Espectroscopia do núcleo 23Mg acima do limiar de decaimento de prótons com interesse para astrofísica nuclear / Spectroscopy of 23Mg nucleus above the proton threshold of interest to nuclear astrophysics

Alessandro Luiz de Lara

05 November 2018

O conhecimento das reações nucleares que ocorrem no interior das estrelas permite estudar como será a evolução destes astros e as relações de abundância entre os isótopos de alguns elementos. Em alguns casos, a detecção de elementos traços pode ser útil para inferir a ocorrência de eventos explosivos, como novas e supernovas. Um destes elementos é o 22Na, cuja abundância depende da reação de captura de próton 22Na(p, ?)23Mg. Assim, o estudo dos estados de ressonância do 23Mg, é importante para compreender o mecanismo de reação e determinar a abundância do 22Na. O núcleo de 23Mg ainda participa do ciclo NeNa na fase AGB da evolução de estrelas de massa média. Com essa motivação propomos o estudo espectroscópico do núcleo 23Mg por meio da reação de transferência 24Mg(3He, 4He)23Mg, cujos dados experimentais foram obtidos no laboratório Tandem-Orsay (França), com o uso de um feixe de 3He de 25 MeV. As ressonâncias de interesse do núcleo 23Mg estudadas nesse trabalho estão compreendidas na faixa de energia de excitação 7.5 MeV a 9.5 MeV. Os estados de ressonância do 23Mg foram populados com a interação do feixe com o alvo de natMg, e as partículas de 4He foram analisadas com o espectrógrafo Split-pole. Os espectros de posição das partículas de 4He foram então calibrados em rigidez magnética, por meio de um polinômio de segunda ordem. Após a calibração os espectros de rigidez magnética foram transformados em espectros de energia de excitação. Nesses espectros pudemos identificar e estudar a presença de contaminantes. Vários estados abaixo e alguns estados acima do limiar de decaimento foram observados e identificados. Dentre os estados acima do limiar estão os estados: 7.586, 7.648, (7.782 e 7.786), 7.855, 8.076, 8.163, 8.420, 8.453, 8.943 e 8.990 MeV do 23Mg. Sendo que apenas os estados 7.586 e 8.163 tem o spin J=5/2+ estabelecido. Ao final apresentamos uma discussã / The knowledge of the nuclear reactions that take place inside the stars allows to study how the evolution of this star will be and the relations of abundance between the isotopes of some elements. In some cases the detection of trace elements can be useful to infer about the occurrence of explosive events, as novae and the supernovae. One of these elements is the 22Na, whose abundance depends on the proton capture reaction 22Na(p, ?)23Mg. The gamma radiation photon with energy 1.275 MeV emitted by 22Na may be a novae type event indicator. Thus, the study of the resonance states of 23Mg is important to understand the mechanism of reaction and determine the 22Na abundance. The nucleus of 23Mg still participate in the cycle NeNa in the AGB phase of the evolution of average stars. With this motivation, we propose to study the spectroscopy of the 23Mg by the 24Mg(3He, 4He)23Mg neutron transfer reaction, whose experimental data were obtained in the Tandem-Orsay facility (France), using the 3He beam of energy 25 MeV. The resonances of interest for this work are in the range of 7.5 MeV up to 9.5 MeV, above the decay threshold for protons. The resonance states of 23Mg were obtained with the interaction of the beam with the natMg target, and the 4He particles were analyzed in a Split-pole spectrograph. The position spectra were then calibrated in magnetic rigidity by means of a second-order polynomial function. The effects of the contaminants were analyzed by converting the spectra into excitation energy, in which it was possible to separate the states 7.586, 7.648, (7.782 e 7.786), 7.855, 8.076, 8.163, 8.420, 8.453, 8.943 e 8.990 MeV of 23Mg. Finally we present a qualitative discussion of the angular distribution for some states and we discuss the possibilities for the future.

Astrofísica Nuclear

Nuclear Astrophysics

Resonances of 23Mg and Enge Split-pole.

Primordial nuclides and low-level counting at Felsenkeller

Turkat, Steffen

09 November 2023

Within cosmology, there are two entirely independent pillars which can jointly drive this field towards precision: Astronomical observations of primordial element abundances and the detailed surveying of the cosmic microwave background. However, the comparatively large uncertainty stemming from the nuclear physics input is currently still hindering this effort, i.e. stemming from the 2H(p,γ)3He reaction. An accurate understanding of this reaction is required for precision data on primordial nucleosynthesis and an independent determination of the cosmological baryon density. Elsewhere, our Sun is an exceptional object to study stellar physics in general. While we are now able to measure solar neutrinos live on earth, there is a lack of knowledge regarding theoretical predictions of solar neutrino fluxes due to the limited precision (again) stemming from nuclear reactions, i.e. from the 3He(α,γ)7Be reaction. This thesis sheds light on these two nuclear reactions, which both limit our understanding of the universe. While the investigation of the 2H(p,γ)3He reaction will focus on the determination of its cross- section in the vicinity of the Gamow window for the Big Bang nucleosynthesis, the main aim for the 3He(α,γ)7Be reaction will be a measurement of its γ-ray angular distribution at astrophysically relevant energies. In addition, the installation of an ultra-low background counting setup will be reported which further enables the investigation of the physics of rare events. This is essential for modern nuclear astrophysics, but also relevant for double beta decay physics and the search for dark matter. The presented setup is now the most sensitive in Germany and among the most sensitive ones worldwide.

Radiative alpha capture on 7Be with DRAGON at νp–process nucleosynthesis energies

Psaltis, Athanasios

January 2020

A possible mechanism to explain the origin of around 35 neutron–deficient stable isotopes with mass A≥75 between 74 Se and 196 Hg, known as the p–nuclei is the nucleosynthesis in the proton–rich neutrino–driven winds of core–collapse supernovae via the νp–process. However this production scenario is very sensitive to the underlying supernova dynamics and the nuclear physics input. As far as nuclear uncertainties are concerned, the breakout reaction from the pp-chains, 7Be(α, γ)11C, has been identified as an important link which can influence the nuclear flow and therefore the efficiency of the νp–process. However its reaction rate is not well known over the relevant energy range (T9 = 1.5–3). In this thesis we report on the direct first measurement of two resonances of the 7Be(α, γ)11 C reaction with previously unknown strengths using an intense radioactive 7Be beam from ISAC and the DRAGON recoil separator in inverse kinematics. Since resonance strength measurements with low mass beams using recoil separators depend strongly on the recoil angular distribution, which can exceed the acceptance of the separator, we first performed a proof–of–principle test by measuring a known resonance of the 6Li(α, γ)10B reaction, which also presents a similar challenge. Our results from the 6Li(α, γ)10B reaction are in agreement with literature, showing that DRAGON can measure resonance strengths of reactions for which the maximum momentum cone of the recoils exceeds its acceptance. From the newly measured 7Be(α, γ)11C resonance strengths we calculated the new reaction rate which is lower than the current recommended by 10–50% and constrained to 5–10% in the relevant temperature region. Using this new rate, we performed detailed nucleosynthesis calculations which suggest that there is no effect the production of light p–nuclei, but a production increase for CNO elements of up to an order of magnitude is observed. / Dissertation / Doctor of Philosophy (PhD)

nuclear astrophysics

recoil separators

radioactive ion beams

reaction networks

explosive nucleosynthesis

nuclear physics

supernovae

S-factor measurement of the 2H(α,γ)6Li reaction at energies relevant for Big-Bang nucleosynthesis

Anders, Michael

January 2013

For about 20 years now, observations of 6Li in several old metal-poor stars inside the halo of our galaxy have been reported, which are largely independent of the stars’ metallicity, and which point to a possible primordial origin. The observations exceed the predictions of the Standard Big-Bang Nucleosynthesis model by a factor of 500. In the relevant energy range, no directly measured S-factors were available yet for the main production reaction 2H(α,γ)6Li, while different theoretical estimations have an uncertainty of up to two orders of magnitude. The very small cross section in the picobarn range has been measured with a deuterium gas target at the LUNA acceler- ator (Laboratory for Underground Nuclear Astrophysics), located deep underground inside Laboratori Nazionali del Gran Sasso in Italy. A beam-induced, neutron-caused background in the γ-detector occurred which had to be analyzed carefully and sub- tracted in an appropriate way, to finally infer the weak signal of the reaction. For this purpose, a method to parameterize the Compton background has been developed. The results are a contribution to the discussion about the accuracy of the recent 6Li observations, and to the question if it is necessary to include new physics into the Standard Big-Bang Nucleosynthesis model.

info:eu-repo/classification/ddc/339

ddc:339

Caractérisation du séparateur de recul ARES et application à l'étude de la réaction 19Ne(p,g)20N

Couder, Manoel

04 June 2004

Dans les milieux astrophysiques explosifs tels que les novae ou les sursauts X, la densité d'hydrogène et la température sont suffisamment grandes pour que le temps entre deux réactions impliquant un proton soit plus court que le temps de vie de certains ions radioactifs. La connaissance de la section efficace des réactions de capture d’un proton par un ion radioactif est un des ingrédients important permettant la modélisation de tels milieux. Dans ce travail, un nouveau dispositif expérimental permettant d'étudier la force de résonance de réactions (p,gamma) en cinématique inverse est présenté. Ce dispositif, baptisé ARES (Astrophysical REcoil Separator), a été d’abord caractérisé à l'aide de l'étude de la réaction 19F(p,gamma)20Ne et plus particulièrement de la mesure de la force de la résonance bien connue à 635 keV au dessus du seuil 19F+p. De plus, la simulation de cette expérience est en accord avec les mesures effectuées. Une première mesure de force de résonance d'une réaction impliquant un faisceau d'ions radioactifs est ensuite présentée. Il s'agit de la réaction 19Ne(p,gamma)20Na et plus particulièrement de la résonance à 448 keV au dessus du seuil 19Ne+p. Une limite supérieure de 15.2 meV avec un niveau de confiance de 90% est obtenue. Cette limite supérieure améliore légèrement les résultats de mesures antérieures. / In explosive astrophysical environments such as novae or X-ray bursts, the temperature and the hydrogen density are so large that the time between two reactions involving protons is smaller than the live time of radioactive ions. The cross section of such reactions is an important ingredient of the modeling of such environments. In this work, a new experimental device, allowing the study of resonance strength of (p,gamma) reactions, is presented. This setup, called ARES (Astrophysical REcoil Separator), is first characterized using the study of the well known reaction, 19F(p,gamma)20Ne and more precisely the measurement of the resonance strength of the 635 keV level above the 19F+p threshold. The simulation of this experiment is found in good agreement with the measurement. Then the first resonance strength measurement of a reaction involving radioactive ions beams is presented, i.e. the resonance strength of the 448 keV level above the 19Ne+p threshold in the 19Ne(p,gamma)20Na reaction. An upper limit of 15.2 meV with a confidence level of 90% is obtained. This upper limit improves slightly the results of previous measurements.

Nuclear astrophysics

Radioactive ion beams

Séparateur de recul

Recoil separator

Faisceaux d'ions radioactifs

Caracterisation

Astrophysique

CNO

Cinematique

Inverse

ARES

Astrophysique nucléaire

Precise nuclear physics for the sun

Bemmerer, Daniel

January 2012

For many centuries, the study of the Sun has been an important testbed for understanding stars that are further away. One of the first astronomical observations Galileo Galilei made in 1612 with the newly invented telescope concerned the sunspots, and in 1814, Joseph von Fraunhofer employed his new spectroscope to discover the absorption lines in the solar spectrum that are now named after him. Even though more refined and new modes of observation are now available than in the days of Galileo and Fraunhofer, the study of the Sun is still high on the agenda of contemporary science, due to three guiding interests. The first is connected to the ages-old human striving to understand the structure of the larger world surrounding us. Modern telescopes, some of them even based outside the Earth’s atmosphere in space, have succeeded in observing astronomical objects that are billions of lightyears away. However, for practical reasons precision data that are important for understanding stars can still only be gained from the Sun. In a sense, the observations of far-away astronomical objects thus call for a more precise study of the closeby, of the Sun, for their interpretation. The second interest stems from the human desire to understand the essence of the world, in particular the elementary particles of which it consists. Large accelerators have been constructed to produce and collide these particles. However, man-made machines can never be as luminous as the Sun when it comes to producing particles. Solar neutrinos have thus served not only as an astronomical tool to understand the Sun’s inner workings, but their behavior on the way from the Sun to the Earth is also being studied with the aim to understand their nature and interactions. The third interest is strictly connected to life on Earth. A multitude of research has shown that even relatively slight changes in the Earth’s climate may strongly affect the living conditions in a number of densely populated areas, mainly near the ocean shore and in arid regions. Thus, great effort is expended on the study of greenhouse gases in the Earth’s atmosphere. Also the Sun, via the solar irradiance and via the effects of the so-called solar wind of magnetic particles on the Earth’s atmosphere, may affect the climate. There is no proof linking solar effects to short-term changes in the Earth’s climate. However, such effects cannot be excluded, either, making it necessary to study the Sun. The experiments summarized in the present work contribute to the present-day study of our Sun by repeating, in the laboratory, some of the nuclear processes that take place in the core of the Sun. They aim to improve the precision of the nuclear cross section data that lay the foundation of the model of the nuclear reactions generating energy and producing neutrinos in the Sun. In order to reach this goal, low-energy nuclear physics experiments are performed. Wherever possible, the data are taken in a low-background, underground environment. There is only one underground accelerator facility in the world, the Laboratory Underground for Nuclear Astrophysics (LUNA) 0.4MV accelerator in the Gran Sasso laboratory in Italy. Much of the research described here is based on experiments at LUNA. Background and feasibility studies shown here lay the base for future, higher-energy underground accelerators. Finally, it is shown that such a device can even be placed in a shallow-underground facility such as the Dresden Felsenkeller without great loss of sensitivity.

info:eu-repo/classification/ddc/539

ddc:539

A Study of the Astrophysically Important States of 31S via the 32S(d,t)31S Reaction

Irvine, Dan T.

04 1900

<p>The astrophysical ³⁰P(<em>p</em>,<em>γ</em>)³¹S reaction rate is a key quantity used in both classical nova and type I X-ray burst models that predict isotopic abundances produced during nucleosynthesis in the outburst. Currently, uncertainties in ³¹S structure parameters lead to a variation in the reaction rate by a factor of 20 at nova temperatures causing predicted isotopic abundance ratios in the Si-Ar mass region to vary by factors of up to 4. The ³⁰P(<em>p</em>,<em>γ</em>)³¹S reaction rate can be determined indirectly by measuring transfer reactions populating excited states in ³¹S. Nuclear structure information for ³¹S resonant states above the proton threshold of 6131 keV and within the Gamow window that contribute most significantly to the reaction rate can be used to re-evaluate the rate for nova and type I X-ray burst temperatures and reduce current uncertainties. We have performed an experiment in order to study the level structure of ³¹S via the ³²S(<em>d</em>,<em>t</em>)³¹S single-nucleon transfer reaction using the MP tandem accelerator and Q3D magnetic spectrograph at MLL in Munich, Germany. Excited states of ³¹S in the 6-7 MeV region were observed and spin-parity constraints have been suggested. In this work we describe the experimental setup, data analysis and results for both experiments and provide recommendations for further investigation of the ³⁰P(<em>p</em>,<em>γ</em>)³¹S astrophysical reaction rate.</p> / Master of Science (MSc)

Nuclear Astrophysics

Reaction Rate

Isotopic Abundance

Classical Nova

Stellar Nucleosynthesis

Astrophysics and Astronomy

Nuclear

Physical Processes

Physics

Astrophysics and Astronomy

Verification of an Activity Method Approach to Determine the alpha-Partial Width of the 4.03 MeV State of Ne-19

Manwell, Spencer

10 1900

<p>This thesis describes a new experimental approach that has been designed to determine the alpha-branching ratio of the 4.03-MeV excited state of Ne-19. A precise measurement of this quantity is needed to reduce reaction rate uncertainties in Type I x-ray bursts models. The alpha-branching will be measured by the detection of the beta+ activity of the associated alpha-decay product. This activity method has been modelled using two separate simulations. The first, a Monte Carlo code to simulate the reaction process and energy distributions of the decay products. Secondly, a GEANT4 simulation was created to predict the detector response to the O-15 beta+ activity. Along with the simulations two NaI(Tl) detectors, which were customized to this experiment's geometric constraints, have been tested and their response and resolution have been determined. The results of this work will be used to refine the experimental setup such that the proposed test run and eventual alpha-branching ratio measurement of the 4.03-MeV state will be successful. With the results of the simulations and subsequent yield calculations, it has been found that reasonable statistical significance in the O-15 yield from the 4.03-MeV excited state in Ne-19 can be achieved within 10 days of beamtime.</p> / Master of Science (MSc)

Nuclear Astrophysics

Type I x-ray bursts

Nucleosynthesis

Experimental

HCNO Breakout Reactions

Instrumentation

Nuclear

Other Astrophysics and Astronomy

Instrumentation

Contributions récéntes à l'astrophysique nucléaire / Recent contributions to nuclear astrophysics

Angulo Pérez, Carmen

20 June 2006

L'astrophysique nucléaire est la discipline scientifique qui étudie la production d'énergie et la synthèse des éléments (nucléosynthèse) dans les étoiles. Les réactions nucléaires entre des noyaux légers (A < 20-30) et des protons ou des particules alpha jouent un rôle fondamental. Elles produisent les éléments lourds à partir des éléments plus légers et permettent à l'étoile de dégager de l'énergie. Cette production d'énergie et des éléments explique à son tour la structure et l'évolution des étoiles et, donc de l'Univers. Quels que soient les processus considérés (nucléosynthèse primordiale, stellaire ou explosive) le calcul des abondances des éléments dans les étoiles requiert la connaissance de nombreuses sections efficaces de réactions nucléaires [B2FH57]. Les réactions nucléaires sous-coulombiennes entre noyaux légers interviennent au cœur des étoiles lors des phases de combustion de l'hydrogène et de l'hélium en équilibre hydrostatique. Dans des processus à température plus élevée (novae, supernovae, sursauts X) les éléments radioactifs sont largement impliqués dans le réseau de réactions, ce qui, d'autre part, amène des problèmes spécifiques aux expérimentateurs [Bla06]. Ma dissertation est une récapitulation des travaux expérimentaux et théoriques en astrophysique nucléaire que j'ai réalisés de janvier 1993 à janvier 2006 (cette thèse ne présente pas mes autres travaux en physique nucléaire, principalement sur la structure et les interactions des noyaux exotiques, voir par exemple [Ang03a, Raa04, Cas06]). Je présente quelques méthodes expérimentales en astrophysique nucléaire et je discute brièvement certains problèmes techniques liés aux mesures des sections efficaces très petites, et en particulier, au caractère spécifique de certains appareils (accélérateurs, spectromètres, etc.). Un premier exemple se rapporte à la mise au point de l'accélérateur de protons de 250 kV construit au CSNSM à Orsay (France) dont j'ai été responsable de la calibration [Bog94]. Ensuite, je présente les tests du spectromètre de recul ARES [Cou03] construit au Centre de Recherches du Cyclotron et l'étude d'une réaction d'intérêt astrophysique avec le premier faisceau radioactif produit par le cyclotron CYCLONE44 [Cou04]. Je discute également d'une manière générale les mesures de sections efficaces de réactions nucléaires par des méthodes directes et indirectes. Pour les méthodes directes, je me suis intéressée plus particulièrement aux mesures avec des faisceaux de protons très intenses (accélérateur de 100 kV au DTL-Bochum), ainsi qu'aux expériences avec des éléments radioactifs -cibles ou faisceaux- (CSNSM, Orsay et cyclotrons de Louvain-la-Neuve). Dans ce contexte, je présente plusieurs cas de réactions d'intérêt en astrophysique comme, par exemple, 9Be(p,gamma)10B [Zah95] (nucléosynthèse stellaire), 7Be(p,gamma)8B [Ham98, Ham01] (liée au problème du neutrino solaire), 7Be(p,p)7Be [Ang03b] (liée à la réaction 7Be(p,?)8B), 18F(p,alpha)15O [Ser03] (nucléosynthèse explosive dans les novae), 7Be(d,p)2alpha [Ang05a] (nucléosynthèse du Big Bang). Quand une mesure directe est très difficile à réaliser, il existe des méthodes indirectes comme, par exemple, les réactions de transfert. Elles sont utiles, entre autres, dans l'étude des largeurs alpha des états d'importance astrophysique de certains noyaux. Je discute les cas du 19F (nucléosynthèse du fluor) étudié par la réaction 15N(7Li,t)19F [Oli95] et du 19Ne (nucléosynthèse dans les novae) étudié avec 18F(d,p)19F [Ser03]. Un traitement théorique rigoureux de la dépendance en énergie des sections efficaces est nécessaire pour extrapoler ces dernières aux énergies caractéristiques des processus astrophysiques, à partir des sections efficaces expérimentales (prises à des énergies plus élevées). Un des effets dont il faut tenir compte pour ces extrapolations est l'effet d'écrantage électronique en laboratoire [Ass87] qui devient important à des énergies très basses (< 10-20 keV). Parmi les différents modèles théoriques généralement appliqués aux réactions d'intérêt astrophysique, je me suis spécialement intéressée à la méthode de la matrice R [Lan58]. Cette approche contient des paramètres ajustables sur les sections efficaces disponibles, et les valeurs des sections efficaces aux énergies stellaires sont obtenues par extrapolation. Je présente l'étude de l'écrantage électronique de réactions non-résonnantes en appliquant le modèle de la matrice R [Ang98]. Je montre également son application à deux réactions de capture radiative importantes en astrophysique, 12C(alpha,gamma)16O [Ang00] et 14N(p,gamma)15O [Ang01]. L'analyse de la réaction 14N(p,gamma)15O est discutée en détails [For04, Run04, Ang05b]. Elle joue un rôle important dans la détermination de l'âge des amas globulaires, donc dans la détermination de l'âge de l'Univers [Deg04], et dans la nucléosynthèse dans des étoiles géantes rouges [Her06]. Finalement, je discute l'importance des bases de données pour l'astrophysique nucléaire, et en particulier, des compilations de taux de réactions. Je présente la compilation de taux de réactions la plus récente [Ang99], que j'ai coordonnée pendant mon séjour à l'Université Libre de Bruxelles (1995-1998) dans le cadre d'une collaboration entre 10 laboratoires européens (cette publication a actuellement plus de 350 citations à la date de mai 2006). Je présente aussi une compilation des réactions les plus importantes impliquées dans la nucléosynthèse du Big Bang [Des04] et une évaluation de l'effet des nouveaux taux de réactions sur la valeur de la densité baryonique de l'univers [Coc04]. Les conclusions situent ces travaux dans leur contexte actuel.

Radioactive beams

Combustion stellaire

Explosive burning

Primordial burning

Combustion primordiale

Theoretical models

Faisceaux radioactifs

Combustions explosive

Astrophysique nucléaire

Nuclear reactions

Réactions nucléaires

Modèles théoriques

Nuclear astrophysics

Stellar burning

Experimente zur Entstehung von Titan-44 in Supernovae

Schmidt, Konrad

08 August 2012

In dieser Diplomarbeit wurde das astrophysikalisch interessante Resonanztriplett der Reaktion 40Ca(α,γ)44Ti bei 4,5MeV untersucht. Am 3-MV-Tandetron des Helmholtz-Zentrums Dresden-Rossendorf wurden dafür die Energien von Protonen- und -Strahlen kalibriert, Anregungsfunktionen im Energiebereich der drei Resonanzen aufgenommen, vier CaOTargets aktiviert und deren Struktur mittels der Reaktion 40Ca(p,γ)41Sc überprüft. Im Felsenkeller-Niederniveaumesslabor wurde anschließend die Aktivität der Proben gemessen. Schließlich konnte die Summe der Resonanzstärken bei 4497 und 4510 keV -Energie im Laborsystem zu (12;8 2;3) eV und die Summe der Resonanzstärken des gesamten Tripletts, d.h. zusätzlich bei 4523 keV, zu (12;0 2;0) eV bestimmt werden. Bei der ersten Resonanzstärke konnte die Unsicherheit im Vergleich zur Literatur von 19% auf 18% verbessert werden. Außerdem bieten die Daten der vorliegenden Arbeit die Grundlage, zukünftig die Unsicherheiten noch erheblich weiter zu reduzieren. / In this thesis the astrophysically interesting resonance triplet of the 40Ca(α ,γ)44Ti reaction at 4.5MeV has been studied. For this purpose energies of proton and beams provided by 3MVTandetron at Helmholtz-Zentrum Dresden-Rossendorf have been calibrated. Excitation functions of energy regions near the resonances and in-beam spectra of four different targets have been measured. The 40Ca(p,γ)41Sc reaction has been used to scan the structure of the activated targets. Afterwards their activity has been measured in the underground laboratory Felsenkeller Dresden. Hence the sum of resonance strengths at laboratory energies of 4497 and 4510 keV of (12:8 2:3) eV has been determined as well as the sum of the total triplet strength, including 4523 keV, of (12:0 2:0) eV. In the case of the first resonance, the uncertainty was decreased from 19% to 18 %. Furthermore the results of this work establish a basis for reaching much lower uncertainties in the future.

Ti-44

Supernova

Nukleare Astrophysik

Aktivierung

40Ca(alpha

gamma)44Ti

Tandetron

Felsenkeller

Ti-44

supernova

nuclear astrophysics

activation

40Ca(alpha

gamma)44Ti

Tandetron

Felsenkeller

ddc:539