Your search keyword '"Efremov, Maxim A."' showing total 13 results

1. Perspectives and Opportunities: A Molecular Toolkit for Fundamental Physics and Matter Wave Interferometry in Microgravity

Author

D'Incao, Jose P., Williams, Jason R., Gaaloul, Naceur, Efremov, Maxim A., Nimmrichter, Stefan, Schrinski, Bjorn, Elliott, Ethan, and Ketterle, Wolfgang

Subjects

Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

The study of molecular physics using ultracold gases has provided a unique probe into the fundamental properties of nature and offers new tools for quantum technologies. In this article we outline how the use of a space environment to study ultracold molecular physics opens opportunities for 1) exploring ultra-low energy regimes of molecular physics with high efficiency, 2) providing a toolbox of capabilities for fundamental physics, and 3) enabling new classes of matter-wave interferometers with applications in precision measurement for fundamental and many-body physics., Comment: 6 pages

Published

2022

2. Matter-wave lensing of shell-shaped Bose-Einstein condensates

Author

Boegel, Patrick, Wolf, Alexander, Meister, Matthias, and Efremov, Maxim A.

Subjects

Quantum Gases (cond-mat.quant-gas), Atomic Physics (physics.atom-ph), FOS: Physical sciences, Condensed Matter - Quantum Gases, Physics - Atomic Physics

Abstract

Motivated by the recent experimental realization of ultracold quantum gases in shell topology, we propose a straightforward implementation of matter-wave lensing techniques for shell-shaped Bose-Einstein condensates. This approach allows to significantly extend the observation time of the condensate shell during its free expansion and enables the study of novel quantum many-body effects on curved geometries. With both analytical and numerical methods we derive optimal parameters for realistic lensing schemes to conserve the shell shape of the condensate for times up to hundreds of milliseconds.

Published

2022

3. Shell-shaped Bose-Einstein condensates realized with dual-species mixtures

Author

Meister, Matthias, Wolf, Alexander, Boegel, Patrick, Gaaloul, Naceur, and Efremov, Maxim

Subjects

quantum gas mixtures, shell topolgy, Bose-Einstein condensates

Published

2021

4. The Bose-Einstein Condensate and Cold Atom Laboratory

Author

Frye, Kai, Abend, Sven, Bartosch, Wolfgang, Bawamia, Ahmad, Becker, Dennis, Blume, Holger, Braxmaier, Claus, Chiow, Sheng-Wey, Efremov, Maxim A., Ertmer, Wolfgang, Fierlinger, Peter, Franz, Tobias, Gaaloul, Naceur, Grosse, Jens, Grzeschik, Christoph, Hellmig, Ortwin, Henderson, Victoria A., Herr, Waldemar, Israelsson, Ulf, Kohel, James, Krutzik, Markus, Kürbis, Christian, Lämmerzahl, Claus, List, Meike, Lüdtke, Daniel, Lundblad, Nathan, Marburger, J. Pierre, Meister, Matthias, Mihm, Moritz, Müller, Holger, Müntinga, Hauke, Nepal, Ayush M., Oberschulte, Tim, Papakonstantinou, Alexandros, Perovs̆ek, Jaka, Peters, Achim, Prat, Arnau, Rasel, Ernst M., Roura, Albert, Sbroscia, Matteo, Schleich, Wolfgang P., Schubert, Christian, Seidel, Stephan T., Sommer, Jan, Spindeldreier, Christian, Stamper-Kurn, Dan, Stuhl, Benjamin K., Warner, Marvin, Wendrich, Thijs, Wenzlawski, André, Wicht, Andreas, Windpassinger, Patrick, Yu, Nan, and Wörner, Lisa

Subjects

Condensed Matter::Quantum Gases, Atom optics, Bose-Einstein condensate, Quantum optics, ddc:530, Dewey Decimal Classification::500 | Naturwissenschaften::530 | Physik, Physics::Atomic Physics, Microgravity, Atom interferometry, 530 Physik, International Space Station

Abstract

Microgravity eases several constraints limiting experiments with ultracold and condensed atoms on ground. It enables extended times of flight without suspension and eliminates the gravitational sag for trapped atoms. These advantages motivated numerous initiatives to adapt and operate experimental setups on microgravity platforms. We describe the design of the payload, motivations for design choices, and capabilities of the Bose-Einstein Condensate and Cold Atom Laboratory (BECCAL), a NASA-DLR collaboration. BECCAL builds on the heritage of previous devices operated in microgravity, features rubidium and potassium, multiple options for magnetic and optical trapping, different methods for coherent manipulation, and will offer new perspectives for experiments on quantum optics, atom optics, and atom interferometry in the unique microgravity environment on board the International Space Station. All the Funding for this research are stated in the acknowledgment Projekt DEAL

Published

2021

5. Universality of excited three-body bound states in one dimension

Author

Happ, Lucas, Zimmermann, Matthias, and Efremov, Maxim

Subjects

Physics, Quantum Physics, High Energy Physics::Phenomenology, Binding energy, Universality (philosophy), FOS: Physical sciences, low-dimensional systems, Resonance, State (functional analysis), Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Dimension (vector space), few-body systems, Excited state, Quantum mechanics, Bound state, universality, Quantum Physics (quant-ph), Nuclear Experiment, Wave function

Abstract

We study a heavy–heavy–light three-body system confined to one space dimension in the regime where an excited state in the heavy–light subsystems becomes weakly bound. The associated two-body system is characterized by (i) the structure of the weakly-bound excited heavy–light state and (ii) the presence of deeply-bound heavy–light states. The consequences of these aspects for the behavior of the three-body system are analyzed. We find a strong indication for universal behavior of both three-body binding energies and wave functions for different weakly-bound excited states in the heavy–light subsystems.

Published

2022

6. The Bose-Einstein Condensate and Cold Atom Laboratory

Author

Frye, Kai, Abend, Sven, Bartosch, Wolfgang, Bawamia, Ahmad, Becker, Dennis, Blume, Holger, Braxmaier, Claus, Chiow, Sheng-Wey, Efremov, Maxim A., Ertmer, Wolfgang, Fierlinger, Peter, Gaaloul, Naceur, Grosse, Jens, Grzeschik, Christoph, Hellmig, Ortwin, Henderson, Victoria A., Herr, Waldemar, Israelsson, Ulf, Kohel, James, Krutzik, Markus, Kürbis, Christian, Lämmerzahl, Claus, List, Meike, Lüdtke, Daniel, Lundblad, Nathan, Marburger, J. Pierre, Meister, Matthias, Mihm, Moritz, Müller, Holger, Müntinga, Hauke, Oberschulte, Tim, Papakonstantinou, Alexandros, Perovšek, Jaka, Peters, Achim, Prat i Sala, Arnau, Rasel, Ernst Maria, Roura, Albert, Schleich, Wolfgang, Schubert, Christian, Seidel, Stephan T., Sommer, Jan, Spindeldreier, Christian, Stamper-Kurn, Dan, Stuhl, Benjamin K., Warner, Marvin, Wendrich, Thijs, Wenzlawski, Andre, Wicht, Andreas, Windpassinger, Patrick, Yu, Nan, and Wörner, Lisa

Subjects

Condensed Matter::Quantum Gases, Systems Enabling Technologies, Relativistische Modellierung, Atomic Physics (physics.atom-ph), Software für Raumfahrtsysteme und interaktive Visualisierung, Quanten Engineering, FOS: Physical sciences, International Space Station, Quantum Optics, Physics - Atomic Physics, Quantum Gases (cond-mat.quant-gas), AtomInterferometry, Theoretische Quantenphysik, Microgravity, Physics::Atomic Physics, Condensed Matter - Quantum Gases, Atom Optics, Bose-Einstein Condensate

Abstract

Microgravity eases several constraints limiting experiments with ultracold and condensed atoms on ground. It enables extended times of flight without suspension and eliminates the gravitational sag for trapped atoms. These advantages motivated numerous initiatives to adapt and operate experimental setups on microgravity platforms. We describe the design of the payload, motivations for design choices, and capabilities of the Bose-Einstein Condensate and Cold Atom Laboratory (BECCAL), a NASA-DLR collaboration. BECCAL builds on the heritage of previous devices operated in microgravity, features rubidium and potassium, multiple options for magnetic and optical trapping, different methods for coherent manipulation, and will offer new perspectives for experiments on quantum optics, atom optics, and atom interferometry in the unique microgravity environment on board the International Space Station.

Published

2019

7. Representation-free description of atom interferometers in time-dependent linear potentials

Author

Zimmermann, Matthias, Efremov, Maxim A., Zeller, Wolfgang, Schleich, Wolfgang P., Davis, Jon P., and Narducci, Frank A.

Subjects

DDC 530 / Physics, Astrophysics::Instrumentation and Methods for Astrophysics, ddc:530, Atom interferometry, Interferometer, Precision measurements, Representation-free formalism

Abstract

In this article we present a new representation-free formalism, which can significantly simplify the analysis of interferometers comprised of atoms moving in time-dependent linear potentials.We present a methodology for the construction of two pairs of time-dependent functions that, once determined, lead to two conditions for the closing of the interferometer, and determine the phase and the contrast of the resultant interference. Using this new formalism, we explore the dependency of the interferometer phase on the interferometer time T for different atom interferometers. By now, it is well established that light pulse atom interferometers of the type first demonstrated by Kasevich and Chu (1991 Phys. Rev. Lett. 67, 181–4; 1992 Appl. Phys. B 54, 321–32), henceforth referred to as Mach– Zehnder (MZ) atom interferometers, have a phase scaling as T2. A few years ago, McDonald et al (2014 Europhys. Lett. 105, 63001) have experimentally demonstrated a novel type of atom interferometer, referred to as the continuous-acceleration bloch (CAB) interferometer, where the phase reveals a mixed scaling which is governed by a combination of T2 and T3. Moreover, we have recently proposed a different type of atom interferometer (Zimmermann et al 2017 Appl. Phys. B 123, 102), referred to as the T3-interferometer, which has a pure T3 scaling, as demonstrated theoretically. Finally, we conclude that the CAB interferometer can be shown to be a hybrid of the standardMZinterferometer and the T3-interferometer., publishedVersion

Published

2019

8. Sufficient condition for a quantum state to be genuinely quantum non-Gaussian

Author

Happ, Lucas, Efremov, Maxim A., Nha, Hyunuchul, and Schleich, Wolfgang P.

Subjects

Wigner functions, DDC 530 / Physics, quantum information, non-Gaussian states, DDC 500 / Natural sciences & mathematics, Gaussian quadrature formulas, Quanteninformation, ddc:530, quadrature measurements, ddc:500, continuous variables, Gaussian state

Abstract

We show that the expectation value of the operator Ô ≡ exp (−cx̂²) + exp (−cpˆ²) defined by the position and momentum operators x̂ and pˆ with a positive parameter c can serve as a tool to identify quantum non-Gaussian states, that is states that cannot be represented as a mixture of Gaussian states. Our condition can be readily tested employing a highly efficient homodyne detection which unlike quantum-state tomography requires the measurements of only two orthogonal quadratures. We demonstrate that our method is even able to detect quantum non-Gaussian states with positive–definite Wigner functions. This situation cannot be addressed in terms of the negativity of the phase-space distribution. Moreover, we demonstrate that our condition can characterize quantum non-Gaussianity for the class of superposition states consisting of a vacuum and integer multiples of four photons under more than 50 % signal attenuation., publishedVersion

Published

2018

9. Erratum: Sufficient condition for a quantum state to be genuinely quantum non-Gaussian (2018 New J. Phys. 20 023046)

Author

Happ, Lucas, Efremov, Maxim A., Nha, Hyunchul, and Schleich, Wolfgang P.

Subjects

DDC 530 / Physics, Numerical integration, Quanteninformation, ddc:530, Quadraturformel, Continuity

Published

2018

10. Efficient description of Bose-Einstein condensates in time-dependent rotating traps

Author

Meister, Matthias, Arnold, Stefan, Moll, Daniela, Eckart, Michael, Kajari, Endre, Efremov, Maxim A., Walser, Reinhold, and Schleich, Wolfgang P.

Subjects

Condensed Matter::Quantum Gases, Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

Quantum sensors based on matter-wave interferometry are promising candidates for high-precision gravimetry and inertial sensing in space. The favorable source for the coherent matter waves in these devices are Bose-Einstein condensates. A reliable prediction of their dynamics, which is governed by the Gross-Pitaevskii equation, requires suitable analytical and numerical methods which take into account the center-of-mass motion of the condensate, its rotation and its spatial expansion by many orders of magnitude. In this chapter, we present an efficient way to study their dynamics in time-dependent rotating traps that meet this objective. Both, an approximate analytical solution for condensates in the Thomas-Fermi regime and dedicated numerical simulations on a variable adapted grid are discussed. We contrast and relate our approach to previous alternative methods and provide further results, such as analytical expressions for the one- and two-dimensional spatial density distributions and the momentum distribution in the long-time limit that are of immediate interest to experimentalists working in this field of research., 49 pages, 7 figures, preprint submitted to Advances in Atomic, Molecular, and Optical Physics Volume 66

Published

2017

11. Planar three-body bound states induced by $p$-wave interatomic resonance

Author

Efremov, Maxim A. and Schleich, Wolfgang P.

Subjects

Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

We consider the bound states of a system consisting of a light particle and two heavy bosonic ones, which are restricted in their quantum mechanical motion to two space dimensions. A $p$-wave resonance in the heavy-light short-range potential establishes the interaction between the two heavy particles. Due to the large ratio of the atomic masses this planar three-body system is perfectly suited for the Born-Oppenheimer approximation which predicts a Coulomb energy spectrum with a Gaussian cut-off., Comment: arXiv admin note: text overlap with arXiv:1407.3352

Published

2015

12. Quasi-Coulomb series in a two-dimensional three-body system

Author

Efremov, Maxim A. and Schleich, Wolfgang P.

Subjects

Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

We show that the bound states in a three-body system display a Coulomb series with a Gaussian cut-off provided: (i) the system consists of a light particle and two heavy bosonic ones, (ii) the heavy-light short-range potential has a resonance in the $p$-wave scattering amplitude, and (iii) all three particles move in two space dimensions. For a decreasing mass ratio this quasi-Coulomb series merges into a pure Coulombic one., Comment: 5 pages; submitted to Phys. Rev. Lett

Published

2014

13. Quantum non-Gaussianity and universality of one-dimensional three-body bound states

Author

Happ, Lucas Michael Carlo, Efremov, Maxim, and Ankerhold, Joachim

Subjects

Physik, DDC 530 / Physics, Quantum theory, Physics, Quantenphysik, Quanteninformation, ddc:530, Wenigteilchenphysik

Abstract

This cumulative thesis presents four publications (I)-(IV), Refs. [1-4], resulting from the author's research activities under the supervision of apl. Prof. Dr. M. A. Efremov at the Institut f��r Quantenphysik at Universit��t Ulm. These publications range over the scope of two subfields of quantum physics, namely quantum information theory and few-body physics. Accordingly, we have organized this thesis in two parts, each of which has its own introduction, conclusion and outlook. The first part is centered around publication (I) which concludes the author's work in the field of quantum information theory. This publication aims at classifying quantum states, in particular it presents a novel sufficient condition to determine whether a quantum state is genuinely quantum non-Gaussian. The class of non-Gaussian states are important in many aspects of quantum information, e.g. entanglement distillation or enhancing quantum teleportation. The condition relies on an upper border for the possible measurement outcomes of a hermitian operator. This operator consists of two orthogonal phase space quadratures and can therefore be measured employing standard techniques in quantum optics experiments. Unlike many other criteria on non-Gaussianity, our condition is shown to be powerful in detecting the non-Gaussian character of quantum states even when the experiment is subject to significant imperfections of the measurement devices. The second part of the thesis is based on the publications (II)-(IV) and contains the main part of the author's research which is placed in the field of few-body physics. Here, the main focus lies on universal behavior, a property which allows to apply the corresponding results to physical systems of various fields, e.g. ultracold atoms or systems of nuclear particles. At the heart of our studies is a mass-imbalanced quantum mechanical three-body system confined to one spatial dimension. In contrast to the three-dimensional case, the situation in one spatial dimension is much less studied and requires research efforts on a more fundamental level. In particular, in publication (II) we have analyzed the energy spectrum and wave functions of three-body bound states in this system. More precisely, we have proved that in the weakly-interacting limit, the three-body results for a large class of short-range two-body interactions show universal behavior and converge to those obtained for the zero-range contact interaction. The publications (III) and (IV) follow up on these results, and we have revealed how several properties of finite-range two-body interactions, which cannot be modeled by the contact interaction, affect the aforementioned universality of the three-body results. These properties correspond to relevant situations in experiments of ultracold atoms, and include interactions that are resonant but not necessarily weak (III), and interactions with anisotropic features (IV).

Published

2022