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The subject of this thesis is the experimental investigation of the neutron-capture cross sections of the neutron-rich, short-lived boron isotopes 13B and 14B, as they are thought to influence the rapid neutron-capture process (r process) nucleosynthesis in a neutrino-driven wind scenario.
The 13;14B(n,g)14;15B reactions were studied in inverse kinematics via Coulomb dissociation at the LAND/R3B setup (Reactions with Relativistic Radioactive Beams). A radioactive beam of 14;15B was produced via in-flight fragmentation and directed onto a lead-target at about 500 AMeV. The neutron breakup of the projectile within the electromagnetic field of the target nucleus was investigated in a kinematically complete measurement. All outgoing reaction products were detected and analyzed in order to reconstruct the excitation energy.
The differential Coulomb dissociation cross sections as a function of the excitation energy were obtained and first experimental constraints on the photoabsorption and the neutron-capture cross sections were deduced. The results were compared to theoretical approximations of the cross sections in question. The Coulomb dissociation cross section of 15B into 14B(g.s.) + n was determined to be s(15B;14B(g:s:)+n) CD = 81(8stat)(10syst) mb ; while the Coulomb dissociation cross section of 14B into a neutron and 13B in its ground state was found to be s(14B;13B(g:s:)+n) CD = 281(25stat)(43syst) mb: Furthermore, new information on the nuclear structure of 14B were achieved, as the spectral shape of the differential Coulomb dissociation cross section indicates a halolike structure of the nucleus.
Additionally, the Coulomb dissociation of 11Be was investigated and compared to previous measurements in order to verify the present analysis. The corresponding Coulomb dissociation cross section of 11Be into 10Be(g.s.) + n was found to be 450(40stat)(54syst ) mb, which is in good agreement with the results of Palit et al.
Kleine Planeten oder Planetoiden, zu denen auch der Planetoid "Rilke" gehört, sind Überreste aus der Zeit der Entstehung unseres Sonnensystems. In den Bereichen, in denen sich die Mehrzahl der kleinen Planeten auch jetzt noch befindet (dem Planetoidengürtel), sind sie auch entstanden - vor etwa fünf Milliarden Jahren. In diesen Bereichen unseres Sonnensystems hatte die Menge des für die Bildung fester Körper verfügbaren Materials nicht einen einzigen großen Körper, sondern eine Vielzahl kleiner Körper gebildet.
We present a 360∘ (i.e., 4π steradian) general-relativistic ray-tracing and radiative transfer calculations of accreting supermassive black holes. We perform state-of-the-art three-dimensional general-relativistic magnetohydrodynamical simulations using the BHAC code, subsequently post-processing this data with the radiative transfer code RAPTOR. All relativistic and general-relativistic effects, such as Doppler boosting and gravitational redshift, as well as geometrical effects due to the local gravitational field and the observer’s changing position and state of motion, are therefore calculated self-consistently. Synthetic images at four astronomically-relevant observing frequencies are generated from the perspective of an observer with a full 360∘ view inside the accretion flow, who is advected with the flow as it evolves. As an example we calculated images based on recent best-fit models of observations of Sagittarius A*. These images are combined to generate a complete 360∘ Virtual Reality movie of the surrounding environment of the black hole and its event horizon. Our approach also enables the calculation of the local luminosity received at a given fluid element in the accretion flow, providing important applications in, e.g., radiation feedback calculations onto black hole accretion flows. In addition to scientific applications, the 360∘ Virtual Reality movies we present also represent a new medium through which to interactively communicate black hole physics to a wider audience, serving as a powerful educational tool.
Buch des Monats März 2023
(2023)
Eine jede Sonnenfinsternis, mag sie sich in noch so entlegenen, weltabgeschiedenen Gegenden abspielen, erweckt in unserer Zeit das lebhafteste Interesse des Astronomen, und mit den größten Opfern an Zeit und Geld zieht er hinaus, um dem Himmel ein neues Geheimnis abzulauschen. Einen solchen Strom von Beobachtern aber, wirklichen sowohl wie auch Sonnenfinsternis-bummlern, wie die Finsternis vom 30. August 1905, wird wohl sobald keine wieder heranlocken. In der Tat vereinigten sich alle Umstände, die Beobachtung dieser Finsternis besonders viel versprechend zu gestalten: einmal die verhältnismäßig lange Dauer (rund 3 3/4 Min.), dann die leichte Möglichkeit, die Totalitätszone zu erreichen und schließlich das für Ende August zu erwartende gute Wetter.
High resolution gamma spectroscopy with sophisticated detector arrays significantly contributes to nuclear structure physics. The Advanced Gamma Tracking Array (AGATA) combines gamma tracking and pulse shape analysis to achieve an efficiency and quality of the spectra that could not be reached with spectrometers of the previous generation. Tracking of the photons interacting in the detector requires a precise knowledge of the individual interaction positions. The task of the pulse shape analysis is to provide a position resolution of better than $5mm$ FWHM, a value that could not be achieved by segmentation of the detector alone. As the signals induced on the electrodes of the detectors depends on the position of interaction, the charge pulses can be used to infer the interaction position. To be able to handle high rates, algorithms that are used have to be optimized to be able to process the data in real-time. Pulse shape analysis is the most involved part of the real-time processing and requires further improvement. This work is dealing with optimizations and improvements of pulse shape analysis algorithms. The Grid Search algorithm localizes the interaction position by comparing the measured pulse shape with precomputed shapes in a database to find the best fit. Two linear filters based on orthogonal transformations have been compared and it could be concluded that the one based on a singular value decomposition of the pulse shapes works best. It speeds up the pulse shape analysis by a factor of roughly $2-3$ (depending on how it is combined with the other modifications). Further, a new method to exclude most signals from the database as best fit has been developed based on the principle of lateration. Most interaction positions can be excluded by means of a fast check and for single interactions on average only $34.8\%$ of all signals from the database have to be compared to the measured one. The overhead introduced by the method is negligible and the reduced number of comparisons almost direclty translates into increased efficiency of the algorithm. A similar method could also be applied for double interactions. Two or more interactions taking place in the same segment require special treatment as the measured signals cannot be directly compared to signals from the database. A new method to calculate the figure of merit that quantifies the fit in case of a double interaction has been introduced. Compared to the unmodified algorithm the new method finds the best fit for double interactions roughly two orders of magnitude faster. Actually, the time required to localize double interactions is almost the same as for single interactions. Apart from optimizing the algorithm, also the achievable position resolution was investigated. It strongly varies inside the volume of the detector and it crucially depends on the shape of all signals in the database and the amplitude of the noise present in the measured signals. As a first step towards a precise analytic expression for the position resolution, an estimate for the probability to find the correct position has been derived.
Rezensionen zu: Govert Schilling, Lars Lindberg Christensen : Unser Fenster zum Weltraum : 400 Jahre Entdeckungen mit Teleskopen. Wiley-VCH-Verlag, Weinheim 2009, 135 Seiten und Begleit DVD, ISBN 978-3-527-40867-2, 24,90 Euro. Thomas Bührke, Roland Wengenmayr (Hrsg.) : Geheimnisvoller Kosmos Astrophysik und Kosmologie im 21. Jahrhundert, Wiley-VCH Verlag, Weinheim 2009, 200 Seiten, ISBN 978-3-527-40899-3, 29,00 Euro. Lars Lindberg Christensen, Robert Fosbury, Robert Hurt : Verborgenes Universum. Wiley-VCH-Verlag, Weinheim 2009, 145 Seiten, ISBN 978-3-527-40868-9, 24,90 Euro.