Your search keyword '"Rosecker, Veronika"' showing total 4 results

1. Growth and characterization of thorium-doped calcium fluoride single crystals

Author

Beeks, Kjeld, Sikorsky, Tomas, Rosecker, Veronika, Pressler, Martin, Schaden, Fabian, Werban, David, Hosseini, Niyusha, Rudischer, Lukas, Schneider, Felix, Berwian, Patrick, Friedrich, Jochen, Hainz, Dieter, Welch, Jan, Sterba, Johannes H., Kazakov, Georgy, and Schumm, Thorsten

Subjects

Condensed Matter - Materials Science, Nuclear Experiment, Physics - Atomic Physics

Abstract

We have grown $^{232}$Th:CaF$_2$ and $^{229}$Th:CaF$_2$ single crystals for investigations on the VUV laser-accessible first nuclear excited state of $^{229}$Th. To reach high doping concentrations despite the extreme scarcity (and radioactivity) of $^{229}$Th, we have scaled down the crystal volume by a factor 100 compared to established commercial or scientific growth processes. We use the vertical gradient freeze method on 3.2 mm diameter seed single crystals with a 2 mm drilled pocket, filled with a co-precipitated CaF$_2$:ThF$_4$:PbF$_2$ powder in order to grow single crystals. Concentrations of $4\cdot10^{19}$ cm$^{-3}$ have been realized with $^{232}$Th with good ($>$10%) VUV transmission. However, the intrinsic radioactivity of $^{229}$Th drives radio-induced dissociation during growth and radiation damage after solidification. Both lead to a degradation of VUV transmission, limiting the $^{229}$Th concentration to $<5\cdot10^{17}$ cm$^{-3}$., Comment: 12 pages, 18 figures

Published

2022

2. Growth and characterization of thorium-doped calcium fluoride single crystals

Author

Beeks, Kjeld, Sikorsky, Tomas, Rosecker, Veronika, Pressler, Martin, Schaden, Fabian, Werban, David, Hosseini, Niyusha, Rudischer, Lukas, Schneider, Felix, Berwian, Patrick, Friedrich, Jochen, Hainz, Dieter, Welch, Jan, Sterba, Johannes H., Kazakov, Georgy, and Schumm, Thorsten

Published

2023

3. Measurement of the $^{229}$Th isomer energy with a magnetic micro-calorimeter

Author

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

Subjects

Nuclear Experiment, Nuclear Theory, Physics - Instrumentation and Detectors

Abstract

We present a measurement of the low-energy (0--60$\,$keV) $\gamma$ ray spectrum produced in the $\alpha$-decay of $^{233}$U using a dedicated cryogenic magnetic micro-calorimeter. The energy resolution of $\sim$$10\,$eV, together with exceptional gain linearity, allow us to measure the energy of the low-lying isomeric state in $^{229}$Th using four complementary evaluation schemes. The most accurate scheme determines the $^{229}$Th isomer energy to be $8.10(17)\,$eV, corresponding to 153.1(37)$\,$nm, superseding in precision previous values based on $\gamma$ spectroscopy, and agreeing with a recent measurement based on internal conversion electrons. We also measure branching ratios of the relevant excited states to be $b_{29}=9.3(6)\%$ and $b_{42}=0.3(3)\%$., Comment: 5 pages, 5 figures + supplementary

Published

2020

4. Towards an energy measurement of the internal conversion electron in the de-excitation of the Th-229 isomer

Author

Stellmer, Simon, Shigekawa, Yudai, Rosecker, Veronika, Kazakov, Georgy A., Kasamatsu, Yoshitaka, Yasuda, Yuki, Shinohara, Atsushi, and Schumm, Thorsten

Subjects

Nuclear Experiment

Abstract

The first excited isomeric state of Th-229 has an exceptionally low energy of only a few eV and could form the gateway to high-precision laser spectroscopy of nuclei. The excitation energy of the isomeric state has been inferred from precision gamma spectroscopy, but its uncertainty is still too large to commence laser spectroscopy. Reducing this uncertainty is one of the most pressing challenges in the field. Here we present an approach to infer the energy of the isomer from spectroscopy of the electron which is emitted when the isomer de-excites through internal conversion (IC). The experiment builds on U-233, which decays to Th-229 and populates the isomeric state with a 2% fraction. A film of U-233 is covered by a stopping layer of few-nm thickness and placed between an alpha detector and an electron detector, such that the alpha particle and the IC electron can be detected in coincidence. Retarding field electrodes allow for an energy measurement. In the present design, the signal of the Th-229m IC electrons is masked by low-energy electrons emitted from the surface of the metallic stopping layer. We perform reference measurements with U-232 and U-234 to study systematic effects, and we study various means to reduce the background of low-energy electrons. Our study gives guidelines to the design of an experiment that is capable of detecting the IC electrons and measuring the isomer energy., Comment: 11 pages, 8 figures

Published

2018