standard Models of particle physics and cosmology.
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Baptiste Batellier
Working at Institut d’Optique in Bordeaux (France), Baptiste Battelier oversees experimental activities in microgravity to support the development of atom interferometry for future Space missions. In parallel he leads a joint laboratory with the French industrial iXblue to develop cold atom sensors for inertial navigation and onboard gravimetry.
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Michael Holinsky
Birmingham
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Oliver Buchmueller
Buchmueller is a Professor of Physics at Imperial College London, a Visiting Professor at Oxford University, a senior member of the CMS Collaboration, and the leading Principal Investigator of the Atom Interferometer Observatory and Network (AION) consortium [AION, JCAP 05 (2020) 011, arXiv:1911.11755] as well as the lead author of the Atomic Experiment for Dark Matter and Gravity Exploration in Space (AEDGE) mission [AEDGE, EPJ Quant. Tec. 7 (2020) 6, EPJ QT, 1908.00802]. He also spearheads the international community building process for Cold Atoms in Space, which brings together representatives of the cold atom, astrophysics, cosmology, fundamental physics, geodesy and earth observation communities [https://arxiv.org/abs/2201.07789]. Buchmueller’s research interests focus on several of the most intriguing…
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Nicola Poli
Nicola Poli is at the LENS – European Laboratory for Non-Linear Spectroscopy of the of the University of Florence in the group of Precision Measurements with Ultracold Atoms.
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Mauro Paternostro
Mauro Paternostro’s research interests are in the areas quantum information and quantum technology. He has worked on the foundations of quantum mechanics and the design of quantum technologies. His work has pioneered the fields of cavity optomechanics, quantum communication, quantum thermodynamics, and the foundations of quantum mechanics.
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Uros Delic
Uros Delic is a Senior Scientist in the group of Markus Aspelmeyer at the University of Vienna. His PhD research, conducted in the Aspelmeyer group, focused on cavity cooling of optically levitated nanoparticles. He defended his PhD thesis in 2019, for which he has received the Award of Excellence by the Austrian Ministry of Science, Research and Education. His research accomplishments include the first demonstration of motional quantum ground state cooling of a single nanoparticle and the demonstration of tunable dipole-dipole interactions between two particles. His current research focuses on quantum state engineering in a trap array of levitated particles and its application in quantum sensing and non-equilibrium physics. Photo…
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Hélène Perrin
Hélène Perrin is a Research Director at CNRS, working at Laser physics laboratory of Université Sorbonne Paris Nord where she leads the BEC group. She is the coordinator of the network Quantum Technologies in Paris Region (QuanTiP). Her research interest concern superfluid dynamics of quantum gases, quantum simulation, low dimensional quantum systems, adiabatic potentials, ring traps and bubble traps. Photo Credits: © Olivier Ezratty
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Yuji Hasegawa
Professor at Atominstitut, TU ViennaResearch interests: foundation of quantum mechanics Field of research: neutron optics, quantum optics, experimental physics
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Peter Hommelhoff
Peter Hommelhoff is professor of physics at Friedrich-Alexander-Universität Erlangen-Nürnberg in Erlangen, Germany. His main research interest comprise ultrafast electron matter wave control with the help of laser-driven nanophotonic structures, ultrafast electron matter wave control inside of graphene with phase-controlled few cycle light fields, attosecond physics at the surface of needle tips and quantum-enhanced electron microscopy. He recently received the Leibniz Prize of the DFG, the Innovation Prize of the Leibinger Foundation and an ERC Advanced Grant. Photo Credits: © R. Schmid
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Saïda Guellati-Khélifa
Saïda Guellati-Khelifa is a full professor at the National Conservatory of Arts and Crafts and researcher at the Kastler Brossel laboratory (LKB) where she leads the “Atomic Interferometry” team. Her research area focuses on high-precision measurements based on atom interferometry to perform highly precise tests of quantum electrodynamics and other fundamental theories. Currently, she is working on the measurement of the structure-fine constant, compact gravimetry, atom interferometry with a frequency comb and the test of the equivalence principle with anti-hydrogen in the framework of the international collaboration GBAR.
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Andrea Trombettoni
Ricercatore a Tempo Determinato B, University of Trieste & Ricercatore presso CNR- IOM
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Anna Minguzzi
Director of Research at the CNRS
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Arnaud Landragin
Arnaud Landragin is currently a research director at CNRS and director of the SYRTE laboratory. He obtained a PhD in physics from the University of Paris XI, Orsay, France, in 1997. After a two-year postdoctoral fellowship under the supervision of Prof. Kasevich at Yale University on an atomic gyroscope, USA, he joined the CNRS. His research focuses on the realisation and characterisation of atomic interferometers to be used as inertial sensors. He was awarded the Lamb Prize of the French Academy of Sciences in 2009 and the CNRS Medal for Innovation in 2020.
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Pierre Cladé
Pierre Cladé is chargé de recherche (CNRS) at Laboratoire Kastler Brossel. He is a specialist in atomic interferometry. He works in particular on the application of this technique to the measurement of the fine structure constant α. He is also part of the GBAR collaboration aiming at measuring the free fall acceleration of anti-matter in the earth gravity field.
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Guglielmo Tino
Guglielmo Tino is head of the cold atom laboratory at LENS, University of Florence.
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Clare Burrage
Clare Burrage is a Professor in the School of Physics and Astronomy at the University of Nottingham. Before coming to Nottingham she held research positions at the University of Geneva and at DESY (German Electron Synchrotron). She was awarded her PhD in 2008 from the University of Cambridge. In 2015 she was awarded the Maxwell Medal by the Institute of Physics for outstanding contributions to Theoretical Physics. She currently holds a Research Leadership Award from the Leverhulme Trust. She is a theoretical cosmologist, mainly interested in theories of dark energy and modified gravity.
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Wolfgang Schleich
Wolfgang P. Schleich is engaged in research on quantum optics ranging from the foundations of quantum physics via tests of general relativity with light and cold atoms to number theory. He was educated at the Ludwig Maximilians-Universität (LMU) in Munich and studied with Marlan O. Scully at the University of New Mexico, Albuquerque, and the Max-Planck Institute for Quantum Optics, Garching. Moreover, he was also a post doctoral fellow with John Archibald Wheeler at the University of Texas at Austin.Professor Schleich is a member of several national and international academies and has received numerous prizes and honors for his scientific work such as the Gottfried Wilhelm Leibniz Prize, the Max…
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Ernst Rasel
Ernst Rasel, Institute of Quantum Optics, University of Hannover, Germany
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Oliver Buchmueller
Oliver Buchmueller is a scientist and professor of physics at the Faculty of Natural Science, Imperial College London. Buchmueller is presently serving as one of the lead scientists on the CMS experiment at CERN’s LHC, the Principal Investigator of the Atom Interferometer Observatory and Network (AION) and also one of the lead authors at Atomic Experiment for Dark Matter and Gravity Exploration in Space (AEDGE). Previously he has been associated with ALPEH experiment at CERN’s LEP collider and the BaBar experiment at SLAC.
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Buchmüller, Oliver — Fundamental Forces — The SM, The Higgs Discovery, and GW Intro (Slides)
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Buchmüller, Oliver — Fundamental Forces — AION and AEDGE (Slides)
Lecture Slides (pdf) Lecture Slides (pptx)
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Lisa Wörner (Speaker at FOMO2021)
Lisa Wörner works at the ZARM – Center for Applied Space Technology and Microgravity, University of Bremen in the Space Technology Group. is a researcher with interests in different quantum mechanical areas. Her main focus is BECCAL (Bose Einstein Condensate and Cold Atom Laboratory), a joint mission between NASA and DLR to investigate atom optics under microgravity. In this capacity she is striving to advance fundamental quantum physics research in space as well as developing new technologies. This includes the preparation of experiments for extreme environments, tackling open challenges, finding novel solutions, and the ruggedization and miniaturization of setups. In addition to the research on cold and condensed atoms, she is involved in development of optical clocks and quantum repeaters for space based applications.…
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Lisa Wörner — Devices — MW Interferometry in Space (Lecture Slides)
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Philippe Bouyer (Speaker at FOMO2021)
Philippe Bouyer is research director at CNRS and deputy director of the Institut d’Optique Graduate School in Bordeaux. He received his doctorate at Ecole Normale Supérieure in 1995. Since then, he has been worked on atom interferometer-based inertial sensor experiments, atom lasers and Anderson localization with cold atoms. His current interests are the study of quantum simulators with ultracold atoms and the development of atom interferometers for testing general relativity in space or detecting gravity fields and gravitational waves underground. He is the recipient of the 2012 Louis D award of the French academy, APS fellow and OSA senior member.
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Lisa Wörner — Devices — MW Interferometry in Space (Lecture Video)
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Wolf von Klitzing
Wolf von Klitzing is research group leader of the Matterwave Optics and BEC group at IESL–FORTH on Crete in Greece. He is currently also heading the Atom Quantum Technologies COST network (AtomQT.eu). His main interests lie in guided matterwave interferometry and quantum space technologies.
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Mark Baker (Speaker at FOMO2021)
Mark Baker is a researcher in Quantum Technologies with DSTG (Defence Science and Technology Group), Australia. He is also Research Fellow & Honorary Senior Fellow at the School of Mathematics and Physics of the The University of Queensland.
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Wolf von Klitzing — Atomtronic Matterwave Guides (Lecture Slides)
Wolf von Klitzing is research group leader of the Matterwave Optics and BEC group at IESL–FORTH on Crete in Greece. He is currently also heading the Atom Quantum Technologies COST network (AtomQT.eu). His main interests lie in guided matterwave interferometry and quantum space technologies.
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Mark Baker — Devices: Painting Optical Potentials (Lecture Slides)
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Wolf von Klitzing — Atomtronic Matterwave Guides (Video)
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Mark Baker — Devices: Painting Optical Potentials (Video)
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Michael Holynski (Speaker at FOMO2021)
Michael Holynski is a Senior Lecturer in the Cold Atoms research group, part of the Midlands Ultracold Atom Research Centre, and the UK National Quantum Technology Hub in Sensors and Metrology. He leads the Atom Interferometry group, where he focuses on gravity gradient sensors and their use within applications. This includes developing gradiometers for use in the field and pushing to create more compact and deployable devices, while also investigating approaches to improve their sensitivity. Michael is active in enabling the translation and commercialisation of quantum technology, and leads a portfolio of collaborative projects with industry ranging from component development to system level realisation of industrial sensor prototypes and engagement…
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Stephanie Manz (Speaker at FOMO2021)
Stephanie Manz is University Assistant at TU Wien. Her main research interests are quantum metrologyand matter-wave optics with cold atoms and electrons, with a current focus on cold atoms and interferometry with trapped Bose-Einstein condensates. With a small team, she is developing a trapped Cesium interferometer with tunable interactions.
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Onur Hosten (Speaker at FOMO2021)
Onur Hosten is head of the Quantum Sensing with Atoms and Light Group at the Institute of Science and Technology Austria (IST Austria). He received his PhD from the University of Illinois at Urbana-Champaign and then worked as a postdoc and Research Associate at Stanford University, Palo Alto. His group aims to develop innovative techniques to control quantum properties of atomic and optical systems with an eye towards applications in the domain of precision sensing. By manipulating the collective properties of cold atomic ensembles in optical cavities, the group intends to build precision sensors of time, force, acceleration, and in the process gain more insight into foundational aspects of quantum mechanics. The current focus is developing…
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Luca Pezzé
Luca Pezzé is at QSTAR – Quantum Science and Technology in Arcetri of the Istituto Nazionale di Ottica, CNR-INO at LENS. His research activity focuses on the theory of quantum-enhanced interferometry, entanglement and quantum gases.
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Buchmüller, Oliver — Fundamental Forces (Video)
More Info: Fundamental Forces Lecture — AION and AEDGE (pdf) Fundamental Forces — The SM, The Higgs Discovery, and GW Intro.pdf (ppt)
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Augusto Smerzi
Augustois Director of Research at the Istituto Nazionale di Ottica, CNR-INO and head of the Theory of Quantum Information Group. at the QSTAR – Quantum Science and Technology in Arcetri. His research interests mainly focus on the theory of quantum enhanced interferometry, the dynamics of ultra cold gases andthe foundations of quantum mechanics.
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Manz, Stephanie — Interferometry 2.0: Interactions (Lecture Slides)
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Manz, Stephanie — Interferometry 2.0: Interactions (Video)
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Hosten, Onur — Interferometry 2.0: Entanglement (Video)
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Onur Hosten — Interferometry 2.0: Entanglement (Lecture Slides)
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Pezze, Luca — Interferometry 1.1: Quantum Statistics and information theory (Video 2)
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Pezze, Luca — Interferometry 1.1: Quantum Statistics and information theory (Video 1)
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Luca Pezzé — Interferometry 1.1: Quantum Statistics and information theory (Lecture Notes 3)
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Luca Pezzé — Interferometry 1.1: Quantum Statistics and information theory (Lecture Notes 2)
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Luca Pezzé — Interferometry 1.1: Quantum Statistics and information theory (Lecture Notes 1)
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Remi Geiger (Speaker at FOMO2021)
Remi Geigeris an Associate Professor of Physics at Sorbonne Université (Paris). His research at the SYRTE laboratory(Observatoire de Paris) focuses on the development of atom interferometry techniques serving high precision measurements of inertial effects, both for field applications and for future gravitational wave detectors.
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Geiger, Remi — Interferometry 1.0: Experiments (Video 2)
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Remi Geiger: Interferometry 1.0: Experiments (Lecture 1+2, Slides)
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Geiger, Remi — Interferometry 1.0: Experiments (Video 1)
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Remi Geiger — Interferometry 1.0: Experiments (Lecture 1, Notes)
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Augusto Smerzi — Interferometry 1.0: Theory (Lecture 2, notes)
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Augusto Smerzi — Interferometry 1.0: Theory (Lecture 2, notes)
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Smerzi, Augusto — Interferometry 1.0: Theory (Video 2)
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Smerzi, Augusto — Interferometry 1.0: Theory (Video 1)
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Augusto Smerzi — Interferometry 1.0: Theory (Lecture 1, Slides)
