Neutron capture cross sections of 69,71 Ga at n TOF EAR1

Similar documents
Recent neutron capture measurements at FZK

Measurement of the 62,63. Ni(n,γ) cross section at n_tof/cern

Measurement of the neutron capture cross section of gadolinium even isotopes relevant to Nuclear Astrophysics

Neutron capture cross sections on light nuclei

New measurement of the 62 Ni(n,γ) cross-section with n_tof at CERN

Experimental neutron capture data of 58 Ni from the CERN n TOF facility

PoS(NIC XII)184. Neutron capture on the s-process branch point nucleus 63 Ni

Neutron cross sections in stellar nucleosynthesis: study of the key isotope 25 Mg

The (n, α) reaction in the s-process branching point 59 Ni

The Origin of the Elements between Iron and the Actinides Probes for Red Giants and Supernovae

Neutron capture cross section of 25 Mg and its astrophysical implications

Current studies of neutron induced reactions regard essentially two mass regions, identified in the chart of nuclides: isotopes in the region from Fe

Studying Neutron-Induced Reactions for Basic Science and Societal Applications

This paper should be understood as an extended version of a talk given at the

From Notre Dame to National Labs: Cross sections at no charge!

Neutron-induced reactions on U and Th a new approach via AMS in collaboration with: KIT (Karlsruhe): F. Käppeler, I. Dillmann

Nuclear astrophysics of the s- and r-process

New Neutron-Induced Cross-Section Measurements for Weak s-process Studies

Reaction measurements on and with radioactive isotopes for nuclear astrophysics

Zach Meisel, PAN 2016

13 Synthesis of heavier elements. introduc)on to Astrophysics, C. Bertulani, Texas A&M-Commerce 1

Cross section measurement of 209 Bi(n,γ) 210 Bi g and s process abundance predictions in low-mass AGB stars

Fundamental Stellar Parameters. Radiative Transfer. Stellar Atmospheres. Equations of Stellar Structure

Nuclear Cross-Section Measurements at the Manuel Lujan Jr. Neutron Scattering Center

Neutron capture cross section of 139 La

Impact of Nuclear Reaction Uncertainties on AGB Nucleosynthesis Models

Astrophysical Nucleosynthesis

PoS(NIC XI)248. Cross section measurements of 103 Rh(p, γ) 104 Pd with the Karlsruhe 4πBaF 2 detector

PoS(NIC-IX)192. Measurement of the partial (n, γ) cross section to. 176 Lu m at s-process temperatures

Forschungszentrum Karlsruhe, Institut für Kernphysik, Postfach 3640, D Karlsruhe

Neutron capture cross section on Lu isotopes at DANCE

The r-process and the νp-process

Neutron capture measurements at the CERN neutron Time Of Flight (n_tof) facility. Nuclear astrophysics aspects

First measurements of the total and partial stellar cross section to the s-process branching-point 79 Se

Experimental Neutron Capture Measurements and Nuclear Theory Needs

BRANCHINGS, NEUTRON SOURCES AND POISONS: EVIDENCE FOR STELLAR NUCLEOSYNTHESIS

Evolution of Intermediate-Mass Stars

A new approach to the 176 Lu puzzle

STELLAR HEAVY ELEMENT ABUNDANCES AND THE NATURE OF THE R-PROCESSR. JOHN COWAN University of Oklahoma

Chapter 3: Neutron Activation and Isotope Analysis

PoS(NIC XII)118 Jan Glorius 1, J. Görres2, M. Knörzer3, R. Reifarth1, A. Sauerwein4, K. Sonnabend1, M. Wiescher2

Present and Future of Fission at n_tof

Activation Analysis. Characteristic decay mechanisms, α, β, γ Activity A reveals the abundance N:

NIM B. Measurement of (n, c) reaction cross sections at stellar energies for 58 Ni and 78 Se

Measurementof 7 Be(n,α) and 7 Be(n,p) cross sections for the Cosmological Li problem in

Determination of the boron content in polyethylene samples using the reactor Orphée

atomic structure practice test D) neutrons and protons B) empty space and has a small, positively charged nucleus C) neutron

Stellar neutron capture rates and the s process

Supernova events and neutron stars

14 Supernovae (short overview) introduc)on to Astrophysics, C. Bertulani, Texas A&M-Commerce 1

Nuclear Binding Energy

In the Beginning. After about three minutes the temperature had cooled even further, so that neutrons were able to combine with 1 H to form 2 H;

Perspectives on Nuclear Astrophysics

Nuclear Astrophysics - I

:Lecture 27: Stellar Nucleosynthesis. Cassieopia A

New experiments on neutron rich r-process Ge Br isotopes at the NSCL

Neutron induced reactions & nuclear cosmo-chronology. chronology. A Mengoni IAEA Vienna/CERN, Geneva

X-RAY BURSTS AND PROTON CAPTURES CLOSE TO THE DRIPLINE. The hydrogen-rich accreted envelopes of neutron stars in binary systems are

Heavy Element Nucleosynthesis. A summary of the nucleosynthesis of light elements is as follows

Nuclear Astrophysics

Rubidium, zirconium, and lithium production in massive AGB stars

The LUNA - MV project at the Gran Sasso Laboratory

The Possibility to Use Energy plus Transmutation Setup for Neutron Production and Transport Benchmark Studies

Simulating Gamma-Ray Telescopes in Space Radiation Environments with Geant4: Detector Activation

IB Test. Astrophysics HL. Name_solution / a) Describe what is meant by a nebula [1]

arxiv:nucl-th/ v1 14 Nov 2005

Stellar Interior: Physical Processes

Measurement of the n_tof beam profile in the second experimental area (EAR2) using a silicon detector

MAJOR NUCLEAR BURNING STAGES

H/He burning reactions on unstable nuclei for Nuclear Astrophysics

Neutrinos and Supernovae

The possibility to use energy plus transmutation set-up for neutron production and transport benchmark studies

nuclear states nuclear stability

Scientific goal in Nuclear Astrophysics is to explore:

Lecture 3: Big Bang Nucleosynthesis The First Three Minutes

ASTROFÍSICA NUCLEAR (EXPERIMENTAL)

Latest results from LUNA

Experimental Nuclear Astrophysics: Lecture 1. Chris Wrede National Nuclear Physics Summer School June 19 th, 2018

He-Burning in massive Stars

Institut d Astronomie et d Astrophysique, Université Libre de Bruxelle, Belgium

Section 12. Nuclear reactions in stars Introduction

Primer: Nuclear reactions in Stellar Burning

1 Stellar Abundances: The r-process and Supernovae

Be(n,a) and 7 Be(n,p) cross-sections measurement for the Cosmological Lithium problem at the n_tof facility at CERN

The CNO Bi-Cycle. Note that the net sum of these reactions is

Lecture 24: Testing Stellar Evolution Readings: 20-6, 21-3, 21-4

Conceptos generales de astrofísica

A Monte Carlo Simulation for Estimating of the Flux in a Novel Neutron Activation System using 252 Cf Source

Nuclear Burning in Astrophysical Plasmas

Today. Stars. Evolution of High Mass Stars. Nucleosynthesis. Supernovae - the explosive deaths of massive stars

ASTRONOMY 220C ADVANCED STAGES OF STELLAR EVOLUTION AND NUCLEOSYNTHESIS. Spring, 2013

Introduction Frankfurt Neutron Source at Stern-Gerlach-Zentrum FRANZ Development of new accelerator concepts for intense proton and ion beams. High in

The origin of heavy elements in the solar system

Direct measurement of the 17 O(p,α) 14 N reaction at energies of astrophysical interest at LUNA

Nucleosynthesis in core-collapse supernovae. Almudena Arcones

arxiv: v4 [astro-ph.sr] 1 Sep 2018

Monte Carlo Methods for Uncertainly Analysis Using the Bayesian R-Matrix Code SAMMY

Lecture 3: Big Bang Nucleosynthesis The First Three Minutes Last time:

Neutrino Physics and Nuclear Astrophysics: the LUNA-MV project at Gran Sasso

How Nature makes gold

Transcription:

EUROPEAN ORGANIZATION FOR NUCLEAR RESEARCH Proposal to the ISOLDE and Neutron Time-of-Flight Committee Neutron capture cross sections of 69,71 Ga at n TOF EAR1 May 31, 2016 K. Göbel 1, S. Fiebiger 1, D. Kurtulgil 1, F. Käppeler 2, C. Lederer 3, S.-J. Lonsdale 3, R. Reifarth 1, M. Weigand 1, P. Woods 3 and the n TOF Collaboration. 1 Goethe University Frankfurt, Germany 2 Karlsruhe Institute of Technology, Karlsruhe, Germany 3 University of Edinburgh, Edinburgh, United Kingdom Spokesperson: K. Göbel, goebel@physik.uni-frankfurt.de Technical coordinator: O. Aberle, oliver.aberle@cern.ch CERN-INTC-2016-023 / INTC-P-466 31/05/2016 Abstract: We propose to measure the neutron capture cross sections of the stable gallium isotopes 69 Ga and 71 Ga. These reactions are important during the astrophysical slow neutron capture process (s-process) which produces about half of the elements heavier than iron. The neutron capture cross sections of the two gallium isotopes not only determine the abundances of gallium, but also affect the abundances of the elements up to zirconium. The data from cross section measurements of Ga(n,γ) is scarce, and no data is available for the relevant energy range during the s-process. The Ga(n,γ) cross sections will be measured in the full energy range from 25 mev to about 500 kev at n TOF EAR-1. Requested protons: 4.0 10 18 protons on target Experimental Area: EAR1 1

1 Motivation The origin of heavy elements in the Universe is a fascinating and interdisciplinary challenge. The quest starts with an inventory: In our Solar System, the solar photosphere, the Earth, and meteorites reflect the chemical signature of the gas cloud in which the Sun formed. These abundances show the combined results of different nucleosynthesis contributions and the imprints of nuclear physics. Astrophysicists aim at reproducing the observed abundances by measuring nuclear reaction cross sections and by performing stellar simulations and nucleosynthesis calculations. Most of the elements heavier than iron are produced by the slow (s) and the rapid (r) neutron capture processes. The s-process takes place during stellar He and C burning phases with neutron densities between 10 8 and 10 10 cm 3. The reaction path closely follows the valley of stability since neutron capture times of typically ten years are much slower than most of the β- decay times of the involved nuclei (Figure 1) [1]. The s-process is composed of the weak and the main component [2]. The main differences lie in the neutron-to-seed ratios, the temperatures as well as the neutron densities. The main component of the Figure 1: The s-process path closely follows the valley of stability (black squares, stable isotopes in the chart of nuclei) since neutron capture time scales (typically ten years) are much slower than most of the β-decay time scales of the involved nuclei. s-process takes place at about 5 to 25 kev in low-mass asymptotic giant branch (AGB) stars and produces the nuclei with mass numbers above A 90 [2]. The weak component of the s-process takes place at about 90 kev in massive stars with M star > 8 M. The time-integrated neutron flux is lower compared to the main component producing nuclei with mass numbers A 90. 1.1 Neutron capture cross sections for the s-process Nucleosynthesis simulations for the s-process depend on stellar decay half-lives and stellar neutron capture cross sections. The Maxwellian Averaged Cross Section (MACS) gives the cross section averaged over the stellar neutron spectrum and is defined as < σ >= 2 π 1 (k B T ) 2 0 σ(e)e exp ( E k B T ) de where E is the neutron energy, k B is the Boltzmann constant and T is the temperature in the star. The MACS needs to be known for an energy range of 5 to 90 kev for the main and the weak s-processes. Hence, the excitation function has to be determined up to neutron energies of a few hundred kev by a time-of-flight measurement. 2

1.2 The weak s-process The weak s-process produces most of the s-process isotopes between iron and strontium. The neutron fluence in the weak s-process is too low to achieve reaction flow equilibrium, in contrast to the main s-process component. Therefore, a particular neutron capture cross section not only determines the abundance of the respective isotope (as in the case of the main component), but affects the abundances of all heavier isotopes as well. The uncertainties of the neutron capture cross sections of the weak s-process nuclei (60 A 90) are higher than the uncertainties of the main s-proces nuclei (A 90). Following the weak s-process path, the cumulated uncertainties affect all isotopes of the weak s-process, up to krypton and strontium, with possible minor contributions to the yttrium and zirconium abundances [3, 1]. Accurate predictions require the cross sections to be known with an accuracy of at least 5% for all involved nuclei in the weak s-process [4]. In the past years, new measurements of neutron capture cross sections of isotopes beyond iron significantly changed the predicted weak s-process distribution due to the propagation to heavier isotopes on the s-process path. Recent nucleosynthesis calculations showed an increase of s-process yields from nickel up to selenium. New cross sections of the nuclei 74 Ge, 75 As and 78 Se resulted in a higher production of germanium, arsenic, and selenium, thereby reducing the s-process yields of heavier elements by propagation [3]. 1.3 The case of gallium Gallium is mostly produced by the weak s-process in massive stars. Recent simulations [3] show that gallium is the most abundant s-element at the end of shell carbon burning. So far, there is only a time-of-flight measurement with a sample of natural gallium [5]. Other nuclei ( 81 Br, 75 As, 74 Ge) measured within the same experimental campaign show large deviations from more recent results [6]. For 71 Ga two discrepant results from integral measurements at 25 kev are published [7, 8]. The cross sections should be remeasured to solve the discrepancies. Data for carbon shell burning in massive stars at 90 kev are highly desired. Figure 2 shows the sensitivities to the propagation effect of cross section uncertainties of 69 Ga and 71 Ga during the weak s-process. Changing the stellar neutron capture cross section of one gallium isotope by 50% leads to changes of up to 20% for the s-abundances of all following isotopes. The abundances of 69 Ga and 71 Ga are changed by a factor of two. Accurate cross section data for neutron energies from 25 mev up to 500 kev are needed to provide a reliable prediction of the gallium and weak s-nuclei abundances. 2 Experimental Setup and Beam Time Request We propose to measure the neutron capture cross sections of 69 Ga and 71 Ga at Experimental Area 1 (EAR1) of the n TOF facility for the full neutron energy range from 25 mev up to a few hundred kev. We will use the C 6 D 6 detection setup at n TOF to detect the prompt γ-radiation of neutron capture events. The C 6 D 6 detectors show a very low sensitivity to scattered neutrons, an important background component. 3

RELATIVE CHANGE IN ABUNDANCE 2.2 2.0 1.8 1.6 1.4 1.2 1.0 0.8 0.6 60 70 80 90 100 110 120 130 MASS NUMBER A 69 Ga(n, ) x1.5 69 Ga(n, ) x0.5 RELATIVE CHANGE IN ABUNDANCE 2.0 1.8 1.6 1.4 1.2 1.0 0.8 0.6 60 70 80 90 100 110 120 130 MASS NUMBER A 71 Ga(n, ) x 1.5 71 Ga(n, ) x 0.5 Figure 2: Impact of the cross section uncertainties of the reactions 69 Ga(n,γ) (left panel) and 71 Ga(n,γ) (right panel) on the abundances of the weak s-process elements. Each of the samples will consist of 1 gram, with an isotopic enrichment of 99.6% for 69 Ga and 99.8% for 71 Ga. We will provide cylindrical samples with a diameter of 2 cm. Figures 3 and 4 show the expected count rate for the C 6 D 6 detection setup for the 69 Ga and 71 Ga samples with 1.6 10 18 protons on the spallation target. We used the evaluated neutron capture cross sections of ENDF/B-VII [9] for the calculations. The results are shown for a resolution of 5000 bins per energy decade, which is needed to perform a resonance shape analysis. We compare the results to the background level obtained from the germanium measurements performed at n TOF in 2015 [10]. We expect the background level to be lower in the case of gallium since the ratio of the neutron scattering cross section and the neutron capture cross section is lower than in the case of germanium. We will normalize the cross section using the saturated resonance technique with a gold sample of the same size as the gallium samples. We will study the background by recording runs without a sample in the beam. We will measure the background due to sample scattered neutrons with a carbon sample, which has a very high neutron scattering to capture ratio. The background and normalization measurements require 0.8 10 18 protons. Sample specifications and the requested number of protons are listed in Table 1. 3 Summary The neutron capture cross sections of the stable gallium isotopes 69 Ga and 71 Ga determine the abundances of the elements up to zirconium, which are produced during the weak s- process. So far, only data from integral measurements is available for 71 Ga for the energy range of the main s-process. Data for the weak s-process is highly desired. We propose to measure the neutron capture cross sections for 69 Ga and 71 Ga at n TOF EAR-1. We will use the C 6 D 6 detection setup at n TOF to detect the prompt γ-radiation of neutron capture events. We request 4.0 10 18 protons to measure the neutron capture cross sections in an energy range from 25 mev to 500 kev. Summary of requested protons: 4.0 10 18 4

69 Ga COUNTS / 1.6 10 18 protons 10 6 10 5 10 4 10 3 10 2 10 background level 2.77 10-3 at/b, 5000 bins/dec 10-1 1 10 10 2 10 3 10 4 10 5 NEUTRON ENERGY (ev) Figure 3: Count rate estimates (red line) for 69 Ga. The sample characteristics are described in Table 1. The blue line shows the background level obtained from the germanium measurements performed at n TOF in 2015 [10]. 71 Ga COUNTS / 1.6 10 18 protons 10 6 10 5 10 4 10 3 10 2 10 background level 2.70 10-3 at/b, 5000 bins/dec 10-1 1 10 10 2 10 3 10 4 10 5 NEUTRON ENERGY (ev) Figure 4: Count rate estimates (red line) for 71 Ga. The sample characteristics are described in Table 1. The blue line shows the background level obtained from the germanium measurements performed at n TOF in 2015 [10]. 5

Sample Mass (g) Enrichment (%) Thickness (at/b) No. of Protons ( 10 18 ) 69 Ga 1 99.6 2.77 10 3 1.6 71 Ga 1 99.8 2.70 10 3 1.6 Au 0.2 C 0.2 Empty frame 0.4 Total 4.0 Table 1: Summary of samples and corresponding requested number of protons. Isotopic enrichment as quoted by ISOFLEX [11]. References [1] R. Reifarth, C. Lederer, and F. Käppeler. Journal of Physics G Nuclear Physics 41(5), 053101 (2014). [2] P. A. Seeger, W. A. Fowler, and D. D. Clayton. The Astrophysical Journal, Supplement 11, 121 (1965). [3] M. Pignatari et al.. The Astrophysical Journal 710, 1557 (2010). [4] Z. Y. Bao et al.. Atomic Data and Nuclear Data Tables 76, 70 (2000). [5] G. Walter. KfK Bericht 3706 (1984). [6] I. Dillmann, R. Plag, F. Käppeler, and T. Rauscher. In Proceeding of the workshop EFNUDAT Fast Neutrons - scientific workshop on neutron measurements, theory & applications, Geel, Belgium. [7] R. Anand, M. Jhingan, D. Bhattacharya, and E. Kondaiah. Nuovo Cimento 50A, 247 (1979). [8] G. Walter, H. Beer, F. Käppeler, G. Reffo, and F. Fabbri. Astronomy and Astrophysics 167, 186 (1986). [9] M. Chadwick et al.. Nuclear Data Sheets 112(12), 2887 (2011). Special Issue on ENDF/B-VII.1 Library. [10] Lederer, C. Private communication. [11] http://www.isoflex.com. 6

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback