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We address the modification of open heavy-flavor mesons in a hot medium of light mesons within an effective theory approach consistent with chiral and heavy-quark spin-flavor symmetries and the use of the imaginarytime formalism to introduce the non-zero temperature effects to the theory. The unitarized scattering amplitudes, the ground-state self-energies and the corresponding spectral functions are calculated self-consistently. We use the thermal ground-state spectral functions obtained with this methodology to further calculate 1) open-charm meson Euclidean correlators, and 2) off-shell transport coefficients in the hadronic phase.
Sensors for high rate charge particle tracking have to withstand the harsh radiation doses deposited by the particles to be sensed. This holds particularly for the novel CMOS Monolithic Active Pixel Sensors, which are considered a promising sensor technology for future vertex detectors due to their very light material budget and excellent spatial resolution. To resist the radiation doses expected close to the interaction regions of heavy-ion experiments, the sensors have to be hardened against radiation doses, which exceed the native tolerance of CMOS technology significantly. In this thesis, the results of non-ionizing radiation hardness studies at the IKF on sensor prototypes developed at the IPHC in Strasbourg are presented. Our results demonstrate that the CMOS sensors evaluated in the context of this thesis can withstand non-ionizing radiation of up to 5×10^14 neq/cm^2. This hardness qualifies them as promising candidates for use in future vertex detectors.
The stellar nucleosynthesis of elements heavier than iron can primarily be attributed to neutron capture reactions in the s and r process. While the s process is considered to be well understood with regards to the stellar sites, phases and conditions where it occurs, nucleosynthesis networks still need accurate neutron capture cross sections
with low uncertainties as input parameters. Their quantitative outputs for the isotopic abundances produced in the s process, coupled with the observable solar abundances, can be used to indirectly infer the expected r process abundances. The two stable gallium isotopes, 69Ga and 71Ga, have been shown in sensitivity studies to have considerable impact on the weak s process in massive stars. The available experimental data, mostly derived from neutron activation measurements for quasi-stellar neutron spectra at kBT = 25 keV, show disagreements up to a factor of three.
Determining the differential neutron capture cross section can provide input data for the whole range of astrophysically relevant energies. To that end, a neutron time of flight experimental campaign at the n_TOF facility at CERN was performed for three months, using isotopically enriched samples of both isotopes. The data taken at the EAR1 experimental area covered a wide neutron energy range from thermal to several hundred keV. The respective differential and spectrum averaged neutron capture cross sections for 69Ga and 71Ga were determined in this thesis. They show good agreement with the evaluated cross sections for 71Ga, but reproduce the deviations from the evaluated data that other, more recent activation measurements showed for 69Ga.
We present the first measurement of event-by-event fluctuations in the kaon sector in Pb – Pb collisions at √sNN = 2.76 TeV with the ALICE detector at the LHC. The robust fluctuation correlator νdyn is used to evaluate the magnitude of fluctuations of the relative yields of neutral and charged kaons, as well as the relative yields of charged kaons, as a function of collision centrality and selected kinematic ranges. While the correlator νdyn[K+,K−] exhibits a scaling approximately in inverse proportion of the charged particle multiplicity, νdyn[K0 S ,K±] features a significant deviation from such scaling. Within uncertainties, the value of νdyn[K0 S ,K±] is independent of the selected transverse momentum interval, while it exhibits a pseudorapidity dependence. The results are compared with HIJING, AMPT and EPOS–LHC predictions, and are further discussed in the context of the possible production of disoriented chiral condensates in central Pb – Pb collisions.
Die Entstehung der Elemente im Universum wird auf eine Vielzahl von Prozessen zurückgeführt, die sowohl in Urknall - als auch in stellaren Szenarien angesiedelt werden. Die Kenntnis der dort ablaufenden Reaktionen und deren Raten ermöglicht es die zugrundeliegenden Modelle einzugrenzen und somit genauere Aussagen über die Plausibilität der Szenarien zu treffen. Ein Teil dieser Prozesse stützt sich auf Neutroneneinfänge an Atomkernen, wodurch die Massezahl des Ausgangskerns erhöht wird.
Die Aktivierungsmethode ermöglicht die Bestimmung der Wahrscheinlichkeit eines Neutroneneinfangs, sofern der Zielkern eine detektierbare Radioaktivität aufweist. Die experimentelle Untersuchung einer Reaktion mit einem kurzlebigen Produktkern ist eine besondere Herausforderung, da bei langen Aktivierungen zwar viele Einfänge stattfinden, die meisten Produktkerne jedoch schon während der Aktivierung zerfallen. Ein probates Mittel um genügend Zerfälle des Produktkerns beobachten zu können ist die zyklische Aktivierung, wobei die Probe in mehrfachen Wiederholungen kurz bestrahlt und ausgezählt wird.
Im Rahmen dieser Arbeit wurden zwei verschiedene Anwendungen der zyklischen Aktivierung behandelt.
Eine vom Paul Scherrer Institut Villigen bereitgestellte Probe von 10Be wurde am TRIGA Reaktor der Johannes Gutenberg - Universität Mainz mit Neutronen aktiviert. Über die Cadmiumdifferenzmethode konnte der thermische und der epithermische Anteil der Neutronen separiert werden und dadurch sowohl der thermische Wirkungsquerschnitt als auch das Resonanzintegral für die Reaktion 10Be(n,γ)11Be bestimmt werden.
Am Institut für Kernphysik der Goethe Universität Frankfurt wurde mit einem Van - de - Graaff - Beschleuniger über die 7Li(p,n)7Be Reaktion ein quasistellares Neutronenspektrum mit kBT ≈ 25 keV erzeugt. Für die zyklische Aktivierung von Proben wurde die Infrastruktur in Form einer automatisiert ablaufenden Vorrichtung zur Bestrahlung und Auszählung geplant und umgesetzt. In diesem Rahmen wurden die über das Spektrum gemittelten Neutroneneinfangsquerschnitte für verschiedene Reaktionen bestimmt. Für 19F(n,γ)20F konnte der Gesamteinfangsquerschnitt bestimmt werden. Für die Reaktion 45Sc(n,γ)46Sc wurde der partielle Wirkungsquerschnitt in den 142,5 keV Isomerzustand gemessen. Aus der 115In(n,γ)116In Reaktion konnten die partiellen Querschnitte in die Isomerzustände bei 289,7 keV, 127,3 keV sowie den Grundzustand bestimmt werden.
Außerdem wurde mit einer Hafniumprobe die partiellen Einfangsquerschnitte in den 1147,4 keV Isomerzustand von 178Hf und in den 375 keV Isomerzustand von 179Hf gemessen.
Dumme Fragen gibt es nicht
(2022)
In March 2019 the HADES experiment recorded 14 billion Ag+Ag collisions at √SNN = 2.55 GeV as a part of the FAIR phase-0 physics program. With the capabilities to measure and analyze particles forming the bulk matter, namely pions, protons and light nuclei, as well as rare probes like dilepton decays of vectormesons and strange hadrons, the HADES experiment allows to study the properties of matter at high densities in great detail. In this contribution a special focus is put on the reconstruction of weakly decaying strange hadrons.
After briefly reviewing the state of theoretical knowledge related to the behavior of the ϕ meson in nuclear matter, preliminary results of transport simulations of pA reactions corresponding to the KEK E325 experiment are presented. Finally, an outlook to current and future developments in the field is given.
Asymptotic giant branch (AGB) stars are thought to be among the most important sources of fluorine in our Galaxy. While observations and theory agree at close-to-solar metallicity, stellar models overestimate fluorine production in comparison to heavy elements at lower metallicities. We present predictions for 19F abundance for a set of AGB models with various masses and metallicities, in which magnetic buoyancy induces the formation of the 13C neutron source (the so-called 13C pocket). In our new models, fluorine is mostly created as a consequence of secondary 14N nucleosynthesis during convective thermal pulses, with a minor contribution from the 14N existing in the 13C pocket zone. As a result, AGB stellar models with magnetic-buoyancyinduced mixing show low 19F surface abundances which agree with fluorine spectroscopic observations at both low and near-solar metallicity.