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14,954 results on '"A. Arlt"'

1. On the fluctuations of the number of atoms in the condensate

Author

Kruk, Maciej B., Kulik, Piotr, Andersen, Malthe F., Deuar, Piotr, Gajda, Mariusz, Pawłowski, Krzysztof, Witkowska, Emilia, Arlt, Jan J., and Rzążewski, Kazimierz

Subjects
Condensed Matter - Quantum Gases
Abstract

Bose-Einstein condensation represents a remarkable phase transition, characterized by the formation of a single quantum subsystem. As a result, the statistical properties of the condensate are highly unique. In the case of a Bose gas, while the mean number of condensed atoms is independent of the choice of statistical ensemble, the microcanonical, canonical, or grand canonical variances differ significantly among these ensembles. In this paper, we review the progress made over the past 30 years in studying the statistical fluctuations of Bose-Einstein condensates. Focusing primarily on the ideal Bose gas, we emphasize the inequivalence of the Gibbs statistical ensembles and examine various approaches to this problem. These approaches include explicit analytic results for primarily one-dimensional systems, methods based on recurrence relations, asymptotic results for large numbers of particles, techniques derived from laser theory, and methods involving the construction of statistical ensembles via stochastic processes, such as the Metropolis algorithm. We also discuss the less thoroughly resolved problem of the statistical behavior of weakly interacting Bose gases. In particular, we elaborate on our stochastic approach, known as the hybrid sampling method. The experimental aspect of this field has gained renewed interest, especially following groundbreaking recent measurements of condensate fluctuations. These advancements were enabled by unprecedented control over the total number of atoms in each experimental realization. Additionally, we discuss the fluctuations in photonic condensates as an illustrative example of grand canonical fluctuations. Finally, we briefly consider the future directions for research in the field of condensate statistics., Comment: 33 pages + references, review

Published
2025

2. Advancing Atom Probe Tomography of SrTiO$_3$: Measurement Methodology and Impurity Detection Limits

Author

Rybak, J. E., Arlt, J., Gault, B., and Volkert, C. A.

Subjects
Condensed Matter - Materials Science
Abstract

Strontium titanate (STO) possesses promising properties for applications in thermoelectricity, catalysis, fuel cells, and more, but its performance is highly dependent on stoichiometry and impurity levels. While atom probe tomography (APT) can provide detailed three-dimensional atomic-scale chemical information, STO specimens have been challenging to analyze due to premature specimen fracture. In this study, we show that by applying a thin metal coating to atom probe tips, STO specimens can be analyzed with nearly 100% success. Using this approach, we investigate both undoped STO and 1 at% Nb-doped STO, achieving sufficient sensitivity to detect Nb concentrations as low as 0.7 at%. This work establishes a reliable APT method for high-resolution chemical analysis of STO at the nanoscale., Comment: 33 pages, 8 figures + 7 pages supplementary material

Published
2025

3. Polarons in atomic gases and two-dimensional semiconductors

Author

Massignan, Pietro, Schmidt, Richard, Astrakharchik, Grigori E., İmamoglu, Ataç, Zwierlein, Martin, Arlt, Jan J., and Bruun, Georg M.

Subjects
Condensed Matter - Quantum Gases, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons
Abstract

In this work we provide a comprehensive review of theoretical and experimental studies of the properties of polarons formed by mobile impurities strongly interacting with quantum many-body systems. We present a unified perspective on the universal concepts and theoretical techniques used to characterize polarons in two distinct platforms, ultracold atomic gases and atomically-thin transition metal dichalcogenides, which are linked by many deep parallels. We review polarons in both fermionic and bosonic environments, highlighting their similarities and differences including the intricate interplay between few- and many-body physics. Various kinds of polarons with long-range interactions or in magnetic backgrounds are discussed, and the theoretical and experimental progress towards understanding interactions between polarons is described. We outline how polaron physics, regarded as the low density limit of quantum mixtures, provides fundamental insights regarding the phase diagram of complex condensed matter systems. Furthermore, we describe how polarons may serve as quantum sensors of many-body physics in complex environments. Our work highlights the open problems, identifies new research directions and provides a comprehensive framework for this rapidly evolving research field., Comment: Submitted to Rev. Mod. Phys. - Comments are welcome

Published
2025

4. Self-diffusion in isotropic and liquid crystalline phases of fd virus colloidal rods: a combined single particle tracking and differential dynamic microscopy study

Author

Grelet, Eric, Martinez, Vincent A., and Arlt, Jochen

Subjects
Condensed Matter - Soft Condensed Matter
Abstract

In this article, we investigate the dynamics of self-organised suspensions formed by rod-like fd virus colloids. Two methods have been employed for analysing fluorescence microscopy movies: single particle tracking (SPT) in direct space and differential dynamic microscopy (DDM) in reciprocal space. We perform a quantitative analysis on this anisotropic system with complex diffusion across different self-assembled states, ranging from dilute and semi-dilute liquids to nematic and smectic organisations. By leveraging the complementary strengths of SPT and DDM, we provide new insights in the dynamics of viral colloidal rods, such as long time diffusion coefficients in the smectic phase. We further discuss the advantages and limitations of both methods for studying the intricate dynamics of anisotropic colloidal systems.

Published
2025
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5. Gravity's role in taming the Tayler instability in red giant cores

Author

Meduri, Domenico G., Arlt, Rainer, Bonanno, Alfio, and Licciardello, Giovanni

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

The stability of toroidal magnetic fields within the interior of stars remains a significant unresolved issue in contemporary astrophysics. In this study, we combine a nonlocal linear analysis with 3D direct numerical simulations to examine the instability of toroidal fields within nonrotating, stably stratified stellar interiors in spherical geometry. Both analyses start from an equilibrium solution derived from balancing the Lorentz force with an anisotropic component of the fluid pressure, which is unstable to the (nonaxisymmetric) Tayler instability, and account for the combined effects of gravity and thermal diffusion. The numerical simulations incorporate finite magnetic resistivity and fluid viscosity while reaching a regime of highly stable stratification that has never been explored before. The linear analysis, which is global in the radial direction, shows that gravity significantly reduces the growth rate of the instability and uncovers the importance of unstable modes with low radial wavenumbers operating at low latitudes. The simulations trace the entire evolution of the instability from the linear to the nonlinear phase and strongly corroborate the findings of the linear analysis. Our results reveal that in highly stratified stellar interiors, the newly configured magnetic fields remain unstable only on the thermal diffusion timescale. Combining the linear analysis results with stellar evolution models of low-mass stars, we find that the limiting toroidal field strength for Tayler instability in red giant cores decreases with the stellar evolution. The predicted field strengths align with the ones expected from recent asteroseismic observations, suggesting that the observed fields may be remnants of a Tayler instability during the transition from the main sequence to the giant phase., Comment: 13 pages, 13 figures, to be submitted to A&A

Published
2024

7. Meta-Designing Quantum Experiments with Language Models

Author

Arlt, Sören, Duan, Haonan, Li, Felix, Xie, Sang Michael, Wu, Yuhuai, and Krenn, Mario

Subjects
Quantum Physics, Computer Science - Machine Learning
Abstract

Artificial Intelligence (AI) has the potential to significantly advance scientific discovery by finding solutions beyond human capabilities. However, these super-human solutions are often unintuitive and require considerable effort to uncover underlying principles, if possible at all. Here, we show how a code-generating language model trained on synthetic data can not only find solutions to specific problems but can create meta-solutions, which solve an entire class of problems in one shot and simultaneously offer insight into the underlying design principles. Specifically, for the design of new quantum physics experiments, our sequence-to-sequence transformer architecture generates interpretable Python code that describes experimental blueprints for a whole class of quantum systems. We discover general and previously unknown design rules for infinitely large classes of quantum states. The ability to automatically generate generalized patterns in readable computer code is a crucial step toward machines that help discover new scientific understanding -- one of the central aims of physics., Comment: 10+3 pages, 5 figures

Published
2024

8. Towards establishing best practice in the analysis of hydrogen and deuterium by atom probe tomography

Author

Gault, Baptiste, Saksena, Aparna, Sauvage, Xavier, Bagot, Paul, Aota, Leonardo S., Arlt, Jonas, Belkacemi, Lisa T., Boll, Torben, Chen, Yi-Sheng, Daly, Luke, Djukic, Milos B., Douglas, James O., Duarte, Maria J., Felfer, Peter J., Forbes, Richard G., Fu, Jing, Gardner, Hazel M., Gemma, Ryota, Gerstl, Stephan S. A., Gong, Yilun, Hachet, Guillaume, Jakob, Severin, Jenkins, Benjamin M., Jones, Megan E., Khanchandani, Heena, Kontis, Paraskevas, Krämer, Mathias, Kühbach, Markus, Marceau, Ross K. W., Mayweg, David, Moore, Katie L., Nallathambi, Varatharaja, Ott, Benedict C., Poplawsky, Jonathan D, Prosa, Ty, Pundt, Astrid, Saha, Mainak, Schwarz, Tim M., Shang, Yuanyuan, Shen, Xiao, Vrellou, Maria, Yu, Yuan, Zhao, Yujun, Zhao, Huan, and Zou, Bowen

Subjects
Condensed Matter - Materials Science
Abstract

As hydrogen is touted as a key player in the decarbonization of modern society, it is critical to enable quantitative H analysis at high spatial resolution, if possible at the atomic scale. Indeed, H has a known deleterious impact on the mechanical properties (strength, ductility, toughness) of most materials that can hinder their use as part of the infrastructure of a hydrogen-based economy. Enabling H mapping, including local hydrogen concentration analyses at specific microstructural features, is essential for understanding the multiple ways that H affect the properties of materials, including for instance embrittlement mechanisms and their synergies, but also spatial mapping and quantification of hydrogen isotopes is essential to accurately predict tritium inventory of future fusion power plants, ensuring their safe and efficient operation for example. Atom probe tomography (APT) has the intrinsic capabilities for detecting hydrogen (H), and deuterium (D), and in principle the capacity for performing quantitative mapping of H within a material's microstructure. Yet the accuracy and precision of H analysis by APT remain affected by the influence of residual hydrogen from the ultra-high vacuum chamber that can obscure the signal of H from within the material, along with a complex field evaporation behavior. The present article reports the essence of discussions at a focused workshop held at the Max-Planck Institute for Sustainable Materials in April 2024. The workshop was organized to pave the way to establishing best practices in reporting APT data for the analysis of H. We first summarize the key aspects of the intricacies of H analysis by APT and propose a path for better reporting of the relevant data to support interpretation of APT-based H analysis in materials.

Published
2024

9. Dismantling Common Internet Services for Ad-Malware Detection

Author

Nettersheim, Florian, Arlt, Stephan, and Rademacher, Michael

Subjects
Computer Science - Networking and Internet Architecture, Computer Science - Cryptography and Security, C.2.4
Abstract

Online advertising represents a main instrument for publishers to fund content on the World Wide Web. Unfortunately, a significant number of online advertisements often accommodates potentially malicious content, such as cryptojacking hidden in web banners - even on reputable websites. In order to protect Internet users from such online threats, the thorough detection of ad-malware campaigns plays a crucial role for a safe Web. Today, common Internet services like VirusTotal can label suspicious content based on feedback from contributors and from the entire Web community. However, it is open to which extent ad-malware is actually taken into account and whether the results of these services are consistent. In this pre-study, we evaluate who defines ad-malware on the Internet. In a first step, we crawl a vast set of websites and fetch all HTTP requests (particularly to online advertisements) within these websites. Then we query these requests both against popular filtered DNS providers and VirusTotal. The idea is to validate, how much content is labeled as a potential threat. The results show that up to 0.47% of the domains found during crawling are labeled as suspicious by DNS providers and up to 8.8% by VirusTotal. Moreover, only about 0.7% to 3.2% of these domains are categorized as ad-malware. The overall responses from the used Internet services paint a divergent picture: All considered services have different understandings to the definition of suspicious content. Thus, we outline potential research efforts to the automated detection of ad-malware. We further bring up the open question of a common definition of ad-malware to the Web community., Comment: 4 pages, 4 figures

Published
2024

12. Atom Number Fluctuations in Bose Gases -- Statistical analysis of parameter estimation

Author

Vibel, Toke, Christensen, Mikkel Berg, Andersen, Rasmus Malthe Fiil, Stokholm, Laurits Nikolaj, Pawłowski, Krzysztof, Rzążewski, Kazimierz, Kristensen, Mick Althoff, and Arlt, Jan Joachim

Subjects
Condensed Matter - Quantum Gases, Physics - Atomic Physics
Abstract

The investigation of the fluctuations in interacting quantum systems at finite temperatures showcases the ongoing challenges in understanding complex quantum systems. Recently, atom number fluctuations in weakly interacting Bose-Einstein condensates were observed, motivating an investigation of the thermal component of partially condensed Bose gases. Here, we present a combined analysis of both components, revealing the presence of fluctuations in the thermal component. This analysis includes a comprehensive statistical evaluation of uncertainties in the preparation and parameter estimation of partially condensed Bose gases. Using Monte Carlo simulations of optical density profiles, we estimate the noise contributions to the atom number and temperature estimation of the condensed and thermal cloud, which is generally applicable in the field of ultracold atoms. Furthermore, we investigate the specific noise contributions in the analysis of atom number fluctuations and show that preparation noise in the total atom number leads to an important technical noise contribution. Subtracting all known noise contributions from the variance of the atom number in the BEC and thermal component allows us to improve the estimate of the fundamental peak fluctuations.

Published
2024
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13. Virtual Reality for Understanding Artificial-Intelligence-driven Scientific Discovery with an Application in Quantum Optics

Author

Schmidt, Philipp, Arlt, Sören, Ruiz-Gonzalez, Carlos, Gu, Xuemei, Rodríguez, Carla, and Krenn, Mario

Subjects
Computer Science - Human-Computer Interaction, Computer Science - Artificial Intelligence, Computer Science - Graphics, Quantum Physics
Abstract

Generative Artificial Intelligence (AI) models can propose solutions to scientific problems beyond human capability. To truly make conceptual contributions, researchers need to be capable of understanding the AI-generated structures and extracting the underlying concepts and ideas. When algorithms provide little explanatory reasoning alongside the output, scientists have to reverse-engineer the fundamental insights behind proposals based solely on examples. This task can be challenging as the output is often highly complex and thus not immediately accessible to humans. In this work we show how transferring part of the analysis process into an immersive Virtual Reality (VR) environment can assist researchers in developing an understanding of AI-generated solutions. We demonstrate the usefulness of VR in finding interpretable configurations of abstract graphs, representing Quantum Optics experiments. Thereby, we can manually discover new generalizations of AI-discoveries as well as new understanding in experimental quantum optics. Furthermore, it allows us to customize the search space in an informed way - as a human-in-the-loop - to achieve significantly faster subsequent discovery iterations. As concrete examples, with this technology, we discover a new resource-efficient 3-dimensional entanglement swapping scheme, as well as a 3-dimensional 4-particle Greenberger-Horne-Zeilinger-state analyzer. Our results show the potential of VR for increasing a human researcher's ability to derive knowledge from graph-based generative AI that, which is a common abstract data representation used in diverse fields of science., Comment: 12 pages, 6 figures, comments welcome

Published
2024
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14. Spatial calibration of high-density absorption imaging

Author

Vibel, Toke, Christensen, Mikkel Berg, Kristensen, Mick Althoff, Thuesen, Jeppe Juhl, Stokholm, Laurits Nikolaj, Weidner, Carrie Ann, and Arlt, Jan Joachim

Subjects
Physics - Atomic Physics, Condensed Matter - Quantum Gases
Abstract

The accurate determination of atom numbers is an ubiquitous problem in the field of ultracold atoms. For modest atom numbers, absolute calibration techniques are available, however, for large numbers and high densities, the available techniques neglect many-body scattering processes. Here, a spatial calibration technique for time-of-flight absorption images of ultracold atomic clouds is presented. The calibration is obtained from radially averaged absorption images and we provide a practical guide to the calibration process. It is shown that the calibration coefficient scales linearly with optical density and depends on the absorbed photon number for the experimental conditions explored here. This allows for the direct inclusion of a spatially dependent calibration in the image analysis. For typical ultracold atom clouds the spatial calibration technique leads to corrections in the detected atom number up to $\approx\! 12\,\%$ and temperature up to $\approx \!14\,\%$ in comparison to previous calibration techniques. The technique presented here addresses a major difficulty in absorption imaging of ultracold atomic clouds and prompts further theoretical work to understand the scattering processes in ultracold dense clouds of atoms for accurate atom number calibration.

Published
2024
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15. Student Self-Efficacy: Learning Math with Visual/Kinesthetic Tools

Author

Samantha Sylvestri and Lauren Arlt

Abstract

For years, educators have been using "foldables" as a visual and/or kinesthetic approach to note taking within elementary school classrooms. The purpose of the study is to determine to what extent these foldables have on students' self-efficacy of grade level math concepts. We previously found that there were learning gaps in students' understanding of math concepts with the sole use of the school's mathematical adopted program(s). Additionally, our students had not been exposed to note taking due to the recent pandemic. Therefore, the practice of note taking through a visual or graphic with kinesthetic integration allows for more note-taking opportunities for our students. We hope the use of foldables will reach more kinesthetic learners through a hands-on approach to learning. We would like to use the foldables to not only increase the students' individual mathematical skills, but also to build their confidence while doing math. Building a love and confidence for math at an early age can really help develop a positive mathematical life in a young child. So many adults cringe at the sound of the word "math" and we aim to change that feeling for our students' future. If a student has a positive view about math and is confident while doing math, they will show growth throughout the year in this particular area (Akin & Kurbanoglu, 2011). Utilizing foldables as a tool to strengthen and develop mathematical skills will allow students the opportunity to engage in a hands-on approach and conceptually learn the strategies being taught.

Published
2023

16. Quantum beat spectroscopy of repulsive Bose polarons

Author

Morgen, A. M., Balling, S. S., Nielsen, K. Knakkergaard, Pohl, T., Bruun, G. M., and Arlt, J. J.

Subjects
Condensed Matter - Quantum Gases
Abstract

The physics of impurities in a bosonic quantum environment is a paradigmatic and challenging many-body problem that remains to be understood in its full complexity. Here, this problem is investigated for impurities with strong repulsive interactions based on Ramsey interferometry in a quantum degenerate gas of 39K atoms. We observe an oscillatory signal that is consistent with a quantum beat between two co-existing coherent quasiparticle states: the attractive and repulsive polarons. The interferometric signal allows us to extract the polaron energies for a wide range of interaction strengths, complimenting earlier spectroscopic measurements. We furthermore identify several dynamical regimes towards the formation of the Bose polaron in good agreement with theory. Our results improve the understanding of quantum impurities interacting strongly with a bosonic environment, and demonstrate how quasiparticles as well as short-lived non-equilibrium many-body states can be probed using Ramsey interferometry.

Published
2023

17. XLuminA: An Auto-differentiating Discovery Framework for Super-Resolution Microscopy

Author

Rodríguez, Carla, Arlt, Sören, Möckl, Leonhard, and Krenn, Mario

Subjects
Physics - Optics
Abstract

Driven by human ingenuity and creativity, the discovery of super-resolution techniques, which circumvent the classical diffraction limit of light, represent a leap in optical microscopy. However, the vast space encompassing all possible experimental configurations suggests that some powerful concepts and techniques might have not been discovered yet, and might never be with a human-driven direct design approach. Thus, AI-based exploration techniques could provide enormous benefit, by exploring this space in a fast, unbiased way. We introduce XLuminA, an open-source computational framework developed using JAX, which offers enhanced computational speed enabled by its accelerated linear algebra compiler (XLA), just-in-time compilation, and its seamlessly integrated automatic vectorization, auto-differentiation capabilities and GPU compatibility. Remarkably, XLuminA demonstrates a speed-up of 4 orders of magnitude compared to well-established numerical optimization methods. We showcase XLuminA's potential by re-discovering three foundational experiments in advanced microscopy. Ultimately, XLuminA identified a novel experimental blueprint featuring sub-diffraction imaging capabilities. This work constitutes an important step in AI-driven scientific discovery of new concepts in optics and advanced microscopy., Comment: 29 pages, 15 figures. GitHub repo available!

Published
2023
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18. Gamification of Life and the Gaming Society: The Ludic Century. SpringerBriefs in Education

Author

Fabian Arlt, Hans-Jürgen Arlt, Fabian Arlt, and Hans-Jürgen Arlt

Abstract

This interesting book discusses why, as an activity, topic and metaphor, play and game have become an integral part of modern life. Empirically exemplary and theoretically grounded, this book discusses the developments and expansions in gaming, from easily accessible casual games to the galaxy-spanning gaming worlds of Massively Multiplayer Online Role-Playing Games (MMORPGs). It shows how gaming has become a focal point of the entertainment industry, marked by boundless professionalization and monetization, especially in the realm of sports, and how games become global platforms for social networks, where players from all over the world meet in digital sandboxes. The combination of the virtual and the ludic creates hyperreal spaces in which people try out new forms of interaction, cooperation, and even brainstorming. The authors ask if this behavior has become the new way of life and the new normal, and if this heralds the ludic century. They take readers on a journey to understand the dynamics of today's gaming society, and base their observations and analyses on an original theory of play, which, in contrast to social normalcy, revolves around the allure and threats of the unexpected. This book is of interest to students and researchers of social science and communication studies, especially those working on the interface of AI and society.

Published
2023
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19. Deep Quantum Graph Dreaming: Deciphering Neural Network Insights into Quantum Experiments

Author

Jaouni, Tareq, Arlt, Sören, Ruiz-Gonzalez, Carlos, Karimi, Ebrahim, Gu, Xuemei, and Krenn, Mario

Subjects
Quantum Physics, Computer Science - Artificial Intelligence, Computer Science - Machine Learning
Abstract

Despite their promise to facilitate new scientific discoveries, the opaqueness of neural networks presents a challenge in interpreting the logic behind their findings. Here, we use a eXplainable-AI (XAI) technique called $inception$ or $deep$ $dreaming$, which has been invented in machine learning for computer vision. We use this technique to explore what neural networks learn about quantum optics experiments. Our story begins by training deep neural networks on the properties of quantum systems. Once trained, we "invert" the neural network -- effectively asking how it imagines a quantum system with a specific property, and how it would continuously modify the quantum system to change a property. We find that the network can shift the initial distribution of properties of the quantum system, and we can conceptualize the learned strategies of the neural network. Interestingly, we find that, in the first layers, the neural network identifies simple properties, while in the deeper ones, it can identify complex quantum structures and even quantum entanglement. This is in reminiscence of long-understood properties known in computer vision, which we now identify in a complex natural science task. Our approach could be useful in a more interpretable way to develop new advanced AI-based scientific discovery techniques in quantum physics., Comment: Modified Figure 2. Fixed minor typos

Published
2023
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20. Experimental Solutions to the High-Dimensional Mean King's Problem

Author

Jaouni, Tareq, Gao, Xiaoqin, Arlt, Sören, Krenn, Mario, and Karimi, Ebrahim

Subjects
Quantum Physics
Abstract

In 1987, Vaidman, Aharanov, and Albert put forward a puzzle called the Mean King's Problem (MKP) that can be solved only by harnessing quantum entanglement. Prime-powered solutions to the problem have been shown to exist, but they have not yet been experimentally realized for any dimension beyond two. We propose a general first-of-its-kind experimental scheme for solving the MKP in prime dimensions ($D$). Our search is guided by the digital discovery framework PyTheus, which finds highly interpretable graph-based representations of quantum optical experimental setups; using it, we find specific solutions and generalize to higher dimensions through human insight. As proof of principle, we present a detailed investigation of our solution for the three-, five-, and seven-dimensional cases. We obtain maximum success probabilities of $72.8 \%$, $45.8\%$, and $34.8 \%$, respectively. We, therefore, posit that our computer-inspired scheme yields solutions that exceed the classical probability ($1/D$) twofold, demonstrating its promise for experimental implementation., Comment: Fixed unusual visual aberration in Figure 2, and moved Acknowledgements section

Published
2023
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25. Fock State Sampling Method -- Characteristic temperature of maximal fluctuations for interacting bosons in box potentials

Author

Kruk, M. B., Vibel, T., Arlt, J., Kulik, P., Pawłowski, K., and Rzążewski, K.

Subjects
Quantum Physics, Condensed Matter - Statistical Mechanics
Abstract

We study the statistical properties of a gas of interacting bosons trapped in a box potential in two and three dimensions. Our primary focus is the characteristic temperature $\tchar$, i.e. the temperature at which the fluctuations of the number of condensed atoms (or, in 2D, the number of motionless atoms) is maximal. Using the Fock State Sampling method, we show that $\tchar$ increases due to interaction. In 3D, this temperature converges to the critical temperature in the thermodynamic limit. In 2D we show the general applicability of the method by obtaining a generalized dependence of the characteristic temperature on the interaction strength. Finally, we discuss the experimental conditions necessary for the verification of our theoretical predictions., Comment: This article belongs to the special issue of Acta Physica Polonica A printed in honor of Professor Iwo Bialynicki-Birula on the occasion of his 90th birthday (Ed. Tomasz Sowinski, DOI:10.12693/APhysPolA.143.S0)

Published
2023
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26. Sizing multimodal suspensions with differential dynamic microscopy

Author

Bradley, Joe J, Martinez, Vincent A, Arlt, Jochen, Royer, John R, and Poon, Wilson C K

Subjects
Condensed Matter - Soft Condensed Matter
Abstract

Differential dynamic microscopy (DDM) can be used to extract mean particle size from videos of suspensions. However, many suspensions have multimodal particle size distributions (PSDs), for which this is not a sufficient description. After clarifying how different particle sizes contribute to the signal in DDM, we show that standard DDM analysis can extract the mean sizes of two populations in a bimodal suspension given prior knowledge of the sample's bimodality. Further, the use of the CONTIN algorithm obviates the need for such prior knowledge. Finally, we show that by selectively analysing portions of the DDM images, we can size a trimodal suspension where the large particles would otherwise dominate the signal, again without prior knowledge of the trimodality., Comment: Main Body: 10 pages, 8 figures. Appendix: 5 pages, 6 figures. Manuscript accepted at Soft Matter with open access licence; for version of record see https://doi.org/10.1039/D3SM00593C. Relevant data available at https://doi.org/10.7488/ds/3851

Published
2023
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27. Sunspot positions from observations by Flaugergues in the Dalton Minimum

Author

Illarionov, Egor and Arlt, Rainer

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

French astronomer Honor\'e Flaugergues compiled astronomical observations in a series of hand-written notebooks for 1782$\unicode{x2013}$1830, which are preserved at Paris Observatory. We reviewed these manuscripts and encoded the records that contain sunspot measurements into a numerical table for further analysis. All measurements are timings and we found three types of measurements allowing the reconstruction of heliographic coordinates. In the first case, the Sun and sunspots cross vertical and horizontal wires, in the second case, one vertical and two mirror-symmetric oblique wires, and in the third case, a rhombus-shaped set of wires. Additionally, timings of two solar eclipses also provided a few sunspot coordinates. As a result, we present the time--latitude (butterfly) diagram of the reconstructed sunspot coordinates, which covers the period of the Dalton Minimum and confirms consistency with those of Derfflinger and Prantner. We identify four solar cycles in this diagram and discuss the observed peculiarities as well as the data reliability.

Published
2023
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28. Re-calibration of the Sunspot Number: Status Report

Author

Clette, F., Lefèvre, L., Chatzistergos, T., Hayakawa, H., Carrasco, V. M., Arlt, R., Cliver, E. W., de Wit, T. Dudok, Friedli, T., Karachik, N., Kopp, G., Lockwood, M., Mathieu, S., Muñoz-Jaramillo, A., Owens, M., Pesnell, D., Pevtsov, A., Svalgaard, L., Usoskin, I. G., van Driel-Gesztelyi, L., and Vaquero, J. M.

Subjects
Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics
Abstract

We report progress on the ongoing recalibration of the Wolf sunspot number (SN) and Group sunspot number (GN) following the release of version 2.0 of SN in 2015. This report constitutes both an update of the efforts reported in the 2016 Topical Issue of Solar Physics and a summary of work by the International Space Science Institute (ISSI) International Team formed in 2017 to develop optimal SN and GN re-construction methods while continuing to expand the historical sunspot number database. Significant progress has been made on the database side while more work is needed to bring the various proposed SN and (primarily) GN reconstruction methods closer to maturity, after which the new reconstructions (or combinations thereof) can be compared with (a) ``benchmark'' expectations for any normalization scheme (e.g., a general increase in observer normalization factors going back in time), and (b) independent proxy data series such as F10.7 and the daily range of variations of Earth's undisturbed magnetic field. New versions of the underlying databases for SN and GN will shortly become available for years through 2022 and we anticipate the release of next versions of these two time series in 2024., Comment: 21 figures, 4 tables. To be published in Solar Physics

Published
2023
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41. Characterization and Control of the Run-and-Tumble Dynamics of {\it Escherichia Coli}

Author

Kurzthaler, Christina, Zhao, Yongfeng, Zhou, Nan, Schwarz-Linek, Jana, Devailly, Clemence, Arlt, Jochen, Huang, Jian-Dong, Poon, Wilson C. K., Franosch, Thomas, Tailleur, Julien, and Martinez, Vincent A.

Subjects
Condensed Matter - Soft Condensed Matter, Physics - Biological Physics
Abstract

We characterize the full spatiotemporal gait of populations of swimming {\it Escherichia coli} using renewal processes to analyze the measurements of intermediate scattering functions. This allows us to demonstrate quantitatively how the persistence length of an engineered strain can be controlled by a chemical inducer and to report a controlled transition from perpetual tumbling to smooth swimming. For wild-type {\it E.~coli}, we measure simultaneously the microscopic motility parameters and the large-scale effective diffusivity, hence quantitatively bridging for the first time small-scale directed swimming and macroscopic diffusion.

Published
2022
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42. Quantitative characterization of run-and-tumble statistics in bulk bacterial suspensions

Author

Zhao, Yongfeng, Kurzthaler, Christina, Zhou, Nan, Schwarz-Linek, Jana, Devailly, Clemence, Arlt, Jochen, Huang, Jian-Dong, Poon, Wilson C. K., Franosch, Thomas, Martinez, Vincent A., and Tailleur, Julien

Subjects
Physics - Biological Physics, Condensed Matter - Soft Condensed Matter
Abstract

We introduce a numerical method to extract the parameters of run-and-tumble dynamics from experimental measurements of the intermediate scattering function. We show that proceeding in Laplace space is unpractical and employ instead renewal processes to work directly in real time. We first validate our approach against data produced using agent-based simulations. This allows us to identify the length and time scales required for an accurate measurement of the motility parameters, including tumbling frequency and swim speed. We compare different models for the run-and-tumble dynamics by accounting for speed variability at the single-cell and population level, respectively. Finally, we apply our approach to experimental data on wild-type Escherichia coli obtained using differential dynamic microscopy., Comment: 10 pages, 5 figures

Published
2022
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43. Laser-induced Coulomb Explosion Imaging of Alkali Dimers on Helium Nanodroplets

Author

Kristensen, Henrik H., Kranabetter, Lorenz, Schouder, Constant A., Arlt, Jacqueline, Jensen, Frank, and Stapelfeldt, Henrik

Subjects
Physics - Atomic Physics, Physics - Atomic and Molecular Clusters
Abstract

Alkali dimers, $\mathrm{Ak}_2$, residing on the surface of He nanodroplets are doubly ionized due to multiphoton absorption from an intense, 50-fs laser pulse leading to fragmentation into a pair of alkali cations. Based on the measured kinetic energy distributions, $P(E_{\text{kin}})$, of the $\mathrm{Ak}^+$ fragment ions, we retrieve the distribution of internuclear distances, $P(R)$, via the $\mathrm{Ak}_2^{2+}$ potential curve. Results are obtained for $\mathrm{{Na}_2}$, $\mathrm{K}_2$, $\mathrm{Rb}_2$, and $\mathrm{Cs}_2$ in both the 1 $^1\Sigma_{g}^+$ ground state and in the lowest-lying triplet state 1 $^3\Sigma_{u}^+$, and for $\mathrm{Li}_2$ in the 1 $^3\Sigma_{u}^+$ state. For $\mathrm{Li}_2$, $\mathrm{K}_2$, and $\mathrm{Rb}_2$, the center of the measured $P(R)$'s is close to the center of the wave function, $\Psi(R)$, of the vibrational ground state in the 1 $^1\Sigma_{g}^+$ and 1 $^3\Sigma_{u}^+$ states, whereas for $\mathrm{{Na}_2}$ and $\mathrm{{Cs}_2}$ small shifts are observed. For all the $\mathrm{{Ak}_2}$, the width of the measured $P(R)$ is broader than $|\Psi(R)|^2$ by a factor of 2-4. We discuss that resonance effects in the multiphoton ionization and interaction of the $\mathrm{Ak}^+$ ion with the He droplet give rise to the observed deviations of $P(R)$ from $|\Psi(R)|^2$. Despite these deviations, we deem that timed Coulomb explosion will allow imaging of vibrational wave packets in alkali dimers on He droplets surfaces., Comment: 10 pages, 6 figures

Published
2022
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44. Digital Discovery of a Scientific Concept at the Core of Experimental Quantum Optics

Author

Arlt, Sören, Ruiz-Gonzalez, Carlos, and Krenn, Mario

Subjects
Quantum Physics
Abstract

Entanglement is a crucial resource for quantum technologies ranging from quantum communication to quantum-enhanced measurements and computation. Finding experimental setups for these tasks is a conceptual challenge for human scientists due to the counterintuitive behavior of multiparticle interference and the enormously large combinatorial search space. Recently, new possibilities have been opened by artificial discovery where artificial intelligence proposes experimental setups for the creation and manipulation of high-dimensional multi-particle entanglement. While digitally discovered experiments go beyond what has been conceived by human experts, a crucial goal is to understand the underlying concepts which enable these new useful experimental blueprints. Here, we present Halo (Hyperedge Assembly by Linear Optics), a new form of multiphoton quantum interference with surprising properties. Halos were used by our digital discovery framework to solve previously open questions. We -- the human part of this collaboration -- were then able to conceptualize the idea behind the computer discovery and describe them in terms of effective probabilistic multi-photon emitters. We then demonstrate its usefulness as a core of new experiments for highly entangled states, communication in quantum networks, and photonic quantum gates. Our manuscript has two conclusions. First, we introduce and explain the physics of a new practically useful multi-photon interference phenomenon that can readily be realized in advanced setups such as integrated photonic circuits. Second, our manuscript demonstrates how artificial intelligence can act as a source of inspiration for the scientific discoveries of new actionable concepts in physics., Comment: 6 pages, 6 figures, comments welcome

Published
2022

45. Digital Discovery of 100 diverse Quantum Experiments with PyTheus

Author

Ruiz-Gonzalez, Carlos, Arlt, Sören, Petermann, Jan, Sayyad, Sharareh, Jaouni, Tareq, Karimi, Ebrahim, Tischler, Nora, Gu, Xuemei, and Krenn, Mario

Subjects
Quantum Physics
Abstract

Photons are the physical system of choice for performing experimental tests of the foundations of quantum mechanics. Furthermore, photonic quantum technology is a main player in the second quantum revolution, promising the development of better sensors, secure communications, and quantum-enhanced computation. These endeavors require generating specific quantum states or efficiently performing quantum tasks. The design of the corresponding optical experiments was historically powered by human creativity but is recently being automated with advanced computer algorithms and artificial intelligence. While several computer-designed experiments have been experimentally realized, this approach has not yet been widely adopted by the broader photonic quantum optics community. The main roadblocks consist of most systems being closed-source, inefficient, or targeted to very specific use-cases that are difficult to generalize. Here, we overcome these problems with a highly-efficient, open-source digital discovery framework PyTheus, which can employ a wide range of experimental devices from modern quantum labs to solve various tasks. This includes the discovery of highly entangled quantum states, quantum measurement schemes, quantum communication protocols, multi-particle quantum gates, as well as the optimization of continuous and discrete properties of quantum experiments or quantum states. PyTheus produces interpretable designs for complex experimental problems which human researchers can often readily conceptualize. PyTheus is an example of a powerful framework that can lead to scientific discoveries -- one of the core goals of artificial intelligence in science. We hope it will help accelerate the development of quantum optics and provide new ideas in quantum hardware and technology., Comment: 44 pages, 62 figures, comments welcome!

Published
2022
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