Your search keyword '"Daniel Hengstler"' showing total 9 results

1. Towards Precision Muonic X-ray Measurements of Charge Radii of Light Nuclei

Author

Ben Ohayon, Andreas Abeln, Silvia Bara, Thomas Elias Cocolios, Ofir Eizenberg, Andreas Fleischmann, Loredana Gastaldo, César Godinho, Michael Heines, Daniel Hengstler, Guillaume Hupin, Paul Indelicato, Klaus Kirch, Andreas Knecht, Daniel Kreuzberger, Jorge Machado, Petr Navratil, Nancy Paul, Randolf Pohl, Daniel Unger, Stergiani Marina Vogiatzi, Katharina von Schoeler, and Frederik Wauters

Subjects

muonic atoms, charge radius, X-ray, metallic magnetic calorimeter (MMC), nuclear structure, bound-state quantum electrodynamics (QED), Physics, QC1-999

Abstract

We, the QUARTET Collaboration, propose an experiment to measure the nuclear charge radii of light elements with up to 20 times higher accuracy. These are essential both for understanding nuclear physics at low energies, and for experimental and theoretical applications in simple atomic systems. Such comparisons advance the understanding of bound-state quantum electrodynamics and are useful for searching for new physics beyond the Standard Model. The energy levels of muonic atoms are highly susceptible to nuclear structure, especially to the mean square charge radius. The radii of the lightest nuclei (with the atomic number, Z=1,2) have been determined with high accuracy using laser spectroscopy in muonic atoms, while those of medium mass and above were determined using X-ray spectroscopy with semiconductor detectors. In this communication, we present a new experiment, aiming to obtain precision measurements of the radii of light nuclei 3≤Z≤10 using single-photon energy measurements with cryogenic microcalorimeters; a quantum-sensing technology capable of high efficiency with outstanding resolution for low-energy X-rays.

Published

2024

2. Towards an Intrinsic Doppler Correction for X-ray Spectroscopy of Stored Ions at CRYRING@ESR

Author

Felix Martin Kröger, Günter Weber, Steffen Allgeier, Zoran Andelkovic, Sonja Bernitt, Alexander Borovik, Louis Duval, Andreas Fleischmann, Oliver Forstner, Marvin Friedrich, Jan Glorius, Alexandre Gumberidze, Christoph Hahn, Frank Herfurth, Daniel Hengstler, Marc Oliver Herdrich, Pierre-Michel Hillenbrand, Anton Kalinin, Markus Kiffer, Maximilian Kubullek, Patricia Kuntz, Michael Lestinsky, Bastian Löher, Esther Babette Menz, Tobias Over, Nikolaos Petridis, Philip Pfäfflein, Stefan Ringleb, Ragandeep Singh Sidhu, Uwe Spillmann, Sergiy Trotsenko, Andrzej Warczak, Binghui Zhu, Christian Enss, and Thomas Stöhlker

Subjects

precision X-ray spectroscopy, highly charged heavy ions, ion storage rings, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

We report on a new experimental approach for the Doppler correction of X-rays emitted by heavy ions, using novel metallic magnetic calorimeter detectors which uniquely combine a high spectral resolution with a broad bandwidth acceptance. The measurement was carried out at the electron cooler of CRYRING@ESR at GSI, Darmstadt, Germany. The X-ray emission associated with the radiative recombination of cooler electrons and stored hydrogen-like uranium ions was investigated using two novel microcalorimeter detectors positioned under 0∘ and 180∘ with respect to the ion beam axis. This new experimental setup allowed the investigation of the region of the N, M → L transitions in helium-like uranium with a spectral resolution unmatched by previous studies using conventional semiconductor X-ray detectors. When assuming that the rest-frame energy of at least a few of the recorded transitions is well-known from theory or experiments, a precise measurement of the Doppler shifted line positions in the laboratory system can be used to determine the ion beam velocity using only spectral information. The spectral resolution achievable with microcalorimeter detectors should, for the first time, allow intrinsic Doppler correction to be performed for the precision X-ray spectroscopy of stored heavy ions. A comparison with data from a previous experiment at the ESR electron cooler, as well as the conventional method of conducting Doppler correction using electron cooler parameters, will be discussed.

Published

2023

3. X-ray Spectroscopy Based on Micro-Calorimeters at Internal Targets of Storage Rings

Author

Marc Oliver Herdrich, Daniel Hengstler, Andreas Fleischmann, Christian Enss, Alexandre Gumberidze, Pierre-Michel Hillenbrand, Paul Indelicato, Stephan Fritzsche, and Thomas Stöhlker

Subjects

atomic physics, metallic-magnetic calorimeters, high-precision X-ray spectroscopy, 2s Lamb shift, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

With metallic-magnetic calorimeters (MMCs), promising detectors for high-precision X-ray spectrometry in atomic and fundamental physics experiments are available. In this work, we present a pilot experiment based on a maXs-30 type MMC-spectrometer for recording X-rays emitted in collisions of lithium-like uranium ions with a molecular nitrogen gas jet in the internal target of the ESR storage ring of the GSI. Sample spectra have been measured, and a multitude of X-ray transitions have been unambiguously identified. As a first test and for comparison with data recorded at an EBIT, the 2s Lamb shift in lithium-like uranium was estimated.

Published

2023

4. Exploitation of the Timing Capabilities of Metallic Magnetic Calorimeters for a Coincidence Measurement Scheme

Author

Philip Pfäfflein, Günter Weber, Steffen Allgeier, Sonja Bernitt, Andreas Fleischmann, Marvin Friedrich, Christoph Hahn, Daniel Hengstler, Marc Oliver Herdrich, Anton Kalinin, Felix Martin Kröger, Patricia Kuntz, Michael Lestinsky, Bastian Löher, Esther Babette Menz, Uwe Spillmann, Binghui Zhu, Christian Enss, and Thomas Stöhlker

Subjects

timing, coincidence, metallic magnetic calorimeter, microcalorimeter, precision X-ray spectroscopy, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

In this report, we compare two filter algorithms for extracting timing information using novel metallic magnetic calorimeter detectors, applied to the precision X-ray spectroscopy of highly charged ions in a storage ring. Accurate timing information is crucial when exploiting coincidence conditions for background suppression to obtain clean spectra. For X-rays emitted by charge-changing interactions between ions and a target, this is a well-established technique when relying on conventional semiconductor detectors that offer a good temporal resolution. However, until recently, such a coincidence scheme had never been realized with metallic magnetic calorimeters, which typically feature much longer signal rise times. In this report, we present optimized timing filter algorithms for this type of detector. Their application to experimental data recently obtained at the electron cooler of CRYRING@ESR at GSI, Darmstadt is discussed.

Published

2022

5. Microcalorimeters for X-Ray Spectroscopy of Highly Charged Ions at Storage Rings

Author

Saskia Kraft-Bermuth, Daniel Hengstler, Peter Egelhof, Christian Enss, Andreas Fleischmann, Michael Keller, and Thomas Stöhlker

Subjects

storage rings, high-precision x-ray spectroscopy, highly charged ions, microcalorimeters, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

X-ray spectroscopy of highly charged heavy ions is an important tool for the investigation of many topics in atomic physics. Such highly charged ions, in particular hydrogen-like uranium, are investigated at heavy ion storage rings, where high charge states can be produced in large quantities, stored for long times and cooled to low momentum spread of the ion beam. One prominent example is the determination of the 1s Lamb Shift in hydrogen-like heavy ions, which has been investigated at the Experimental Storage Ring (ESR) at the GSI Helmholtz Centre for Heavy Ion Research. Due to the large electron binding energies, the energies of the corresponding photon transitions are located in the X-ray regime. To determine the transition energies with high accuracy, highly resolving X-ray spectrometers are needed. One concept of such spectrometers is the concept of microcalorimeters, which, in contrast to semiconductor detectors, uses the detection of heat rather than charge to detect energy. Such detectors have been developed and successfully applied in experiments at the ESR. For experiments at the Facility for Antiproton and Ion Research (FAIR), the Stored Particles and Atoms Collaboration (SPARC) pursues the development of new microcalorimeter concepts and larger detector arrays. Next to fundamental investigations on quantum electrodynamics such as the 1s Lamb Shift or electron⁻electron interactions in two- and three-electron systems, X-ray spectroscopy may be extended towards nuclear physics investigations like the determination of nuclear charge radii.

Published

2018

6. Numerical Calculation of the Thermodynamic Properties of Silver Erbium Alloys for Use in Metallic Magnetic Calorimeters

Author

Matthew Herbst, Arnulf Barth, Andreas Fleischmann, Loredana Gastaldo, Daniel Hengstler, Neven Kovac, Federica Mantegazzini, Andreas Reifenberger, and Christian Enss

Subjects

General Materials Science, Condensed Matter Physics, Atomic and Molecular Physics, and Optics

Abstract

Using dilute silver erbium alloys as a paramagnetic temperature sensor in metallic magnetic calorimeters (MMCs) has the advantage of the host material not having a nuclear quadrupole moment, in contrast to the alternative of using gold erbium alloys. We present numerical calculations of the specific heat and magnetization of Ag:Er, which are necessary for designing and optimizing MMCs using this type of alloy as sensor material. The parameter ranges we consider are temperatures between $$1\,{\text {{mK}}}$$ 1 mK and $$1\,{\text {{K}}}$$ 1 K , external magnetic fields of up to $$20\,{\text {{mT}}}$$ 20 mT , and erbium concentrations of up to $$2000\,{\text {{ppm}}}$$ 2000 ppm . The system is dominated by an interplay of crystal field effects, Zeeman splitting, and the RKKY interaction between erbium ions, with certain specific constellations of erbium ions having noticeable effects on the specific heat. Increasing the external magnetic field or assuming a decreased strength of the RKKY interaction leads to a higher magnetization and a narrowing of the main Schottky peak, while changes in the erbium concentration can be well described by parameter scaling.

Published

2022

7. The Electron Capture in $^{163}$ Ho Experiment - a Short Update

Author

Neven Kovac, Felix Ahrens, Arnulf Barth, Sebastian Berndt, Klaus Blaum, Martin Brass, Erik Bruer, Menno Door, Holger Dorrer, Christoph Düllmann, Sergey Maksimovich Eliseev, Christian Enss, Pavel Filianin, Andreas Fleischmann, Loredana Gastaldo, Alexander Göggelmann, Markus Griedel, Robert Hammann, Maurits Haverkort, Daniel Hengstler, Matthew Herbst, Wassily Holzmann, Josef Jochum, Karl Johnston, Nick Karcher, Sebastian Kempf, Tom Kieck, Nina Kneip, Ulli Köster, Kathrin Kromer, Federica Mantegazzini, Bruce Marsh, Martin Neidig, Yuri Novikov, Andreas Reifenberger, Daniel Richter, Sebastian Rothe, Oliver Sander, Rima Schüssler, Christoph Schweiger, Thierry Stora, Clemens Velte, Marc Weber, Mathias Wegner, Klaus Wendt, and Tom Wickenhäuser

Subjects

Nuclear Physics - Experiment, ddc:620, Engineering & allied operations

Abstract

The European Physical Society Conference on High Energy Physics, Online conference, jointly organized by Universität Hamburg and the research center DESY; he European Physical Society Conference on High Energy Physics (EPS-HEP2021) 398, 4 pp. (2022). doi:10.22323/1.398.0211, Published by Sissa Medialab Trieste, Italy

Published

2022

8. The Electron Capture in Ho-163 experiment - ECHo

Author

Andreas Reifenberger, Felix Ahrens, Karl Johnston, Klaus Blaum, Sergey Eliseev, Thierry Stora, Nick Karcher, Daniel Hengstler, Clemens Velte, Daniel Richter, Rima Schuessler, Holger Dorrer, Klaus Wendt, Mathias Wegner, Yuri Novikov, Robert Hammann, Loredana Gastaldo, Federica Mantegazzini, Christoph E. Duellmann, Andreas Fleischmann, Christian Enss, Josef Jochum, Maurits Haverkort, Alexander Goeggelmann, Nina Kneip, Ulli Koester, Martin Brass, Oliver Sander, Menno Door, Alexander Rischka, Marc Weber, Sebastian Rothe, Tom Wickenhaeuser, Bruce Marsh, Sebastian Kempf, Arnulf Barth, Tom Kieck, Christoph Schweiger, and Pavel Filianin

Subjects

Physics::Instrumentation and Detectors

Abstract

The goal for the ECHo experiment is the determination of the effective electron neutrino mass by analyzing the electron capture (EC) spectrum of $^{163}$Ho. Metallic magnetic calorimeters enclosing $^{163}$Ho, achieved very good performance to conduct such an experiment. During the first phase of the experiment, ECHo-1k, the detector production and the implantation process of high purity $^{163}$Ho have been optimized. Large detector arrays have been developed, featuring energy resolution below 5eV and activity of about 1Bq per pixel. High statistics and high resolution $^{163}$Ho spectra have been acquired and analyzed in light of new theoretical description of the spectral shape, considering the independently determined Q$_{\mathrm{EC}}$-value, and a dedicated background model. In this contribution, we present preliminary results obtained in the first phase of ECHo. At the same time, we discuss the necessary upgrades towards the second phase of the experiment, ECHo-100k.

Published

2020

9. Measurement of the Th 229 Isomer Energy with a Magnetic Microcalorimeter

Author

Tomas Sikorsky, Jeschua Geist, Daniel Hengstler, Sebastian Kempf, Loredana Gastaldo, Christian Enss, Christoph Mokry, Jörg Runke, Christoph E. Düllmann, Peter Wobrauschek, Kjeld Beeks, Veronika Rosecker, Johannes H. Sterba, Georgy Kazakov, Thorsten Schumm, Andreas Fleischmann

Published

2020