Your search keyword '"K. Farouqi"' showing total 30 results

1. Production of light trans-Fe elements in core collapse-supernovae: Implications from presolar SiC-X grains

Author

Karl-Ludwig Kratz, Waheed Akram, Oliver Hallmann, and K. Farouqi

Subjects

Core (optical fiber), Physics, Supernova, Collapse (topology), Astrophysics

Published

2019

2. The Hamburg/ESO R-process Enhanced Star survey (HERES):XI. The highly r-process-enhanced star CS 29497-004

Author

B. Pfeiffer, Timothy C. Beers, Norbert Christlieb, Paul S. Barklem, Birgitta Nordström, Karl Kratz, Vanessa Hill, K. Farouqi, Laboratoire de Cosmologie, Astrophysique Stellaire & Solaire, de Planétologie et de Mécanique des Fluides (CASSIOPEE), Université Nice Sophia Antipolis (... - 2019) (UNS), COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de la Côte d'Azur, Université Côte d'Azur (UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Université Côte d'Azur (UCA)-Centre National de la Recherche Scientifique (CNRS), Center for the Study of Cosmic Evolution (CSCE), Michigan State University [East Lansing], Michigan State University System-Michigan State University System, Department of Physics and Astronomy [Uppsala], Uppsala University, Niels Bohr Institute [Copenhagen] (NBI), Faculty of Science [Copenhagen], and University of Copenhagen = Københavns Universitet (KU)-University of Copenhagen = Københavns Universitet (KU)

Subjects

MODEL ATMOSPHERES, Solar System, Population II [stars], Thermodynamic equilibrium, METAL-POOR STARS, FOS: Physical sciences, Astrophysics, Star (graph theory), 01 natural sciences, 7. Clean energy, Spectral line, Galactic halo, chemically peculiar [stars], CORE-COLLAPSE SUPERNOVAE, LABORATORY TRANSITION-PROBABILITIES, 0103 physical sciences, EXPERIMENTAL OSCILLATOR-STRENGTHS, halo [Galaxy], Neutron, EARLY GALAXY, 010306 general physics, 010303 astronomy & astrophysics, ComputingMilieux_MISCELLANEOUS, Solar and Stellar Astrophysics (astro-ph.SR), Physics, PROCESS-RICH, GALACTIC CHEMICAL EVOLUTION, Astronomy and Astrophysics, individual: CS 29497-004 [stars], [PHYS.ASTR.SR]Physics [physics]/Astrophysics [astro-ph]/Solar and Stellar Astrophysics [astro-ph.SR], Astrophysics - Astrophysics of Galaxies, abundances [stars], Stars, HIGH-ENTROPY-WIND, [PHYS.ASTR.GA]Physics [physics]/Astrophysics [astro-ph]/Galactic Astrophysics [astro-ph.GA], Astrophysics - Solar and Stellar Astrophysics, 13. Climate action, Space and Planetary Science, Astrophysics of Galaxies (astro-ph.GA), r-process, NEUTRON-CAPTURE

Abstract

We report an abundance analysis for the highly r-process-enhanced (r-II) star CS 29497-004, a very metal-poor giant with Teff = 5013K and [Fe/H]=-2.85, whose nature was initially discovered in the course of the HERES project. Our analysis is based on high signal-to-noise, high-resolution (R~75000) VLT/UVES spectra and MARCS model atmospheres under the assumption of local thermodynamic equilibrium, and obtains abundance measurements for a total of 46 elements, 31 of which are neutron-capture elements. As is the case for the other 25 r-II stars currently known, the heavy-element abundance pattern of CS 29497-004 well-matches a scaled Solar System second peak r-process-element abundance pattern. We confirm our previous detection of Th, and demonstrate that this star does not exhibit an "actinide boost". Uranium is also detected (log e(U) =-2.20+/-0.30), albeit with a large measurement error that hampers its use as a precision cosmo-chronometer. Combining the various elemental chronometer pairs that are available for this star, we derive a mean age of 12.2+/-3.7 Gyr using the theoretical production ratios from waiting-point approximation models (Kratz et al. 2007). We further explore the high-entropy wind model (Farouqi et al. 2010) production ratios arising from different neutron richness of the ejecta (Y_e), and derive an age of 13.7+/-4.4 Gyr for a best-fitting Y_e=0.447. The U/Th nuclei-chronometer is confirmed to be the most resilient to theoretical production ratios and yields an age of 16.5+:-6.6 Gyr. Lead (Pb) is also tentatively detected in CS 29497-004, at a level compatible with a scaled Solar r-process, or with the theoretical expectations for a pure r-process in this star., Comment: 24 pages, 15 figures, accepted in Astronomy and Astrophysics

Published

2017

3. Nucleosynthesis of light trans-Fe isotopes in ccSNe: Implications from presolar SiC-X grains

Author

Waheed Akram, K. Farouqi, Karl-Ludwig Kratz, and Oliver Hallmann

Subjects

Physics, Solar System, Isotope, QC1-999, Astrophysics, 01 natural sciences, Stars, Supernova, Nucleosynthesis, 0103 physical sciences, 010306 general physics, Ejecta, 010303 astronomy & astrophysics

Abstract

This contribution presents an extension of our r-process parameter study within the high-entropy-wind (HEW) scenario of corecollapse supernovae (ccSNe). One of the primary aims of this study was to obtain indications for the production of classical p-, s- and r-isotopes of the light trans-Fe elements in the Solar System (S.S.). Here, we focus on the nucleosynthesis origin of the anomalous isotopic compositions of Zr, Mo and Ru in presolar SiC X-grains (SNe grains). In contrast to the interpretation of other groups, we show that these grains do not represent the signatures of a ‘clean’ stellar scenario, but rather, are mixtures of an exotic nucleosynthesis component and S.S. material. We further confirm the results of our earlier studies whereby sizeable amounts of all stable p-, s- and r-isotopes of Zr, Mo and Ru can be co-produced by moderately neutron-rich ejecta of the low-entropy, charged-particle scenario of ccSNe (type II). The synthesis of these isotopes through a ‘primary’ production mode provides further means to revise the abundance estimates of the light trans-Fe elements from so far favoured ‘secondary’ scenarios like Type Ia SNe or neutron-bursts in exploding massive stars.

Published

2020

4. Nuclear-data input to the classical r-process: The case of β-decay properties

Author

B. Pfeiffer, Karl-Ludwig Kratz, and K. Farouqi

Subjects

Physics, Isotope, 010308 nuclear & particles physics, Nuclear structure, Extrapolation, Nuclear data, 01 natural sciences, 7. Clean energy, Nuclear physics, 0103 physical sciences, Still face, r-process, Nuclear drip line, 010306 general physics, Line (formation)

Abstract

Attempts to explain the origin of r-process elements in our Solar System (S.S.) still face entwined uncertainties, stemming from the extrapolation of nuclear structure from the line of β-stability to the neutron drip line, inconsistent sources of different properties (e.g. nuclear masses and β-decay quantities), and the poor understanding of astrophysical conditions, which are often hard to disentangle.In this paper, we will focus on the two interrelated gross β-decay quantities T1/2 and Pn. We compare the recent experimental T1/2 of very neutron-rich isotopes in the 36Kr to 50Sn region (measured at RIKEN) with consistent QRPA(GT+ff) predictions based on the two global deformed mass models ETFSI-Q(1996) and FRDM(2012). Analyzing the observed agreement and remaining deficiencies of the T1/2 trends, we predict the still unknown β-delayed neutron-emission probabilities (Pn) for these isotopes using the empirical Kratz-Herrmann formula (KHF) and the microscopic ETFSI-Q/QRPA(GT+ff) model combination.

Published

2017

5. What are the astrophysical sites for the r-process and the production of heavy elements?

Author

Roger Käppeli, I. V. Panov, Iris Dillmann, I. Korneev, Thomas Rauscher, Gabriel Martínez-Pinedo, C. Winteler, Friedrich-Karl Thielemann, Carla Fröhlich, Matthias Liebendörfer, Tobias Fischer, K. Farouqi, Almudena Arcones, K.-L. Kratz, and K. Langanke

Subjects

Physics, Nuclear and High Energy Physics, 010308 nuclear & particles physics, Astrophysics::High Energy Astrophysical Phenomena, Astronomy, Astrophysics, Type II supernova, 01 natural sciences, 7. Clean energy, p-process, Supernova, Neutron star, 13. Climate action, Nucleosynthesis, 0103 physical sciences, Astrophysics::Solar and Stellar Astrophysics, r-process, Nuclear Experiment, s-process, 010303 astronomy & astrophysics, Stellar evolution, Astrophysics::Galaxy Astrophysics

Abstract

This article addresses three of the four nucleosynthesis processes involved in producing heavy nuclei beyond Fe (with a main focus on the r -process). Opposite to the fourth process (the s -process), which operates in stellar evolution during He- and C-burning, they are all related to explosive burning phases, (presumably) linked to core collapse supernova events of massive stars. The (classical) p -process is identified with explosive Ne/O-burning in outer zones of the progenitor star. It is initiated by the passage of the supernova shock wave and acts via photodisintegration reactions like a spallation process which produces neighboring (proton-rich) isotopes from pre-existing heavy nuclei. The reproduction of some of the so-called lighter p -isotopes with A 100 faces problems in this environment. The only recently discovered ν p -process is related to the innermost ejecta, the neutrino wind expelled from the hot proto-neutron star after core collapse and the supernova explosion. This neutrino wind is proton-rich in its early phase, producing nuclei up to 64Ge. Reactions with neutrinos permit to overcome decay/reaction bottlenecks for the flow beyond 64Ge, thus producing light p -isotopes, which face problems in the classical p -process scenario. The understanding of the r -process, being identified for a long time with rapid neutron captures and passing through nuclei far from stability, is still experiencing major problems. These are on the one hand related to nuclear uncertainties far from stability (masses, half-lives, fission barriers), affecting the process speed and abundance peaks. On the other hand the site is still not definitely located, yet. (i) Later, possibly neutron-rich, high entropy phases of the neutrino wind (if they materialize!) could permit its operation. (ii) Other options include the ejection of very neutron-rich neutron star-like matter, occurring possibly in neutron star mergers or core collapse supernova events with jets, related to prior stellar evolution with high rotation rates and magnetic fields. Two different environments are required for a weak and a main/strong r -process, witnessed by observations of low metallicity stars and meteoritic inclusions, which could possibly be identified with the two options listed above, i.e. the weak r -process could be related to the neutrino wind when changing from p -rich to n -rich conditions.

Published

2011

6. CHARGED-PARTICLE AND NEUTRON-CAPTURE PROCESSES IN THE HIGH-ENTROPY WIND OF CORE-COLLAPSE SUPERNOVAE

Author

K. Farouqi, J. W. Truran, Thomas Rauscher, K.-L. Kratz, F.-K. Thilemann, and B. Pfeiffer

Subjects

Physics, Neutron emission, Astrophysics::High Energy Astrophysical Phenomena, Nuclear Theory, FOS: Physical sciences, Astronomy and Astrophysics, Astrophysics, Electron, 01 natural sciences, 7. Clean energy, Charged particle, Neutron capture, Neutron star, Supernova, Astrophysics - Solar and Stellar Astrophysics, 13. Climate action, Space and Planetary Science, 0103 physical sciences, Neutron, Chemical equilibrium, 010306 general physics, Nuclear Experiment, 010303 astronomy & astrophysics, Solar and Stellar Astrophysics (astro-ph.SR)

Abstract

The astrophysical site of the r-process is still uncertain, and a full exploration of the systematics of this process in terms of its dependence on nuclear properties from stability to the neutron drip-line within realistic stellar environments has still to be undertaken. Sufficiently high neutron to seed ratios can only be obtained either in very neutron-rich low-entropy environments or moderately neutron-rich high-entropy environments, related to neutron star mergers (or jets of neutron star matter) and the high-entropy wind of core-collapse supernova explosions. As chemical evolution models seem to disfavor neutron star mergers, we focus here on high-entropy environments characterized by entropy $S$, electron abundance $Y_e$ and expansion velocity $V_{exp}$. We investigate the termination point of charged-particle reactions, and we define a maximum entropy $S_{final}$ for a given $V_{exp}$ and $Y_e$, beyond which the seed production of heavy elements fails due to the very small matter density. We then investigate whether an r-process subsequent to the charged-particle freeze-out can in principle be understood on the basis of the classical approach, which assumes a chemical equilibrium between neutron captures and photodisintegrations, possibly followed by a $\beta$-flow equilibrium. In particular, we illustrate how long such a chemical equilibrium approximation holds, how the freeze-out from such conditions affects the abundance pattern, and which role the late capture of neutrons originating from $\beta$-delayed neutron emission can play., Comment: 52 pages, 31 figures

Published

2010

7. Co-Production of Light p-, s- and r-Process Isotopes in the High-Entropy Wind of Type II Supernovae

Author

B. Pfeiffer, K. Farouqi, and Karl Kratz

Subjects

Physics, Isotope, Stable isotope ratio, FOS: Physical sciences, Astronomy and Astrophysics, Natural abundance, Astrophysics, Electron, Supernova, Astrophysics - Solar and Stellar Astrophysics, Space and Planetary Science, Nucleosynthesis, r-process, Production (computer science), Atomic physics, Solar and Stellar Astrophysics (astro-ph.SR)

Abstract

We have performed large-scale nucleosynthesis calculations within the high-entropy-wind (HEW) scenario of type II supernovae. The primary aim was to constrain the conditions for the production of the classical "p-only" isotopes of the light trans-Fe elements. We find, however, that for electron fractions in the range 0.458 $\le$ Y$_e$ $\le$ 0.478, sizeable abundances of p-, s- and r-process nuclei between $^{64}$Zn and $^{98}$Ru are coproduced in the HEW at low entropies (S $\le$ 100) by a primary charged-particle process after an $\alpha$-rich freezeout. With the above Y$_e$ -- S correlation, most of the predicted isotopic abundance ratios within a given element (e.g. $^{64}$Zn(p)/$^{70}$Zn(r) or $^{92}$Mo(p)/$^{94}$Mo(p)), as well as of neighboring elements (e.g. $^{70}$Ge(s+p)/$^{74}$Se(p) or $^{74}$Se(p)/$^{78}$Kr(p)) agree with the observed Solar-System ratios. Taking the Mo isotopic chain as a particularly challenging example, we show that our HEW model can account for the production of all 7 stable isotopes, from "p-only" $^{92}$Mo, via "s-only" $^{96}$Mo up to "r-only" $^{100}$Mo. Furthermore, our model is able to reproduce the isotopic composition of Mo in presolar SiC X-grains.}, Comment: 10 pages, 2 figures

Published

2009

8. Nucleosynthesis modes in the high-entropy-wind of type II supernovae

Author

Lyudmila Mashonkina, K. L. Kratz, B. Pfeiffer, and K. Farouqi

Subjects

Physics, Superposition principle, Supernova, Space and Planetary Science, Nucleosynthesis, Metallicity, Parameterized complexity, Entropy (information theory), Astronomy, Astronomy and Astrophysics, Astrophysics, Partial correlation, Charged particle

Abstract

The exact conditions for the supernova high-entropy wind (HEW) as one of the favored sites for the rapid neutron-capture (r-) process still cannot be reproduced selfconsistently in present hydrodynamic simulations. Therefore, we have performed large-scale network calculations within a parameterized HEW model to constrain the necessary conditions for a full r-process, and to compare our results with recent astronomical observations. A superposition of entropy trajectories with model-inherent weightings results in an excellent reproduction of the overall solar-system isotopic abundances ( N r ,⊙ ) of the “main” r-process elements beyond Sn. For the lighter r-elements, our model supports earlier qualitative ideas about a multiplicity of nucleosynthesis processes in the Fe-group region. In the high-entropy-wind scenario, these suggestions are quantified, and the origin of the “missing” abundances to N r ,⊙ is determined to be a rapid primary charged-particle (α-) process, thus excluding a classical “weak” neutron-capture component. This explains the recent halo-star observations of a non-correlation of Cu–Ge and Sr–Zr with metallicity [Fe/H] and r-process enrichment [Eu/H]. Moreover, for the first time a partial correlation with the “main” r-process is identified for Ru and Pd.

Published

2008

9. Nucleosynthesis in the Early Galaxy

Author

K. Farouqi, Fernando Montes, B. Pfeiffer, Karl Kratz, R. Gallino, Timothy C. Beers, Marco Pignatari, John J. Cowan, Hendrik Schatz, Michael Heil, and T. Elliot

Subjects

Physics, Star (game theory), Astrophysics (astro-ph), FOS: Physical sciences, Astronomy and Astrophysics, Astrophysics, Galaxy, Neutron capture, Stars, Space and Planetary Science, Abundance (ecology), Nucleosynthesis, Neutron, Mixing (physics)

Abstract

Recent observations of r-process-enriched metal-poor star abundances reveal a non-uniform abundance pattern for elements $Z\leq47$. Based on non-correlation trends between elemental abundances as a function of Eu-richness in a large sample of metal-poor stars, it is shown that the mixing of a consistent and robust light element primary process (LEPP) and the r-process pattern found in r-II metal-poor stars explains such apparent non-uniformity. Furthermore, we derive the abundance pattern of the LEPP from observation and show that it is consistent with a missing component in the solar abundances when using a recent s-process model. As the astrophysical site of the LEPP is not known, we explore the possibility of a neutron capture process within a site-independent approach. It is suggested that scenarios with neutron densities $n_{n}\leq10^{13}$ $cm^{-3}$ or in the range $n_{n}\geq10^{24}$ $cm^{-3}$ best explain the observations., 28 pages, 7 Postscript figures. To be published in The Astrophysical Journal

Published

2007

10. Nuclear physics far from stability and r-process nucleosynthesis

Author

K. Farouqi, K. L. Kratz, and B. Pfeiffer

Subjects

Physics, Nuclear physics, Nuclear and High Energy Physics, Supernova, Stellar nucleosynthesis, Explosive material, Nucleosynthesis, Nuclear astrophysics, r-process, Observable, Stability (probability)

Abstract

Nucleosynthesis theory predicts that half of the chemical elements above Fe are formed in explosive stellar scenarios by the r-process. A correct modelling of this process requires knowledge of nuclear properties very far from stability and a detailed description of the astrophysical environments. Using updated experimental and theoretical nuclear-physics data, we have performed detailed r-process calculations within the classical, site-independent “waiting-point” approximation and the “neutrino-wind” scenario of core-collapse type II supernovae (SNII). Nuclear and astrophysical constraints on the reproduction of the available r-process observables will be reviewed.

Published

2007

11. THE R-PROCESS: SUPERNOVAE AND OTHER SOURCES OF THE HEAVIEST ELEMENTS

Author

K.-H. Schmidt, Friedrich-Karl Thielemann, E. Kolbe, I. V. Panov, K. Farouqi, K.-L. Kratz, Gabriel Martínez-Pinedo, B. Pfeiffer, K. Langanke, A. Kelic, D. Mocelj, Thomas Rauscher, and Nikolaj Thomas Zinner

Subjects

Physics, Nuclear and High Energy Physics, Astrophysics::High Energy Astrophysical Phenomena, Nuclear Theory, General Physics and Astronomy, Astronomy, Astrophysics, Neutron star, Supernova, Neutron capture, Stars, Nucleosynthesis, Photodisintegration, Astrophysics::Solar and Stellar Astrophysics, r-process, Neutron, Nuclear Experiment, Astrophysics::Galaxy Astrophysics

Abstract

Rapid neutron capture in stellar explosions is responsible for the heaviest elements in nature, up to Th , U and beyond. This nucleosynthesis process, the r-process, is unique in the sense that a combination of nuclear physics far from stability (masses, half-lives, neutron-capture and photodisintegration, neutron-induced and beta-delayed fission and last but not least neutrino-nucleus interactions) is intimately linked to ejecta from astrophysical explosions (core collapse supernovae or other neutron star related events). The astrophysics and nuclear physics involved still harbor many uncertainties, either in the extrapolation of nuclear properties far beyond present experimental explorations or in the modeling of multidimensional, general relativistic (neutrino-radiation) hydrodynamics with rotation and possibly required magnetic fields. Observational clues about the working of the r-process are mostly obtained from solar abundances and from the abundance evolution of the heaviest elements as a function of galactic age, as witnessed in old extremely metal-poor stars. They contain information whether the r-process is identical for all stellar events, how abundance features develop with galactic time and whether the frequency of r-process events is comparable to that of average core collapse supernovae - producing oxygen through titanium, as well as iron-group nuclei. The theoretical modeling of the r-process has advanced from simple approaches, where the use of static neutron densities and temperatures can aid to test the influence of nuclear properties far from stability on abundance features, to more realistic expansions with a given entropy, global neutron/proton ratio and expansion timescales, as expected from explosive astrophysical events. The direct modeling in astrophysical events such as supernovae still faces the problem whether the required conditions can be met.

Published

2007

12. Astrophysical conditions for an r-process in the high-entropy wind scenario of type II supernovae

Author

C. Freiburghaus, B. Pfeiffer, K.-L. Kratz, Friedrich-Karl Thielemann, Thomas Rauscher, and K. Farouqi

Subjects

Physics, Shock wave, Nuclear physics, Nuclear and High Energy Physics, Supernova, Neutron star, Bubble, r-process, Entropy (information theory), Neutron, Astrophysics, Nuclear Experiment

Abstract

Within a full dynamical parameter study including freezeout effects, we have determined the astrophysical conditions for an r-process in the so-called ``neutrino-wind`` scenario of core-collapse type II supernovae (SNII). We have started our calculations after the total photo disintegration of the matter above the nascent neutron star at 9 (.) 101 Kelvin with protons and neutrons. We have used the charged-particle network of Thielemann and the r-process code of Freiburghaus, combined with the NON-SMOKER neutron-capture rates of Rauscher, nuclear masses from the ETFS1-Q mass model and recent experimental and theoretical gross beta-decay properties. Using the three parameters V-exp (expansion speed of the shock wave), S (entropy of the bubble) and the neutron-to-proton ratio Y-e, we show that the above quantities have to fulfill specific conditions in order to make a successful r-process. According to observations and hydrodynamical simulations, respectively, a realistic value for Vexp is 7500 km/s, and Y>0.5.

Published

2005

13. Origin of Anomalous Xe-H in Nanodiamond Stardust

Author

B. Pfeiffer, Karl-Ludwig Kratz, Ulrich Ott, K. Farouqi, and Oliver Hallmann

Subjects

Physics, Earth and Planetary Astrophysics (astro-ph.EP), Supernova, Nucleosynthesis, r-process, FOS: Physical sciences, Natural abundance, Electron, Astrophysics, Ejecta, Abundance of the chemical elements, Cosmic dust, Astrophysics - Earth and Planetary Astrophysics

Abstract

Still today, the nucleosynthesis origin of Xe-H in presolar nanodiamonds is far from understood. Historically, possible explanations were proposed by a secondary "neutron-burst" process occurring in the He- or C/O-shells of a type-II supernova (SN-II), which are, however, not fully convincing in terms of modern nucleosynthesis conditions. Therefore, we have investigated Xe isotopic abundance features that may be diagnostic for different versions of a classical, primary r-process in high-entropy-wind (HEW) ejecta of core-collapse SN-II. We report here on parameter tests for non-standard r-process variants, by varying electron abundances (Y$_e$), ranges of entropies (S) and expansion velocities (V$_{exp}$) with their correlated neutron-freezeout times ($\tau$(freeze)) and temperatures (T$_9$(freeze)). From this study, we conclude that a best fit to the measured Xe-H abundance ratios $^i$Xe/$^{136}$Xe can be obtained with the high-S "main" component of a "cold" r-process variant., Comment: 7 pages, 7 figures, Seventh European Summer School on Experimental Nuclear Astrophysics, Sept. 15-27 2013, Santa Tecla (CT), Sicily, Italy

Published

2014

14. DECAY OF THE r-PROCESS NUCLIDES 137,138,139<font>Sb</font> AND THE <font>A</font>=130 SOLAR r-PROCESS ABUNDANCE PEAK

Author

A. A. Hecht, O. Arndt, V. N. Fedosseev, J. Shergur, U. Köster, S. Hennrich, C. J. Jost, N. Hoteling, K. L. Kratz, B. Pfeiffer, M. A. Stoyer, K. Farouqi, William B. Walters, and A. Wöhr

Subjects

Chemistry, Abundance (ecology), Radiochemistry, r-process, Nuclide

Published

2013

15. New Attempts to Understand Nanodiamond Stardust

Author

Ulrich Ott, A. Besmehn, Karl-Ludwig Kratz, Peter Hoppe, K. Farouqi, Karl Melber, Oliver Hallmann, and Anton Wallner

Subjects

Physics, FOS: Physical sciences, Diamond, Astronomy and Astrophysics, Natural abundance, Astrophysics, engineering.material, Secondary ion mass spectrometry, Supernova, Meteorite, Astrophysics - Solar and Stellar Astrophysics, Space and Planetary Science, Nucleosynthesis, engineering, Neutron, Solar and Stellar Astrophysics (astro-ph.SR), Accelerator mass spectrometry

Abstract

We report on a concerted effort aimed at understanding the origin and history of the pre-solar nanodiamonds in meteorites including the astrophysical sources of the observed isotopic abundance signatures. This includes measurement of light elements by secondary ion mass spectrometry (SIMS), analysis of additional heavy trace elements by accelerator mass spectrometry (AMS) and dynamic calculations of r-process nucleosynthesis with updated nuclear properties. Results obtained indicate: a) there is no evidence for the former presence of now extinct 26Al and 44Ti in our diamond samples other than what can be attributed to silicon carbide and other "impurities"; this does not offer support for a supernova (SN) origin but neither does it negate it; b) analysis by AMS of platinum in "bulk diamond" yields an overabundance of r-only 198Pt that at face value seems more consistent with the neutron burst than with the separation model for the origin of heavy trace elements in the diamonds, although this conclusion is not firm given analytical uncertainties; c) if the Xe-H pattern was established by an unadulterated r-process, it must have been a strong variant of the main r-process, which possibly could also account for the new observations in platinum., Workshop on Astronomy with Radioactvities VII; Publications of the Astronomical Society of Australia, accepted

Published

2012

16. Silver and palladium help unveil the nature of a second r-process

Author

Camilla Juul Hansen, Norbert Christlieb, Henrik Hartman, Hampus Nilsson, K. Farouqi, Bruno Leibundgut, Oliver Hallmann, Shinya Wanajo, Francesca Primas, and Karl-Ludwig Kratz

Subjects

Population II [Stars], general [Supernovae], chemistry.chemical_element, FOS: Physical sciences, Astrophysics, Molecular physics, Abundance (ecology), Naturvetenskap, atomic data, Halo [Galaxy], Solar and Stellar Astrophysics (astro-ph.SR), Physics, Astronomy and Astrophysics, Charged particle, Stars, Astrophysics - Solar and Stellar Astrophysics, chemistry, Space and Planetary Science, Yield (chemistry), Neutron number, abundances [Stars], r-process, chemical evolution, Low Mass, Natural Sciences, Palladium

Abstract

The rapid neutron-capture process, creating about half of the heaviest elements in the Solar System was believed to be unique. Many recent studies have shown that this does not include the formation of lighter elements (in particular 38 < Z < 48). Among those, palladium (Pd) and especially silver (Ag) are expected to be key indicators of a possible second r-process, but until recently they have been studied only in a few stars. Therefore we target Pd and Ag in a large sample of stars and compare these abundances to those of Sr, Y, Zr, Ba and Eu produced by the slow (s-) and rapid (r-) neutron-capture processes. Hereby we investigate the nature of the formation process of Ag and Pd. Through a homogeneous 1D LTE analysis of 71 stars we derive stellar abundances using the spectrum synthesis code MOOG, and MARCS model atmospheres. We calculate abundance ratio trends and compare the derived abundances to site-dependent yield predictions (low mass O-Ne-Mg cc SN, and parametrised high entropy winds), to extract characteristics of the second r-process. The abundance ratios of the heavy elements yield correlations and anti-correlations. These trends lead to clear indications of the existence of a second/weak r-process, responsible for the formation of Pd and Ag. By comparing to the model predictions, we find that the conditions under which this process takes place differ from the main r-process in needing lower neutron number densities, neutron-to-seed ratios, entropies and/or favour higher electron abundances. Our analysis confirms that Pd and Ag form via a r-process that differs from the main r-process, the main and weak s-processes, and charged particle freeze-outs. This process is efficiently working down to [Fe/H] = -3.3 (where our sample ends). Our results may indicate that a combination of these explosive sites is needed to explain the observationally-derived abundance patterns., 29 pages, 28 figures, 4 tables and online material

Published

2012

17. Decay of ther-process nuclides137,138,139Sb, and theA=130solarr-process abundance peak

Author

K. L. Kratz, A. A. Hecht, V. N. Fedosseev, J. Shergur, S. Hennrich, K. Farouqi, O. Arndt, W. B. Walters, A. Wöhr, B. Pfeiffer, N. Hoteling, C. J. Jost, and Ulli Köster

Subjects

Physics, Nuclear and High Energy Physics, Supernova, Nucleosynthesis, Double beta decay, Ionization, Analytical chemistry, Order (ring theory), r-process, Neutron, Nuclide

Abstract

Half-life (${T}_{1/2}$) and \ensuremath{\beta}-delayed neutron branching (${P}_{n}$) values of 492(25) ms and 49(8)$%$, 350(15) ms and 72(8)$%$, and 93(13) ms and 90(10)$%$ for the $r$-process nuclei ${}^{137,138,139}$Sb, respectively, have been measured at the CERN On-Line Isotope Mass Separator (ISOLDE) facility by counting \ensuremath{\beta}-delayed neutrons. More precise ${T}_{1/2}$ and ${P}_{n}$ values of 300(15) ms and 27(4)$%$, and 273(7) ms and 50(8)$%$ for ${}^{136,137}$Sn, respectively, have also been measured. The sources were prepared by using the selective ionization of Sb or Sn with the Resonance Ionization Laser Ion Source and the high-resolution mass separator. The new data for Sb isotopes are compared with calculated ${T}_{1/2}$ and ${P}_{n}$ values for both spherical and nonspherical shapes. The data have been incorporated into parametrized nucleosynthesis calculations of the $r$ process in high-entropy winds of core-collapse supernovae in order to study the properties of the $A$ $=$ 130 solar-system $r$-process abundance peak.

Published

2011

18. Co-Production of Light and Heavy p-, s- and r-Process Isotopes in the High-Entropy Wind of Core-Collapse Supernovae

Author

Karl-Ludwig Kratz, K. Farouqi, Ulrich Ott, and Oliver Hallmann

Subjects

Core (optical fiber), Nuclear physics, Physics, Supernova, Isotope, Collapse (topology), r-process

Published

2011

19. Half-lives and branchings forβ-delayed neutron emission for neutron-rich Co–Cu isotopes in ther-process

Author

K. L. Kratz, Hendrik Schatz, P. Santi, K. Farouqi, A. C. Morton, Peter Möller, R. R. Clement, A. Wöhr, Alfredo Estrade, Sean Liddick, Fernando Montes, B. Pfeiffer, O. Arndt, M. Steiner, P. Hosmer, William B. Walters, Andreas Stolz, Ani Aprahamian, B. E. Tomlin, M. Ouellette, P. Reeder, J. Pereira, W. F. Mueller, Alexander Lisetskiy, E. Pellegrini, and P. F. Mantica

Subjects

Nuclear physics, Nuclear reaction, Physics, Nuclear and High Energy Physics, Branching fraction, Neutron emission, Isotopes of copper, Analytical chemistry, r-process, Neutron, Radioactive decay, Dimensionless quantity

Abstract

The {beta} decays of very neutron-rich nuclides in the Co-Zn region were studied experimentally at the National Superconducting Cyclotron Laboratory using the NSCL {beta}-counting station in conjunction with the neutron detector NERO. We measured the branchings for {beta}-delayed neutron emission (P{sub n} values) for {sup 74}Co (18{+-}15%) and {sup 75-77}Ni (10{+-}2.8%, 14{+-}3.6%, and 30{+-}24%, respectively) for the first time, and remeasured the P{sub n} values of {sup 77-79}Cu, {sup 79,81}Zn, and {sup 82}Ga. For {sup 77-79}Cu and for {sup 81}Zn we obtain significantly larger P{sub n} values compared to previous work. While the new half-lives for the Ni isotopes from this experiment had been reported before, we present here in addition the first half-life measurements of {sup 75}Co (30{+-}11 ms) and {sup 80}Cu (170{sub -50}{sup +110} ms). Our results are compared with theoretical predictions, and their impact on various types of models for the astrophysical rapid neutron-capture process (r-process) is explored. We find that with our new data, the classical r-process model is better able to reproduce the A=78-80 abundance pattern inferred from the solar abundances. The new data also influence r-process models based on the neutrino-driven high-entropy winds in core collapse supernovae.

Published

2010

20. The Ubiquity of the Rapid Neutron-Capture Process

Author

Ian U. Roederer, Karl-Ludwig Kratz, John J. Cowan, Amanda I. Karakas, Jennifer Simmerer, Christopher Sneden, K. Farouqi, and Maria Lugaro

Subjects

Physics, 010308 nuclear & particles physics, Metallicity, chemistry.chemical_element, FOS: Physical sciences, Astronomy and Astrophysics, Yttrium, Astrophysics, Astrophysics - Astrophysics of Galaxies, 01 natural sciences, Spectral line, Supernova, Stars, Astrophysics - Solar and Stellar Astrophysics, chemistry, 13. Climate action, Space and Planetary Science, Nucleosynthesis, Astrophysics of Galaxies (astro-ph.GA), 0103 physical sciences, Lanthanum, Europium, 010303 astronomy & astrophysics, Solar and Stellar Astrophysics (astro-ph.SR)

Abstract

To better characterize the abundance patterns produced by the r-process, we have derived new abundances or upper limits for the heavy elements zinc (Zn), yttrium (Y), lanthanum (La), europium (Eu), and lead (Pb). Our sample of 161 metal-poor stars includes new measurements from 88 high resolution and high signal-to-noise spectra obtained with the Tull Spectrograph on the 2.7m Smith Telescope at McDonald Observatory, and other abundances are adopted from the literature. We use models of the s-process in AGB stars to characterize the high Pb/Eu ratios produced in the s-process at low metallicity, and our new observations then allow us to identify a sample of stars with no detectable s-process material. In these stars, we find no significant increase in the Pb/Eu ratios with increasing metallicity. This suggests that s-process material was not widely dispersed until the overall Galactic metallicity grew considerably, perhaps even as high as [Fe/H]=-1.4. We identify a dispersion of at least 0.5 dex in [La/Eu] in metal-poor stars with [Eu/Fe], Comment: Accepted for publication in the Astrophysical Journal. 25 pages, 13 figures

Published

2010

21. The Hamburg/ESO R-process enhanced star survey (HERES). IV. Detailed abundance analysis and age dating of the strongly r-process enhanced stars CS 29491-069 and HE 1219-0312

Author

Wolfgang Hayek, Karl Kratz, Norbert Christlieb, Kjell Eriksson, Andreas J. Korn, Paul S. Barklem, K. Farouqi, Timothy C. Beers, U. Wiesendahl, Vanessa Hill, B. Pfeiffer, Laboratoire de Cosmologie, Astrophysique Stellaire & Solaire, de Planétologie et de Mécanique des Fluides (CASSIOPEE), Université Nice Sophia Antipolis (... - 2019) (UNS), COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de la Côte d'Azur, and Université Côte d'Azur (UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Université Côte d'Azur (UCA)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Physics, FOS: Physical sciences, Thorium, chemistry.chemical_element, Astronomy and Astrophysics, Astrophysics, 7. Clean energy, 01 natural sciences, Abundance of the chemical elements, Spectral line, Supernova, Stars, Astrophysics - Solar and Stellar Astrophysics, chemistry, 13. Climate action, Space and Planetary Science, 0103 physical sciences, r-process, Radiometric dating, 010306 general physics, 010303 astronomy & astrophysics, Solar and Stellar Astrophysics (astro-ph.SR), Line (formation)

Abstract

We report on a detailed abundance analysis of two strongly r-process enhanced, very metal-poor stars newly discovered in the HERES project, CS 29491-069 ([Fe/H]=-2.51, [r/Fe]=+1.1) and HE 1219-0312 ([Fe/H]=-2.96, [r/Fe]=+1.5). The analysis is based on high-quality VLT/UVES spectra and MARCS model atmospheres. We detect lines of 15 heavy elements in the spectrum of CS 29491-069, and 18 in HE 1219-0312; in both cases including the Th II 4019 {\AA} line. The heavy-element abundance patterns of these two stars are mostly well-matched to scaled solar residual abundances not formed by the s-process. We also compare the observed pattern with recent high-entropy wind (HEW) calculations, which assume core-collapse supernovae of massive stars as the astrophysical environment for the r-process, and find good agreement for most lanthanides. The abundance ratios of the lighter elements strontium, yttrium, and zirconium, which are presumably not formed by the main r-process, are reproduced well by the model. Radioactive dating for CS 29491-069 with the observed thorium and rare-earth element abundance pairs results in an average age of 9.5 Gyr, when based on solar r-process residuals, and 17.6 Gyr, when using HEW model predictions. Chronometry seems to fail in the case of HE 1219-0312, resulting in a negative age due to its high thorium abundance. HE 1219-0312 could therefore exhibit an overabundance of the heaviest elements, which is sometimes called an "actinide boost".

Published

2009

22. Nucleosynthesis Modes in the High-Entropy-Wind of Type II Supernovae: Comparison of Calculations with Halo-Star Observations

Author

James W. Truran, Karl Kratz, Lyudmila Mashonkina, Friedrich-Karl Thielemann, B. Pfeiffer, K. Farouqi, and John J. Cowan

Subjects

Physics, Star (game theory), FOS: Physical sciences, Astronomy and Astrophysics, Astrophysics, Weak correlation, Supernova, Superposition principle, Astrophysics - Solar and Stellar Astrophysics, Space and Planetary Science, Nucleosynthesis, Weighted entropy, Halo, Partial correlation, Solar and Stellar Astrophysics (astro-ph.SR)

Abstract

While the high-entropy wind (HEW) of Type II supernovae remains one of the more promising sites for the rapid neutron-capture (r-) process, hydrodynamic simulations have yet to reproduce the astrophysical conditions under which the latter occurs. We have performed large-scale network calculations within an extended parameter range of the HEW, seeking to identify or to constrain the necessary conditions for a full reproduction of all r-process residuals N_{r,\odot}=N_{\odot}-N_{s,\odot} by comparing the results with recent astronomical observations. A superposition of weighted entropy trajectories results in an excellent reproduction of the overall N_{r,\odot}-pattern beyond Sn. For the lighter elements, from the Fe-group via Sr-Y-Zr to Ag, our HEW calculations indicate a transition from the need for clearly different sources (conditions/sites) to a possible co-production with r-process elements, provided that a range of entropies are contributing. This explains recent halo-star observations of a clear non-correlation of Zn and Ge and a weak correlation of Sr - Zr with heavier r-process elements. Moreover, new observational data on Ru and Pd seem to confirm also a partial correlation with Sr as well as the main r-process elements (e.g. Eu)., Comment: 15 pages, 1 table, 4 figures; To be published in the Astrophysical Journal Letters

Published

2009

23. The Astrophysical r-Process 50 Years after B[sup 2]FH

Author

K.-L. Kratz, K. Farouqi, L. I. Mashonkina, B. Pfeiffer, Livius Trache, and Sabin Stoica

Subjects

Physics, Solar System, Stars, Supernova, Nucleosynthesis, Nuclear data, r-process, Astrophysics, Stellar evolution, Abundance of the chemical elements

Abstract

Since the historical papers by Burbidge et al. and Cameron 50 years ago, it is generally accepted that half of the chemical elements above Fe are formed in explosive stellar scenarios by a rapid neutron‐capture process (the classical “r‐process”). Already from their essential ideas, it became clear that a correct modelling of this nucleosynthesis process requires both, the knowledge of various nuclear properties very far from stability and a detailed description of the astrophysical environments. However, it took about three decades, until in 1986 the first experimental nuclear‐physics data on the neutron‐magic r‐isotopes 80Zn and 130Cd could be obtained, which act as key “waiting points” in the respective A≃80 and 130 peaks of the Solar‐System (SS) r‐abundances (Nr,⊙). Since then, using steadily improved nuclear data, we have optimized our r‐process calculations to reproduce the present observables of the isotopic Nr,⊙ “residuals”, as well as the more recent elemental abundances in ultra‐metal‐poor, r‐process‐enriched halo stars. Concerning the latter observations, we support the basic idea about two different types of r‐processes. Based on our many years' experience with the site‐independent “waiting‐point approach”, we recently have extended our studies to fully dynamical network calculations for the most likely astrophysical r‐process scenario, i.e. the high‐entropy wind (HEW) of core‐collapse type II supernovae (SN II). Again, an excellent reproduction of all observables for the “main” r‐process has been achieved. However, a major difference is the nucleosynthesis origin of the lighter heavy elements in the 29⩽Z⩽45 mass region. Here, the HEW model predicts—instead of a “weak” neutron‐capture r‐process component—a primary rapid charged‐particle process. This may explain the recent observations of a non‐correlation of these elements with the heavier “main” r‐process elements.

Published

2008

24. Nucleosynthesis Modes in the High‐Entropy‐Wind Scenario of Type II Supernovae

Author

Lyudmila Mashonkina, B. Pfeiffer, John J. Cowan, K. L. Kratz, K. Farouqi, J. W. Truran, Christopher Sneden, and Friedrich-Karl Thielemann

Subjects

Physics, Galactic halo, Neutron star, Supernova, Nucleosynthesis, r-process, Astrophysics, Nuclear Experiment, Stellar evolution, Abundance of the chemical elements, Galaxy

Abstract

In an attempt to constrain the astrophysical conditions for the nucleosynthesis of the classical r‐process elements beyond Fe, we have performed large‐scale dynamical network calculations within the model of an adiabatically expanding high‐ entropy wind (HEW) of type II supernovae (SN II). A superposition of several entropy‐components (S) with model‐inherent weightings results in an excellent reproduction of the overall Solar System (SS) isotopic r‐process residuals (Nr,⊙), as well as the more recent observations of elemental abundances of metal‐poor, r‐process rich halo stars in the early Galaxy. For the heavy r‐process elements beyond Sn, our HEW model predicts a robust abundance pattern up to the Th, U r‐chronometer region. For the lighter neutron‐capture region, an S‐dependent superposition of (i) a normal α‐component directly producing stable nuclei, including s‐only isotopes, and (ii) a component from a neutron‐rich α‐freezeout followed by the rapid recapture of β‐delayed neutrons (βdnrpar; emitted ...

Published

2008

25. News from r-Process Nucleosynthesis: Consequences from the ESS to Early Stars

Author

K. Farouqi, K.-L. Kratz, null L. I. Mashonkina, B. Pfeiffer, F.-K. Thielemann, Roald Guandalini, Sara Palmerini, and Maurizio Busso

Subjects

Physics, Supernova, Stars, Nucleosynthesis, Metallicity, r-process, Astrophysics, Dynamical network, Stellar evolution

Abstract

The exact conditions for the supemova high‐entropy wind (HEW) as one of the favored sites for the rapid neutron‐capture (r‐) process still cannot be reproduced self‐consistently in present hydrodynamic astrophysical models. Therefore, we have performed large‐scale dynamical network calculations within a parameterized HEW model to constrain the necessary conditions for a full r‐process and to compare our results with recent observations. A model‐inherently weighted superposition of entropy trajectories results in an excellent reproduction of the overall Solar‐System isotopic abundances (Nr,⊙) of the “main” r‐process elements beyond Sn. For the lighter r‐elements in the range 26⩽Z⩽42, our HEW model supports earlier qualitative ideas about a multiplicity of nucleosynthetic processes leading to the total Nr,⊙ distribution. In the HEW scenario, these suggestions are quantified, and the origin of the missing primary process is confirmed to be a rapid charged‐particle process, thus excluding a “weak” neutron‐capture component. This explains the recent halo‐star observations of a Z‐dependent non‐correlation, respectively partial correlation of the lighter r‐elements with metallicity and/or enrichment of “main” r‐process elements.The exact conditions for the supemova high‐entropy wind (HEW) as one of the favored sites for the rapid neutron‐capture (r‐) process still cannot be reproduced self‐consistently in present hydrodynamic astrophysical models. Therefore, we have performed large‐scale dynamical network calculations within a parameterized HEW model to constrain the necessary conditions for a full r‐process and to compare our results with recent observations. A model‐inherently weighted superposition of entropy trajectories results in an excellent reproduction of the overall Solar‐System isotopic abundances (Nr,⊙) of the “main” r‐process elements beyond Sn. For the lighter r‐elements in the range 26⩽Z⩽42, our HEW model supports earlier qualitative ideas about a multiplicity of nucleosynthetic processes leading to the total Nr,⊙ distribution. In the HEW scenario, these suggestions are quantified, and the origin of the missing primary process is confirmed to be a rapid charged‐particle process, thus excluding a “weak” neutron‐cap...

Published

2008

26. Explorations of the r-Processes: Comparisons between Calculations and Observations of Low-Metallicity Stars

Author

Karl-Ludwig Kratz, Christopher Sneden, James W. Truran, K. Farouqi, John J. Cowan, and B. Pfeiffer

Subjects

Physics, Mass number, Solar System, Metallicity, Astrophysics (astro-ph), FOS: Physical sciences, Astronomy and Astrophysics, Astrophysics, Stars, Space and Planetary Science, Abundance (ecology), Neutron number, Neutron, Halo

Abstract

Abundances of heavier elements (barium and beyond) in many neutron-capture-element-rich halo stars accurately replicate the solar system r-process pattern. However, abundances of lighter neutron-capture elements in these stars are not consistent with the solar system pattern. These comparisons suggest contributions from two distinct types of r-process synthesis events -- a so called main r-process for the elements above the 2nd r-process peak and a weak r-process for the lighter neutron-capture elements. We have performed r-process theoretical predictions to further explore the implications of the solar and stellar observations. We find that the isotopic composition of barium and the elemental Ba/Eu abundance ratios in r-process-rich low metallicity stars can only be matched by computations in which the neutron densities are in the range 23< log n_n < 28, values typical of the main r-process. For r-process conditions that successfully generate the heavy element pattern extending down to A=135, the relative abundance of I129 produced in this mass region appears to be at least 90% of the observed solar value. Finally, in the neutron number density ranges required for production of the observed solar/stellar 3rd r-process-peak (A~200), the predicted abundances of inter-peak element hafnium (Z=72, A~180) follow closely those of 3rd-peak elements and lead. Hf, observable from the ground and close in mass number to the 3rd r-process-peak elements, might also be utilized as part of a new nuclear chronometer pair, Th/Hf, for stellar age determinations., 42 pages, 2 tables, 12 figures; To appear in the Astrophysical Journal

Published

2007

27. Production of intermediate-mass and heavy nuclei

Author

I. V. Panov, Raphael Hirschi, Nikolaj Thomas Zinner, Eduardo Bravo, Sergei Blinnikov, D. Mocelj, D. K. Nadyozhin, Peter Höflich, B. Pfeiffer, K.-L. Kratz, Matthias Liebendörfer, Carla Fröhlich, Friedrich-Karl Thielemann, I. Dillmann, K. Farouqi, Gabriel Martínez-Pinedo, Thomas Rauscher, Karlheinz Langanke, William Raphael Hix, Universitat Politècnica de Catalunya. Departament de Física i Enginyeria Nuclear, and Universitat Politècnica de Catalunya. GAA - Grup d'Astronomia i Astrofísica

Subjects

Astrofísica, Physics, Nuclear and High Energy Physics, Astrophysics::High Energy Astrophysical Phenomena, Astronomy, Astrophysics::Cosmology and Extragalactic Astrophysics, Astrophysics, Type II supernova, p-process, Supernova, Big Bang nucleosynthesis, Nucleosynthesis, Física::Astronomia i astrofísica [Àrees temàtiques de la UPC], Astrophysics::Solar and Stellar Astrophysics, r-process, Hypernova, Stellar evolution, Astrophysics::Galaxy Astrophysics

Abstract

Nucleosynthesis is the science related to all astrophysical processes which are responsible for the abundances of the elements and their isotopes in the universe. The astrophysical sites are the big bang and stellar objects. The working of nucleosynthesis processes is presented in a survey of events which act as abundance sources. For intermediate-mass and heavy elements, these are stellar evolution, type Ia and core collapse supernovae as well as hypernovae. We discuss successes and failures of existing processes and possible solutions via new (hitherto unknown) processes. Finally an analysis of their role is given in the puzzle to explain the evolution of the elemental and isotopic compositions found in galaxies, and especially the mixture found in the solar system. Different timescales due to the progenitor mass dependence of the endpoints of stellar evolution (type II supernova explosions — SNe II vs. planetary nebulae) or single vs. binary stellar systems (the latter being responsible for novae, type Ia supernovae — SNe Ia, or X-ray bursts) are the keys to understand galactic evolution. At very early times, the role of explosion energies of events, polluting pristine matter with a composition originating only from the big bang, might also play a role. We also speculate on the role of very massive stars not undergoing SN II explosions but rather causing “hypernovae” after the formation of a central black hole via core collapse.

Published

2007

28. Origin of Stellar Abundances in the early Galaxy

Author

F. Montes, T. C. Beers, J. Cowan, T. Elliot, K. Farouqi, R. Gallino, M. Heil, K.-L. Kratz, B. Pfeiffer, M. Pignatari, H. Schatz, Ricardo Alarcon, Philip L. Cole, Chaden Djalali, and Fernando Umeres

Subjects

Physics, Stars, Stellar nucleosynthesis, Abundance (ecology), Nucleosynthesis, Astronomy, r-process, Astrophysics, Stellar evolution, Abundance of the chemical elements, Galaxy

Abstract

Observations of metal‐poor stars in the last decade have revealed an abundance pattern that have recently been explained as the result of two nucleosynthesis processes, a strong r‐process that creates most of the Z⩾56 and some 38⩽Z⩽47 abundances and a light element primary process (LEPP) responsible for creating the remaining 38⩽Z⩽47 abundances and some small contribution to heavier elements. We review some of the current literature on the LEPP and show a derived abundance pattern as a function of mass number.

Published

2007

29. A HIGH-ENTROPY-WINDr-PROCESS STUDY BASED ON NUCLEAR-STRUCTURE QUANTITIES FROM THE NEW FINITE-RANGE DROPLET MODEL FRDM(2012)

Author

K. Farouqi, Karl-Ludwig Kratz, and Peter Möller

Subjects

Physics, Nuclear reaction, Nuclear Theory, Extrapolation, Nuclear structure, FOS: Physical sciences, Astronomy and Astrophysics, Nuclear Theory (nucl-th), Stars, Supernova, Astrophysics - Solar and Stellar Astrophysics, Space and Planetary Science, Nucleosynthesis, Entropy (information theory), r-process, Statistical physics, Solar and Stellar Astrophysics (astro-ph.SR)

Abstract

Theoretical studies of the nucleosynthesis origin of the heavy elements in our Solar System (S.S.) by the rapid neutron-capture process (r-process) still face the entwined uncertainties in the possible astrophysical scenarios and the nuclear-physics properties far from stability. In this paper we present results from the investigation of an r-process in the high-entropy wind (HEW) of core-collapse supernovae (here chosen as one of the possible scenarios for this nucleosynthesis process), using new nuclear-data input calculated in a consistent approach, for masses and $\beta$-decay properties from the new finite-range droplet model FRDM(2012). The accuracy of the new mass model is 0.56 MeV with respect to {\sc AME2003}, to which it was adjusted. We compare the new HEW r-process abundance pattern to the latest S.S. r-process residuals and to our earlier calculations with the nuclear-structure quantities based on FRDM(1992). Substantial overall and specific local improvements in the calculated pattern of the r-process between $A\simeq 110$ and $^{209}$Bi, as well as remaining deficiencies are discussed in terms of the underlying spherical and deformed shell structure far from stability., Comment: 8 pages, 4 figures

Published

2014

30. The r-, p-, and {$??$}p-Process

Author

Friedrich-Karl Thielemann, Thomas Rauscher, I. V. Panov, Gabriel Martínez-Pinedo, Iris Dillmann, A. Kelic-Heil, Carla Fröhlich, K. L. Kratz, Tobias Fischer, I. Korneev, K. Farouqi, Karlheinz Langanke, and Matthias Liebendörfer

Subjects

Physics, History, Astrophysics::High Energy Astrophysical Phenomena, Astronomy, Astrophysics, Type II supernova, 01 natural sciences, 7. Clean energy, ddc, Computer Science Applications, Education, Supernova, Neutron star, Photodisintegration, Nucleosynthesis, 0103 physical sciences, Astrophysics::Solar and Stellar Astrophysics, Neutrino, Nuclear Experiment, 010306 general physics, Gamma-ray burst, 010303 astronomy & astrophysics, Stellar evolution, Astrophysics::Galaxy Astrophysics

Abstract

The processes discussed in this review are three of the four nucleosynthesis processes involved in producing heavy nuclei beyond Fe (not counting the rp-process in X-ray bursts). Opposite to the fourth process (the s-process), which operates in stellar evolution during He- and C-burning, they are all related to explosive burning phases, (presumably) linked to core collapse supernova events of massive stars. The (classical) p-process is identified with explosive Ne/O-burning in outer zones of the progenitor star. It is intitiated by the passage of the supernova shock wave and acts via photodisintegration reactions like a spallation process which produces neighboring (proton-rich) isotopes from pre-existing heavy nuclei. The reproduction of some of the so-called lighter p-isotopes with A < 100 faces problems in this environment. The only recently discovered ?p-process is related to the innermost ejecta, the neutrino wind expelled from the hot proto-neutron star after core collapse in the supernova explosion. This neutrino wind is proton-rich in its early phase and reactions with neutrinos permit to overcome decay/reaction bottlenecks for the flow beyond the Fe-group, thus permitting the production of those p-isotopes, which face problems in the classical p-process scenario. The understanding of the r-process, being identified for a long time with rapid neutron captures ? and passing through nuclei far from stability ? is still experiencing major problems. These are on the one hand related to nuclear uncertainties far from stability (masses and half-lives), affecting the process speed and abundance peaks, on the other hand the site is still not definitely located, yet. Later neutron-rich, high entropy phases of the neutrino wind could permit its operation, other options include the ejection of very neutron-rich neutron star matter. Two different environments are required for a weak and a main/strong r-process, witnessed by observations of low metallicity stars.

Published

2010