Your search keyword '"Jennifer Fallis"' showing total 41 results

1. First measurement in the Gamow window of a reaction for the γ-process in inverse kinematics: 76Se(α,γ)80Kr

Author

G. Christian, Alison Laird, D. A. Hutcheon, A. Rojas, S. J. Quinn, Chris Ruiz, C. Akers, A. Spyrou, Patrick O'Malley, D. Connolly, Jennifer Fallis, Anna Simon, J. Riley, U. Hager, M. Williams, and A. Lennarz

Subjects

Physics, Nuclear and High Energy Physics, Work (thermodynamics), Future studies, Inverse kinematics, 010308 nuclear & particles physics, Abundance (chemistry), Branching points, 01 natural sciences, 7. Clean energy, lcsh:QC1-999, Nuclear physics, Cross section (physics), Valley of stability, 0103 physical sciences, Nuclide, 010306 general physics, lcsh:Physics

Abstract

The p-nuclei are the few stable nuclei heavier than iron on the neutron-deficient side of the valley of stability that cannot be produced through astrophysical neutron-capture reactions. The limited experimental data on reactions through which the p-nuclei might be produced leaves the origin of their production largely unknown. This work presents the first cross section measurements of the 76Se( α , γ )80Kr reaction. The rate of the time reversed reaction, 80Kr( γ , α )76Se, is one of the most uncertain of possible reactions which can occur at the 80Kr branching point on the γ-process photo-disintegration pathway. The reaction flow through 80Kr will directly affect the final abundance of the p-nuclide 78Kr. Experimental cross sections at two astrophysically relevant energies are reported and compared to cross sections calculated using Hauser-Feshbach codes talys , non-smoker , and smaragd . The success of these first ( α , γ ) cross section measurements performed in inverse kinematics in the energy region of the γ-process opens the door for future studies of reactions on radioactive γ-process nuclides.

Published

2020

2. A direct measurement of the 17O(a,g)21Ne reaction in inverse kinematics and its impact on heavy element production

Author

L. Buchmann, B. R. Fulton, N. Galinski, Jennifer Fallis, A. Chen, Jun Chen, B. Davids, C. Akers, S. Sjue, Uwe Greife, D. J. Mountford, S. Reeve, M. Williams, D. A. Hutcheon, C. Davis, L. Erikson, Marco Pignatari, Götz Ruprecht, Raphael Hirschi, Kelly Chipps, D. Howell, L. Martin, Chris Ruiz, D.F. Ottewell, M. Taggart, Urs Frischknecht, Laurelle Veloce, J. R. Brown, C. Aa. Diget, U. Hager, Arthur Choplin, Alison Laird, John D'Auria, S. P. Fox, M. A. Bentley, and A. St. J. Murphy

Subjects

Nuclear and High Energy Physics, Metallicity, FOS: Physical sciences, chemistry.chemical_element, nucl-ex, 7. Clean energy, 01 natural sciences, Nuclear physics, Reaction rate, Nucleosynthesis, 0103 physical sciences, Neutron, Nuclear Experiment (nucl-ex), 010306 general physics, Nuclear Experiment, Helium, Physics, 010308 nuclear & particles physics, Resonance, lcsh:QC1-999, Stars, Neutron capture, chemistry, 13. Climate action, lcsh:Physics, QB799

Abstract

During the slow neutron capture process in massive stars, reactions on light elements can both produce and absorb neutrons thereby influencing the final heavy element abundances. At low metallicities, the high neutron capture rate of 16-O can inhibit s-process nucleosynthesis unless the neutrons are recycled via the 17O(a,n)20Ne reaction. The efficiency of this neutron recycling is determined by competition between the 17O(a,n)20Ne and 17O(a,g)21Ne reactions. While some experimental data are available on the former reaction, no data exist for the radiative capture channel at the relevant astrophysical energies. The 17O(a,g)21Ne reaction has been studied directly using the DRAGON recoil separator at the TRIUMF Laboratory. The reaction cross section has been determined at energies between 0.6 and 1.6 MeV Ecm, reaching into the Gamow window for core helium burning for the first time. Resonance strengths for resonances at 0.63, 0.721, 0.81 and 1.122 MeV Ecm have been extracted. The experimentally based reaction rate calculated represents a lower limit, but suggests that significant s-process nucleosynthesis occurs in low metallicity massive stars., 7 pages, 5 figures

Published

2019

3. Study of the 7Be(α,γ)11C reaction with DRAGON for vp–process nucleosynthesis

Author

Annika Lennarz, A. C. Shotter, L. Kroll, A. Psaltis, Som Paneru, Uwe Greife, C. Marshall, G. Tenkila, Barry Davids, M. Lovely, D. A. Hutcheon, M. Luo, Chris Ruiz, J. F. Liang, C. R. Brune, J. Karpesky, A. Chen, Michael Williams, Jennifer Fallis, R. Giri, and D. Connolly

Subjects

Physics, History, Nucleosynthesis, Scientific method, Physical chemistry, Computer Science Applications, Education

Abstract

The production of the p–nuclei is one of the unsolved puzzles in nuclear astrophysics. A possible mechanism is the nucleosynthesis in the neutrino–driven winds of core–collapse supernovae (νp–process), but it carries uncertainties, mostly in the supernova dynamics and the nuclear physics input. The pp-chain breakout reaction 7Be(α,γ)11C, which occurs prior to the supernova explosion, was identified as an important link which can influence the nuclear flow of the z/p-process and the final abundances of the p-nuclei. Nevertheless, its reaction rate is poorly known over the relevant energy range (T=1.5-3 GK). To improve the 7Be(α,γ)11C rate for vp-process nucleosynthesis temperatures, the first measurement of the strengths of two important resonances with unknown strength was recently performed at TRIUMF. A radioactive 7Be beam (t1/2 = 53.24 d) beam and the DRAGON recoil separator were used. The experimental details and preliminary results for the resonance strengths will be discussed.

Published

2020

4. Direct measurement of resonance strengths inS34(α,γ)Ar38at astrophysically relevant energies using the DRAGON recoil separator

Author

Adam Mahl, D. A. Hutcheon, Jennifer Fallis, Alison Laird, G. Christian, Chris Ruiz, Luke E. Erikson, S. V. Ilyushkin, Barry Davids, Uwe Greife, C. Akers, U. Hager, D. Connolly, Patrick O'Malley, B. R. Fulton, and A. Chen

Subjects

Physics, Explosive material, 010308 nuclear & particles physics, Resonance, 01 natural sciences, 7. Clean energy, Bismuth germanate, Ion, Nuclear physics, chemistry.chemical_compound, Recoil, chemistry, Nucleosynthesis, 0103 physical sciences, Ionization chamber, Radiative transfer, 010306 general physics

Abstract

Background: Nucleosynthesis of mid-mass elements is thought to occur under hot and explosive astrophysical conditions. Radiative α capture on S34 has been shown to impact nucleosynthesis in several such conditions, including core and shell oxygen burning, explosive oxygen burning, and type Ia supernovae. Purpose: Broad uncertainties exist in the literature for the strengths of three resonances within the astrophysically relevant energy range (ECM=1.94-3.42MeV at T=2.2GK). Further, there are several states in Ar38 within this energy range which have not been previously measured. This work aimed to remeasure the resonance strengths of states for which broad uncertainty existed as well as to measure the resonance strengths and energies of previously unmeasured states. Methods: Resonance strengths and energies of eight narrow resonances (five of which had not been previously studied) were measured in inverse kinematics with the DRAGON facility at TRIUMF by impinging an isotopically pure beam of S34 ions on a windowless He4 gas target. Prompt γ emissions of de-exciting Ar38 recoils were detected in an array of bismuth germanate scintillators in coincidence with recoil nuclei, which were separated from unreacted beam ions by an electromagnetic mass separator and detected by a time-of-flight system and a multianode ionization chamber. Results: The present measurements agree with previous results. Broad uncertainty in the resonance strength of the ECM=2709keV resonance persists. Resonance strengths and energies were determined for five low-energy resonances which had not been studied previously, and their strengths were determined to be significantly weaker than those of previously measured resonances. Conclusions: The five previously unmeasured resonances were found not to contribute significantly to the total thermonuclear reaction rate. A median total thermonuclear reaction rate calculated using data from the present work along with existing literature values using the STARLIB rate calculator agrees with the NON-SMOKER statistical model calculation as well as the REACLIB and STARLIB library rates at explosive and nonexplosive oxygen-burning temperatures (T=3-4GK and T=1.5-2.7GK, respectively).

Published

2018

5. Direct measurement of astrophysically important resonances in K38(p,γ)Ca39

Author

A. Rojas, Devin Burke, D. A. Hutcheon, U. Hager, W. N. Catford, G. Christian, Barry Davids, Adam Mahl, C. Akers, Gavin Lotay, Chris Ruiz, A. Chen, D. Connolly, Jennifer Fallis, and X Sun

Subjects

Nuclear reaction, Physics, 010308 nuclear & particles physics, Astrophysics::High Energy Astrophysical Phenomena, Resonance, White dwarf, 7. Clean energy, 01 natural sciences, Spectral line, Nuclear physics, Recoil, 13. Climate action, Nucleosynthesis, 0103 physical sciences, Astrophysics::Solar and Stellar Astrophysics, Binary system, Nuclide, Nuclear Experiment, 010303 astronomy & astrophysics

Abstract

Background: Classical novae are cataclysmic nuclear explosions occurring when a white dwarf in a binary system accretes hydrogen-rich material from its companion star. Novae are partially responsible for the galactic synthesis of a variety of nuclides up to the calcium ( A ∼ 40 ) region of the nuclear chart. Although the structure and dynamics of novae are thought to be relatively well understood, the predicted abundances of elements near the nucleosynthesis endpoint, in particular Ar and Ca, appear to sometimes be in disagreement with astronomical observations of the spectra of nova ejecta. Purpose: One possible source of the discrepancies between model predictions and astronomical observations is nuclear reaction data. Most reaction rates near the nova endpoint are estimated only from statistical model calculations, which carry large uncertainties. For certain key reactions, these rate uncertainties translate into large uncertainties in nucleosynthesis predictions. In particular, the 38 K ( p , γ ) 39 Ca reaction has been identified as having a significant influence on Ar, K, and Ca production. In order to constrain the rate of this reaction, we have performed a direct measurement of the strengths of three candidate l = 0 resonances within the Gamow window for nova burning, at 386 ± 10 keV, 515 ± 10 keV, and 689 ± 10 keV. Method: The experiment was performed in inverse kinematics using a beam of unstable 38 K impinged on a windowless hydrogen gas target. The 39 Ca recoils and prompt γ rays from 38 K ( p , γ ) 39 Ca reactions were detected in coincidence using a recoil mass separator and a bismuth-germanate scintillator array, respectively. Results: For the 689 keV resonance, we observed a clear recoil- γ coincidence signal and extracted resonance strength and energy values of 120 + 50 − 30 ( stat . ) + 20 − 60 ( sys . ) meV and 679 + 2 − 1 ( stat . ) ± 1 ( sys . ) keV , respectively. We also performed a singles analysis of the recoil data alone, extracting a resonance strength of 120 ± 20 ( stat . ) ± 15 ( sys . ) meV, consistent with the coincidence result. For the 386 keV and 515 keV resonances, we extract 90 % confidence level upper limits of 2.54 meV and 18.4 meV, respectively. Conclusions: We have established a new recommended 38 K ( p , γ ) 39 Ca rate based on experimental information, which reduces overall uncertainties near the peak temperatures of nova burning by a factor of ∼ 250 . Using the rate obtained in this work in model calculations of the hottest oxygen-neon novae reduces overall uncertainties on Ar, K, and Ca synthesis to factors of 15 or less in all cases.

Published

2018

6. Nuclear Force Imprints Revealed on the Elastic Scattering of Protons with C10

Author

Barry Davids, G. Hackman, Gary D. Christian, Sofia Quaglioni, Jennifer Fallis, A. C. Shotter, A. T. Laffoley, C. Unsworth, Jérémy Dohet-Eraly, J.C. Lighthall, E. T. Rand, A. T. Gallant, A. Kumar, Guillaume Hupin, Petr Navrátil, Martín Alcorta, Angelo Calci, D. Miller, A. Rojas, Junji Tanaka, V. Bildstein, S. Ishimoto, J. S. Randhawa, Robert Roth, Isao Tanihata, Rituparna Kanungo, A. Sanetullaev, R. Krücken, and Baharak Hadinia

Subjects

Elastic scattering, Nuclear reaction, Physics, Quantum chromodynamics, Proton, 010308 nuclear & particles physics, Nuclear Theory, Strong interaction, General Physics and Astronomy, 01 natural sciences, Nuclear physics, Quantum mechanics, 0103 physical sciences, Nuclear force, Neutron, Nuclear drip line, Nuclear Experiment, 010306 general physics

Abstract

How does nature hold together protons and neutrons to form the wide variety of complex nuclei in the Universe? Describing many-nucleon systems from the fundamental theory of quantum chromodynamics has been the greatest challenge in answering this question. The chiral effective field theory description of the nuclear force now makes this possible but requires certain parameters that are not uniquely determined. Defining the nuclear force needs identification of observables sensitive to the different parametrizations. From a measurement of proton elastic scattering on ^{10}C at TRIUMF and ab initio nuclear reaction calculations, we show that the shape and magnitude of the measured differential cross section is strongly sensitive to the nuclear force prescription.

Published

2017

7. Study of the Ti44(α,p)V47 reaction and implications for core collapse supernovae

Author

Thierry Stora, D. J. Mountford, Gavin Lotay, T. Davinson, V. Margerin, Charles Wang, Alison Laird, Dorothea Schumann, Anu Kankainen, A. St. J. Murphy, Rugard Dressler, T. Stowasser, Jennifer Fallis, P. J. Woods, C. Seiffert, and C. D. Murphy

Subjects

Nuclear physics, Nuclear reaction, Physics, Nuclear and High Energy Physics, Stars, Supernova, Isotopes of vanadium, Neutron source, Spallation, Astrophysics, Ejecta, 7. Clean energy, Spallation Neutron Source

Abstract

The underlying physics triggering core collapse supernovae is not fully understood but observations of material ejected during such events helps to solve this puzzle. In particular, several satellite based γ-ray observations of the isotope 44Ti have been reported recently. Conveniently, the amount of this isotope in stellar ejecta is thought to depend critically on the explosion mechanism. The most influential reaction to the amount of 44Ti in supernovae is Ti44(α,p)V47. Here we report on a direct study of this reaction conducted at the REX-ISOLDE facility, CERN. The experiment was performed with a 44Ti beam at Elab = 2.16MeV/u, corresponding to an energy distribution, for reacting α-particles, centred on Ecm = 4.15 with a 1σ width of 0.23 MeV. This is, for the first time, well within the Gamow window for core collapse supernovae. The material from which the 44Ti beam was extracted originates from highly irradiated components of the SINQ spallation neutron source of the Paul Scherrer Institute. No yield above background was observed, enabling an upper limit for the rate of this reaction to be determined. This result is below expectation, suggesting that the Ti44(α,p)V47 reaction proceeds more slowly than previously thought. Implications for astrophysical events, and remnant age, are discussed. © 2014 The Authors.

Published

2014

8. Nuclear astrophysics measurements with DRAGON

Author

Jennifer Fallis

Subjects

Nuclear physics, Physics, Nuclear and High Energy Physics, Inverse kinematics, Radiative capture, Nuclear astrophysics, Measure (physics), Physics::Accelerator Physics, Physical and Theoretical Chemistry, Nuclear Experiment, Condensed Matter Physics, Atomic and Molecular Physics, and Optics

Abstract

The DRAGON facility in ISAC-I at TRIUMF was designed to measure radiative capture reactions of importance for astrophysics in inverse kinematics. This work will provide a short summary of experiments to date, outline the status of the separator and its detectors, as well as discuss recent developments.

Published

2013

9. Measurement of radiative proton capture onF18and implications for oxygen-neon novae reexamined

Author

L. Buchmann, Alison Laird, U. Hager, Chris Ruiz, Luke E. Erikson, Jennifer Fallis, D. W. Bardayan, Barry Davids, A. Spyrou, C. Akers, L. Martin, D.F. Ottewell, B. R. Fulton, G. Christian, D. A. Hutcheon, A. St. J. Murphy, K. J. Nelson, and A. Rojas

Subjects

Physics, Proton, 010308 nuclear & particles physics, Continuum (design consultancy), chemistry.chemical_element, Resonance, Nova (laser), 01 natural sciences, Nuclear physics, Reaction rate, Neon, chemistry, 0103 physical sciences, Radiative transfer, Atomic physics, 010306 general physics, Order of magnitude

Abstract

Background: The rate of the F18(p,γ)Ne19 reaction affects the final abundance of the radioisotope F18 ejected from novae. This nucleus is important as its abundance is thought to significantly influence the first-stage 511-keV and continuum γ-ray emission in the aftermath of novae. No successful measurement of this reaction existed prior to this work, and the rate used in stellar models had been calculated based on incomplete information from contributing resonances. Purpose: Of the two resonances thought to provide a significant contribution to the astrophysical reaction rate, located at Ec.m.=330 and 665 keV, the former has a radiative width estimated from the assumed analog state in the mirror nucleus, F19, while the latter resonance does not have an analog state assignment, resulting in an arbitrary radiative width being assumed. As such, a direct measurement was needed to establish what role this resonance plays in the destruction of F18 at nova temperatures. This paper extends and takes the place of a previous Letter which reported the strength of the Ec.m.=665 keV resonance. Method: The DRAGON recoil separator was used to directly measure the strength of the important 665-keV resonance in this reaction, in inverse kinematics, by observing Ne19 reaction products. A radioactive F18 beam was provided by the ISAC facility at TRIUMF. R-matrix calculations were subsequently used to evaluate the significance of the results at astrophysical energies. Results: We report the direct measurement of the F18(p,γ)Ne19 reaction with the reevaluation of several detector efficiencies and the use of an updated Ne19 level scheme in the reaction rate analysis. The strength of the 665-keV resonance (Ex=7.076 MeV) is found to be an order of magnitude weaker than currently assumed in nova models. An improved analysis of the previously reported data is presented here, resulting in a slightly different value for the resonance strength. These small changes, however, do not alter the primary conclusions. Conclusions: Reaction rate calculations definitively show that the 665-keV resonance plays no significant role in the destruction of F18 at nova temperatures.

Published

2016

10. Direct Measurement of the AstrophysicalK38(p,γ)Ca39Reaction and Its Influence on the Production of Nuclides toward the End Point of Nova Nucleosynthesis

Author

Aa Chen, D. Connolly, W. N. Catford, X Sun, Jennifer Fallis, Adam Mahl, DS Burke, D. A. Hutcheon, GJ Lotay, G. Christian, U. Hager, Chris Ruiz, A. Rojas, Barry Davids, and C. Akers

Subjects

Physics, 010308 nuclear & particles physics, General Physics and Astronomy, Resonance, Nanotechnology, Nova (laser), 7. Clean energy, 01 natural sciences, Ionizing radiation, Nuclear physics, Reaction rate, Orders of magnitude (time), 13. Climate action, Nucleosynthesis, 0103 physical sciences, Nuclide, 010306 general physics, P system

Abstract

We have performed the first direct measurement of the 38Kðp; γÞ39Ca reaction using a beam of radioactive 38K. A proposed l ¼ 0 resonance in the 38K þ p system has been identified at 679(2) keV with an associated strength of 120 þ50 −30 meV. Upper limits of 1.16 (3.5) and 8.6 (26) meV at the 68% (95%) confidence level were also established for two further expected l ¼ 0 resonances at 386 and 515 keV, respectively. The present results have reduced uncertainties in the 38Kðp; γÞ39Ca reaction rate at temperatures of 0.4 GK by more than 2 orders of magnitude and indicate that Ar and Ca may be ejected in observable quantities by oxygen-neon novae. However, based on the newly evaluated rate, the 38Kðp; γÞ39Ca path is unlikely to be responsible for the production of Ar and Ca in significantly enhanced quantities relative to solar abundances.

Published

2016

11. Measurement of lifetimes inMg23

Author

G. Christian, Chris Ruiz, S. T. Nielsen, C. Unsworth, A. B. Garnsworthy, Jennifer Fallis, A. Rojas, A. Sanetullaev, A. J. Radich, R. Churchman, C. J. Pearson, Christopher Wrede, L. J. Evitts, J.C. Lighthall, D. Miller, Barry Davids, G. Hackman, C. R. Nobs, Oliver S. Kirsebom, A. Cheeseman, N. Galinski, M. M. Rajabali, D. S. Cross, P. Machule, P. C. Bender, and Steffen Ketelhut

Subjects

Physics, 010308 nuclear & particles physics, Astrophysics::High Energy Astrophysical Phenomena, Attenuation, 0103 physical sciences, Monte Carlo method, Atomic physics, 010306 general physics, 01 natural sciences, Line (formation)

Abstract

Several lifetimes in $^{23}\text{Mg}$ have been determined for the first time using the Doppler-shift attenuation method. A Monte Carlo simulation code has been written to model the $\ensuremath{\gamma}$-ray line shape. An upper limit of $\ensuremath{\tau}l12$ fs at the 95% C.L. has been obtained for the astrophysically important 7787 keV state.

Published

2016

12. Measurement of radiative capture resonance energies with an extended gas target

Author

Barry Davids, D. A. Hutcheon, S. Reeve, John D'Auria, L. Martin, Chris Ruiz, Jennifer Fallis, D.F. Ottewell, A. Rojas, and U. Hager

Subjects

Physics, Nuclear and High Energy Physics, 010308 nuclear & particles physics, Radiative capture, Detector, Gamma ray, Resonance, 7. Clean energy, 01 natural sciences, Position (vector), 0103 physical sciences, Nuclear astrophysics, Atomic physics, 010306 general physics, Instrumentation, Energy (signal processing)

Abstract

The DRAGON facility for the study of radiative capture reactions has an extended gas target, surrounded by an array of BGO detectors. The distribution of detected gamma rays amongst the segmented array permits an estimate of the reaction position and consequently of the resonance energy. We report a study of the technique, using the 24 Mg(p, γ ) 25 Al reaction. Energy determination to better than 0.5% has been demonstrated.

Published

2012

13. Measurement of the p-process branching point reaction 76Se(alpha,gamma)80Kr in inverse kinematics with Dragon

Author

Jennifer Fallis

Subjects

Nuclear physics, Physics, Inverse kinematics, Alpha (ethology), Branching points, p-process

Published

2015

14. Inverse Kinematic Study of theAl26g(d,p)Al27Reaction and Implications for Destruction ofAl26in Wolf-Rayet and Asymptotic Giant Branch Stars

Author

Jennifer Fallis, Philip Woods, J. A. Tostevin, A. Rojas, G. Christian, Barry Davids, D. T. Doherty, Gavin Lotay, Chris Ruiz, V. Margerin, Thomas Davinson, D. Howell, D. J. Mountford, Marialuisa Aliotta, and Oliver S. Kirsebom

Subjects

Physics, Reaction rate, Stars, Wolf–Rayet star, Hydrogen, chemistry, General Physics and Astronomy, Resonance, chemistry.chemical_element, Asymptotic giant branch, Emission spectrum, Astrophysics, Atmospheric temperature range

Abstract

In Wolf-Rayet and asymptotic giant branch (AGB) stars, the (26g)Al(p,γ)(27)Si reaction is expected to govern the destruction of the cosmic γ-ray emitting nucleus (26)Al. The rate of this reaction, however, is highly uncertain due to the unknown properties of key resonances in the temperature regime of hydrogen burning. We present a high-resolution inverse kinematic study of the (26g)Al(d,p)(27)Al reaction as a method for constraining the strengths of key astrophysical resonances in the (26g)Al(p,γ)(27)Si reaction. In particular, the results indicate that the resonance at E(r)=127 keV in (27)Si determines the entire (26g)Al(p,γ)(27)Si reaction rate over almost the complete temperature range of Wolf-Rayet stars and AGB stars.

Published

2015

15. Measurement ofNa23(α,p)Mg26at Energies Relevant toAl26Production in Massive Stars

Author

Alison Laird, A. Rojas, N. de Séréville, M. Shen, Alan Shotter, N. Galinski, G. Christian, Chris Ruiz, B. R. Fulton, Jennifer Fallis, Thomas Davinson, J. R. Tomlinson, Barry Davids, S. P. Fox, C. Akers, M. A. Bentley, and Martín Alcorta

Subjects

Physics, Nuclear physics, Reaction rate, Solar System, Cross section (physics), Stars, Range (particle radiation), Nucleosynthesis, General Physics and Astronomy, Sensitivity (control systems), 7. Clean energy, Galaxy

Abstract

26Al is an important radioisotope in astrophysics that provides evidence of ongoing nucleosynthesis in the Galaxy. The 23Na(α, p)26Mg reaction has been identified by a sensitivity study as being one of the most important reactions for the production of 26Al in the convective C/Ne burning shell of massive stars. Owing to large uncertainties in previous experimental data, model calculations are used for the reaction rate of 23Na(α, p)26Mg in this sensitivity study. Current experimental data suggest a reaction rate a factor of ∼40 higher than model calculations. However, a new measurement of this reaction cross section has been made in inverse kinematics in the energy range E(c.m.)=1.28-3.15 MeV at TRIUMF, and found to be in reasonable agreement with the model calculation. A new reaction rate is calculated and tight constraints on the uncertainty in the production of 26Al, due to this reaction, are determined.

Published

2015

16. Constraining the Astrophysical S Factor of the 3He(α,γ)7Be Reaction

Author

G. Christian, Chris Ruiz, C. Akers, R. Yaniv, M. Carmona-Gallardo, Z. Yungreis, B. R. Fulton, Y. Nir-El, M. J. G. Borge, U. Hager, A. Rojas, D. A. Hutcheon, O. Aviv, G. Haquin, Barry Davids, Jennifer Fallis, Olof Tengblad, S. Sjue, Michael Hass, B. S. Nara Singh, and D.F. Ottewell

Subjects

Nuclear physics, International research, Physics, Nuclear reaction, Light nucleus, Scaling law, S-factor, Calculation methods

Abstract

ITO International Research Center, on the campus of the University of Tokyo, June 1 to 6, 2014; http://ribf.riken.jp/ARIS2014/index.html

Published

2015

17. Evidence of Soft Dipole Resonance inLi11with Isoscalar Character

Author

C. Unsworth, N. Galinski, R. Krücken, J. P. Fortin, P. C. Bender, P. Voss, Gaute Hagen, Toshio Suzuki, G. Hackman, A. Chen, Gustav R. Jansen, Isao Tanihata, T. Roger, J. Lighthall, T. Myo, Takaharu Otsuka, A. Sanetullaev, Barry Davids, D. Miller, Corina Andreoiu, Z. Wang, A. C. Shotter, Ian J. Thompson, M. Keefe, A. T. Gallant, A. Rojas, Shigeru Ishimoto, Jennifer Fallis, E. McNeice, J. Purcell, R. Kanungo, J. S. Randhawa, H. Savajols, Baharak Hadinia, Junki Tanaka, and P. E. Garrett

Subjects

Physics, Isoscalar, Nuclear Theory, General Physics and Astronomy, Resonance, Inelastic scattering, Nuclear physics, Dipole, Coupled cluster, Ab initio quantum chemistry methods, Physics::Accelerator Physics, Born approximation, Atomic physics, Excitation

Abstract

The first conclusive evidence of a dipole resonance in 11Li having isoscalar character observed from inelastic scattering with a novel solid deuteron target is reported. The experiment was performed at the newly commissioned IRIS facility at TRIUMF. The results show a resonance peak at an excitation energy of 1.03±0.03 MeV with a width of 0.51±0.11 MeV (FWHM). The angular distribution is consistent with a dipole excitation in the distorted-wave Born approximation framework. The observed resonance energy together with shell model calculations show the first signature that the monopole tensor interaction is important in 11Li. The first ab initio calculations in the coupled cluster framework are also included.

Published

2015

18. Mass measurements of neutron-rich Rb and Sr isotopes

Author

A. Bader, Jens Dilling, Vanessa V. Simon, M.C. Simon, U. Chowdhury, A. Lennarz, Jennifer Fallis, T.D. Macdonald, Maxime Brodeur, A. Chaudhuri, Daniel Lascar, A. A. Kwiatkowski, B. E. Schultz, S. Seeraji, Aaron Gallant, K. G. Leach, A. Grossheim, R. Klawitter, and J. Pearkes

Subjects

Physics, Isotope, 010308 nuclear & particles physics, FOS: Physical sciences, Mass spectrometry, 01 natural sciences, 7. Clean energy, Atomic mass, Ion, Nuclear physics, Nucleosynthesis, 0103 physical sciences, Neutron, Präzisionsexperimente - Abteilung Blaum, Atomic physics, Nuclear Experiment (nucl-ex), 010306 general physics, Nuclear Experiment, Excitation

Abstract

We report on the mass measurements of several neutron-rich $\mathrm{Rb}$ and $\mathrm{Sr}$ isotopes in the $A \approx 100$ region with the TITAN Penning-trap mass spectrometer. Using highly charged ions in the charge state $q=10+$, the masses of $^{98,99}\mathrm{Rb}$ and $^{98-100}\mathrm{Sr}$ have been determined with a precision of $6 - 12\ \mathrm{keV}$, making their uncertainty negligible for r-process nucleosynthesis network calculations. The mass of $^{101}\mathrm{Sr}$ has been determined directly for the first time with a precision eight times higher than the previous indirect measurement and a deviation of $3\sigma$ when compared to the Atomic Mass Evaluation. We also confirm the mass of $^{100}\mathrm{Rb}$ from a previous measurement. Furthermore, our data indicates the existance of a low-lying isomer with $80\ \mathrm{keV}$ excitation energy in $^{98}\mathrm{Rb}$. We show that our updated mass values lead to minor changes in the r-process by calculating fractional abundances in the $A\approx 100$ region of the nuclear chart., Comment: 8 pages, 5 figures

Published

2015

19. Beam suppression of the DRAGON recoil separator for 3He()7Be

Author

N. Galinski, L. Buchmann, B. R. Fulton, D. Howell, P. Adsley, Alison Laird, S. Sjue, Götz Ruprecht, M. Carmona-Gallardo, L. Martin, D.F. Ottewell, Chris Ruiz, Barry Davids, Michael Hass, Jennifer Fallis, D. A. Hutcheon, S. Triambak, B. S. Nara Singh, S. Reeve, and U. Hager

Subjects

Physics, Nuclear physics, Nuclear reaction, Nuclear and High Energy Physics, Cross section (physics), Isotope, Separator (oil production), Isotopes of beryllium, Instrumentation, Electromagnetic radiation, Beam (structure), Recoil separator

Abstract

Preliminary studies in preparation for an absolute cross-section measurement of the radiative capture reaction 3 He( α , γ ) 7 Be with the DRAGON recoil separator have demonstrated beam suppression > 10 14 at the 90% confidence level. A measurement of this cross section by observation of 7 Be recoils at the focal plane of the separator should be virtually background free.

Published

2013

20. TheC12(O16,γSi28)radiative capture reaction at sub-barrier energies

Author

D. Lebhertz, Götz Ruprecht, S. Courtin, U. Hager, Jennifer Fallis, F. Haas, D. G. Jenkins, Alain Goasduff, D.F. Ottewell, P.-A. Amandruz, Chris Ruiz, C. Davis, and D. A. Hutcheon

Subjects

Physics, Nuclear and High Energy Physics, Radiative capture, Atomic physics

Published

2014

21. Design and commissioning of a timestamp-based data acquisition system for the DRAGON recoil mass separator

Author

Jennifer Fallis, G. Christian, Chris Ruiz, Dave Hutcheon, D. Connolly, C. Akers, and K. Olchanski

Subjects

Physics, Nuclear and High Energy Physics, Physics - Instrumentation and Detectors, Real-time computing, Separator (oil production), FOS: Physical sciences, Reconstruction algorithm, Instrumentation and Detectors (physics.ins-det), Coincidence, Recoil, Data acquisition, Astrophysics - Solar and Stellar Astrophysics, Radiative transfer, Nuclear fusion, Timestamp, Nuclear Experiment (nucl-ex), Nuclear Experiment, Solar and Stellar Astrophysics (astro-ph.SR)

Abstract

The DRAGON recoil mass separator at TRIUMF exists to study radiative proton and alpha capture reactions, which are important in a variety of astrophysical scenarios. DRAGON experiments require a data acquisition system that can be triggered on either reaction product ($\gamma$ ray or heavy ion), with the additional requirement of being able to promptly recognize coincidence events in an online environment. To this end, we have designed and implemented a new data acquisition system for DRAGON which consists of two independently triggered readouts. Events from both systems are recorded with timestamps from a $20$ MHz clock that are used to tag coincidences in the earliest possible stage of the data analysis. Here we report on the design, implementation, and commissioning of the new DRAGON data acquisition system, including the hardware, trigger logic, coincidence reconstruction algorithm, and live time considerations. We also discuss the results of an experiment commissioning the new system, which measured the strength of the $E_{\text{c}.\text{m}.} = 1113$ keV resonance in the $^{20}$Ne$\left(p, \gamma \right)^{21}$Na radiative proton capture reaction., Comment: 11 pages, 7 figures, accepted for publication in EPJ A "tools for experiment and theory"

Published

2014

22. BETA-DELAYED NEUTRON SPECTROSCOPY USING TRAPPED IONS

Author

R. E. Segel, Bruce J. Zabransky, J. Van Schelt, C. M. Deibel, Marisa Pedretti, R. M. Yee, Gang Li, Daniel Lascar, John P. Greene, P. F. Bertone, Jason A. Clark, S. Gulick, Eric B. Norman, Shane Caldwell, A. F. Levand, Jennifer Fallis, K. S. Sharma, Matthew Sternberg, Guy Savard, N. D. Scielzo, and F. Buchinger

Subjects

Materials science, Radiochemistry, Beta (finance), Spectroscopy, Delayed neutron, Ion

Published

2013

23. Constraining nova observables: Direct measurements of resonance strengths in33S(p,γ)34Cl

Author

K. J. Nelson, D.F. Ottewell, Uwe Greife, G. Lian, W. Liu, Shawn Bishop, B. R. Fulton, C. Herlitzius, Jason A. Clark, A. Chen, D. A. Hutcheon, Z. H. Li, B. Davids, S. Sjue, E. Li, P. D. Parker, Jennifer Fallis, Alison Laird, Y. Wang, L. Martin, Anuj Parikh, Christof Vockenhuber, U. Hager, B. Guo, Jordi José, P. F. Bertone, L. Buchmann, C. M. Deibel, John D'Auria, S. Reeve, G. Christian, Chris Ruiz, A. Rojas, Christopher Wrede, and K. Setoodehnia

Subjects

Nuclear reaction, Physics, Nuclear and High Energy Physics, 010308 nuclear & particles physics, Presolar grains, Resonance, Observable, Nova (laser), 01 natural sciences, 7. Clean energy, Nuclear physics, 13. Climate action, Nucleosynthesis, 0103 physical sciences, Orders of magnitude (data), Atomic physics, 010306 general physics, Energy (signal processing)

Abstract

The ${}^{33}$S($p,\ensuremath{\gamma}$)${}^{34}$Cl reaction is important for constraining predictions of certain isotopic abundances in oxygen-neon novae. Models currently predict as much as 150 times the solar abundance of ${}^{33}$S in oxygen-neon nova ejecta. This overproduction factor may vary by orders of magnitude due to uncertainties in the ${}^{33}$S($p,\ensuremath{\gamma}$)${}^{34}$Cl reaction rate at nova peak temperatures. Depending on this rate, ${}^{33}$S could potentially be used as a diagnostic tool for classifying certain types of presolar grains. Better knowledge of the ${}^{33}$S($p,\ensuremath{\gamma}$)${}^{34}$Cl rate would also aid in interpreting nova observations over the S-Ca mass region and contribute to the firm establishment of the maximum endpoint of nova nucleosynthesis. Additionally, the total S elemental abundance which is affected by this reaction has been proposed as a thermometer to study the peak temperatures of novae. Previously, the ${}^{33}$S($p,\ensuremath{\gamma}$)${}^{34}$Cl reaction rate had only been studied directly down to resonance energies of 432 keV. However, for nova peak temperatures of $0.2--0.4$ GK there are seven known states in ${}^{34}$Cl both below the 432-keV resonance and within the Gamow window that could play a dominant role. Direct measurements of the resonance strengths of these states were performed using the DRAGON (Detector of Recoils And Gammas of Nuclear reactions) recoil separator at TRIUMF. Additionally two new states within this energy region are reported. Several hydrodynamic simulations have been performed, using all available experimental information for the ${}^{33}$S($p,\ensuremath{\gamma}$)${}^{34}$Cl rate, to explore the impact of the remaining uncertainty in this rate on nucleosynthesis in nova explosions. These calculations give a range of $\ensuremath{\approx}$20--150 for the expected ${}^{33}$S overproduction factor, and a range of $\ensuremath{\approx}$100--450 for the ${}^{32}$S/${}^{33}$S ratio expected in ONe novae.

Published

2013

24. Strength of theEc.m.=1113keV resonance in20Ne(p,γ)21Na

Author

C. Akers, D. Connolly, G. Christian, D. A. Hutcheon, Jennifer Fallis, and Chris Ruiz

Subjects

Physics, Nuclear and High Energy Physics, 010308 nuclear & particles physics, Radiative capture, Resonance, 01 natural sciences, Omega, Resonance strength, Nuclear physics, Recoil, 0103 physical sciences, Production (computer science), Atomic physics, 010306 general physics

Abstract

The ${}^{20}$Ne${(p,\ensuremath{\gamma})}^{21}$Na reaction is the starting point of the NeNa cycle, which is an important process for the production of intermediate mass elements. The ${E}_{\text{c.m.}}=1113$ keV resonance plays an important role in the determination of stellar rates for this reaction since it is used to normalize experimental direct capture yields at lower energies. The commonly accepted strength of this resonance, $\ensuremath{\omega}\ensuremath{\gamma}=1.13\ifmmode\pm\else\textpm\fi{}0.07$ eV, has been misinterpreted as the strength in the center-of-mass frame when it is actually the strength in the laboratory frame. This has motivated a new measurement of the ${E}_{\text{c.m.}}=1113$ keV resonance strength in ${}^{20}$Ne${(p,\ensuremath{\gamma})}^{21}$Na using the DRAGON recoil mass spectrometer. The DRAGON result, $0.972\ifmmode\pm\else\textpm\fi{}0.11$ eV, is in good agreement with the accepted value when both are calculated in the same frame of reference.

Published

2013

25. Measurement of Radiative Proton Capture onF18and Implications for Oxygen-Neon Novae

Author

A. Spyrou, D.F. Ottewell, B. R. Fulton, L. Buchmann, D. W. Bardayan, Barry Davids, C. Akers, C. Stanford, Alison Laird, A. St. J. Murphy, L. Martin, D. A. Hutcheon, A. Rojas, Luke E. Erikson, G. Christian, Chris Ruiz, K. J. Nelson, Jennifer Fallis, and U. Hager

Subjects

Reaction rate, Physics, Neon, Proton, chemistry, Radiative transfer, General Physics and Astronomy, Nuclear fusion, chemistry.chemical_element, Resonance, Observable, Atomic physics, Order of magnitude

Abstract

The rate of the 18F(p,γ)19Ne reaction affects the final abundance of the γ-ray observable radioisotope 18F, produced in novae. However, no successful measurement of this reaction exists and the rate used is calculated from incomplete information on the contributing resonances. Of the two resonances thought to play a significant role, one has a radiative width estimated from the assumed analogue state in the mirror nucleus, 19F. The second does not have an analogue state assignment at all, resulting in an arbitrary radiative width being assumed. Here, we report the first successful direct measurement of the 18F(p,γ)^19Ne reaction. The strength of the 665 keV resonance (Ex=7.076 MeV) is found to be over an order of magnitude weaker than currently assumed in nova models. Reaction rate calculations show that this resonance therefore plays no significant role in the destruction of ^{18}F at any astrophysical energy.

Published

2013

26. Radiative capture reactions with heavy beams: extending the capabilities of DRAGON

Author

D.F. Ottewell, Anna Simon, B. R. Fulton, Jennifer Fallis, D. A. Hutcheon, L. Martin, Chris Ruiz, L. Buchmann, Alison Laird, Artemis Spyrou, and A. Rojas

Subjects

Physics, Nuclear reaction, Nuclear physics, Nuclear and High Energy Physics, Recoil, Isotope, Nucleosynthesis, Hadron, Gamma ray, Physics::Accelerator Physics, Nuclear fusion, Nuclear Experiment, Radioactive decay

Abstract

Understanding the nucleosynthesis of stable proton-rich nuclei requires knowledge of the cross sections for both proton and alpha capture reactions. As some of the nucleosynthesis paths responsible for the production of these nuclei involve reactions on unstable isotopes, it is of particular importance to develop techniques to investigate these reactions. This requires radioactive beams and measurements in inverse kinematics, thus making recoil separators an ideal tool for direct measurements of proton and alpha capture reactions. Here, the application of the DRAGON recoil separator for measurements of capture reactions for heavy beams is presented. The performance of the separator was tested using the 58Ni(p,γ)59Cu reaction.

Published

2013

27. MEASURING THE 16<font>O</font>(α, γ)20<font>Ne</font> REACTION RATE WITH THE DRAGON RECOIL SEPARATOR AT TRIUMF

Author

M. Carmona-Gallardo, Jennifer Fallis, U. Hager, C. Vockenhuber, S. Reeve, S. Sjue, D. Ottewell, A. Rojas, L. Buchmann, B. Davids, Luke E. Erikson, D. Hutcheon, D. Irvine, Camilo Ruiz, J. R. Brown, and U. Greife

Subjects

Physics, Nuclear physics, Reaction rate, Recoil separator

Published

2013

28. Measuring radiative capture rates at DRAGON

Author

L. Buchmann, D.F. Ottewell, D. A. Hutcheon, Barry Davids, A. Rojas, Jennifer Fallis, U. Greife, Chris Ruiz, and U. Hager

Subjects

Nuclear physics, Radiative capture, Environmental science

Published

2013

29. Direct measurement of the16O(α,γ)20Ne reaction atEc.m.=2.43MeV and 1.69 MeV

Author

D.F. Ottewell, D. A. Hutcheon, S. Reeve, Uwe Greife, Jennifer Fallis, Barry Davids, U. Hager, L. Buchmann, Chris Ruiz, D. Irvine, and A. Rojas

Subjects

Physics, Nuclear and High Energy Physics, M.2, Atomic physics, Recoil separator

Abstract

In stars, ${}^{16}$O represents the endpoint of the helium burning sequence due to the low rate of ${}^{16}$O($\ensuremath{\alpha}$,$\ensuremath{\gamma}$)${}^{20}$Ne. We present a new direct measurement of the total cross section of ${}^{16}$O($\ensuremath{\alpha}$,$\ensuremath{\gamma}$)${}^{20}$Ne at ${E}_{\mathrm{c}.\mathrm{m}.}=1.69\phantom{\rule{0.16em}{0ex}}\mathrm{MeV}$ employing the DRAGON recoil separator. In addition, the branching ratios and strength of the ${E}_{\mathrm{c}.\mathrm{m}.}=2.426\phantom{\rule{0.16em}{0ex}}\mathrm{MeV}$ ${3}^{\ensuremath{-}}$ resonance were determined.

Published

2012

30. Measurement of the17O(p,γ)18F reaction rate at astrophysically relevant energies

Author

N. Galinski, L. Buchmann, Barry Davids, D.F. Ottewell, D. A. Hutcheon, Uwe Greife, Chris Ruiz, B. R. Fulton, Jennifer Fallis, A. Rojas, K. Setoodehnia, and U. Hager

Subjects

Reaction rate, Nuclear physics, Physics, Nuclear and High Energy Physics, Cross section (physics), Nucleosynthesis, Recoil separator

Abstract

The ${}^{17}$O($p,\phantom{\rule{-0.16em}{0ex}}\ensuremath{\gamma}$)${}^{18}$F reaction plays an important role in hydrogen-burning nucleosynthesis. Conflicting values for the low-energy behavior of its cross section exist in the literature. We present direct measurements of the astrophysical $S$ factor of the ${}^{17}$O($p,\phantom{\rule{-0.16em}{0ex}}\ensuremath{\gamma}$)${}^{18}$F reaction at center-of-mass energies between 250 and 500 keV. These measurements were conducted in inverse kinematics at the DRAGON recoil separator.

Published

2012

31. Cross section measurements of the 3He(alpha, gamma) 7Be reaction using DRAGON at TRIUMF

Author

B. S. Nara Singh, D. A. Hutcheon, U. Hager, S. Reeve, Barry Davids, N. Galinski, S. P. Fox, Alison Laird, B. R. Fulton, Michael Hass, Jennifer Fallis, S. Sjue, Alan Shotter, Götz Ruprecht, L. Buchmann, Chris Ruiz, M. Carmona-Gallardo, Olof Tengblad, P. Adsley, D.F. Ottewell, L. Martin, and Science and Technology Facilities Council (UK)

Subjects

Physics, Nuclear physics, History, Cross section (physics), Alpha (ethology), Computer Science Applications, Education

Abstract

4 pags., 2 figs. -- Nuclear Physics in Astrophysics V 3–8 April 2011, Eilat, Israel, We present our initial efforts with the DRAGON separator at TRIUMF facility towards obtaining the energy dependence of the astrophysical S-factor for 3He(¿, ¿)7Be reaction in the energy range of Ecm = 2 to 3 MeV that was recommended by the recent evaluations. A comparison between the existing data and our new complementary Madrid data, together with the recent theoretical calculations, is also given in the context of our ongoing work., This work has been supported by the UK STFC.

Published

2012

32. [sup 12]C+[sup 16]O: Properties of sub-barrier resonance γ-decay

Author

F. Haas, Jennifer Fallis, Götz Ruprecht, C. Davis, Chris Ruiz, D. A. Hutcheon, D. Lebhertz, Alain Goasduff, D.F. Ottewell, U. Hager, D. G. Jenkins, S. Courtin, and P.-A. Amandruz

Subjects

Physics, Spins, Spectrometer, Radiative capture, Gamma ray, Coulomb barrier, Resonance, Atomic physics, Nuclear Experiment, Spin (physics)

Abstract

In a recent experiment performed at Triumf using the Dragon 0° spectrometer and its associated BGO array, the complete γ-decay of the radiative capture channel below the Coulomb barrier has been measured for the first time. This measurement has been performed at two energies Ec.m. = 6.6 and 7.2 MeV. A selective contribution of the entrance spins 2+ and 3− has been evidenced which is consistent with existing results above the barrier.

Published

2012

33. Direct total cross section measurement of the16O(α,γ)20Ne reaction atEc.m.=2.26MeV

Author

Cristof Vockenhuber, Jennifer Fallis, L. Buchmann, Mariano Carmona-Gallardo, Uwe Greife, J. R. Brown, Luke E. Erikson, D. A. Hutcheon, Chris Ruiz, S. Sjue, U. Hager, and D.F. Ottewell

Subjects

Nuclear reaction, Physics, Nuclear and High Energy Physics, M.2, Gamma ray, chemistry.chemical_element, Recoil separator, Nuclear physics, Cross section (physics), chemistry, Isotopes of neon, Physics::Atomic Physics, Atomic physics, Helium, Radioactive decay

Abstract

In stellar helium burning, ${}^{16}$O represents the endpoint of the helium-burning sequence due to the low rate of ${}^{16}$O($\ensuremath{\alpha}$,$\ensuremath{\gamma}$)${}^{20}$Ne. We present a new direct measurement of the total capture reaction rate of ${}^{16}$O($\ensuremath{\alpha}$,$\ensuremath{\gamma}$)${}^{20}$Ne at ${E}_{\mathrm{c}.\mathrm{m}.}=2.26\phantom{\rule{0.16em}{0ex}}\mathrm{MeV}$ employing the DRAGON recoil separator. For the first time, the total $S$ factor and its contributing direct capture transitions could be determined in one experiment.

Published

2011

34. The 33S(p,\gamma )34Cl reaction in classical nova explosions

Author

Catherine Deibel, Ralf Hertenberger, Kathrin Wimmer, Jennifer Fallis, K. Eppinger, Alejandro L. Garcia, W. Liu, D. A. Hutcheon, Z. H. Li, Anuj Parikh, B. G. Delbridge, Uwe Greife, A. Knecht, Chris Ruiz, G. Lian, Jason A. Clark, Christopher Wrede, B. R. Fulton, Reiner Kruecken, K. Setoodehnia, A. Chen, Er Tao Li, Bing Guo, Hans-Friedrich Wirth, Vinzenz Bildstein, O. Lepyoshkina, L. Buchmann, A. L. Sallaska, B. M. Freeman, S. Bishop, D. Seiler, P. Maierbeck, P. D. Parker, Y. Wang, D.F. Ottewell, C. Herlitzius, U. Hager, Alison Laird, and Thomas Faestermann

Subjects

Physics, Nova (laser), Astrophysics

Published

2011

35. The first direct measurement of 17O(\alpha ,\gamma )21Ne and its impact upon s-process abundances

Author

Jun Chen, Matthew Taggart, N. Galinski, Sarah Reeve, Jennifer Fallis, F. Herwig, B. R. Fulton, M. A. Bentley, Barry Davids, S. P. Fox, D. J. Mountford, Alison Laird, D.F. Ottewell, Dave Hutcheon, L. Erikson, C. A. Davis, Marco Pignatari, Alex Murphy, Götz Ruprecht, S. Sjue, Kelly Chipps, Laurelle Veloce, C. A. Diget, L. Martin, Uwe Greife, Chris Ruiz, L. Buchmann, J. R. Brown, Raphael Hirschi, D. Howell, A. Chen, John D'Auria, and Ulrike Hager

Subjects

Chemistry, Radiochemistry, Alpha (ethology), s-process

Published

2011

36. $^{12}$C+$^{16}$O sub-barrier radiative capture cross-section measurements

Author

G. Ruprecht, S. Courtin, C. Ruiz, D. A. Hutcheon, A. Goasduff, D. Lebhertz, C. Beck, C. A. Davis, Jennifer Fallis, U. Hager, P.-A. Amandruz, F. Haas, D. G. Jenkins, D. Ottewell, Institut Pluridisciplinaire Hubert Curien (IPHC), Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Grand Accélérateur National d'Ions Lourds (GANIL), and Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Physics, QC1-999, Radiative capture, Order (ring theory), Coulomb barrier, FOS: Physical sciences, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], Ion, Cross section (physics), Phase space, Heavy ion, Atomic physics, Nuclear Experiment (nucl-ex), Nuclear Experiment, ComputingMilieux_MISCELLANEOUS

Abstract

We have performed a heavy ion radiative capture reaction between two light heavy ions, $^{12}$C and $^{16}$O, leading to $^{28}$Si. The present experiment has been performed below Coulomb barrier energies in order to reduce the phase space and to try to shed light on structural effects. Obtained $\gamma$-spectra display a previously unobserved strong feeding of intermediate states around 11 MeV at these energies. This new decay branch is not fully reproduced by statistical nor semi-statistical decay scenarii and may imply structural effects. Radiative capture cross-sections are extracted from the data., Comment: 4 pages, 7 figures, to appear as proceedings of FUSION 2011 conference at St-Malo, France

Published

2011

37. NEURAL - A tracking detector for neutron-induced reactions of astrophysical importance

Author

L. Buchmann, Olof Tengblad, L. Martin, D.F. Ottewell, J. F. Carpino, S. Sjue, Aaron Couture, Alison Laird, Götz Ruprecht, Ahmed Hussein, K. Olchanski, Fredrik Tovesson, A. Chen, Jennifer Fallis, Chris Ruiz, U. Hager, G. Sheffer, Barry Davids, and S. P. Fox

Subjects

Nuclear reaction, Physics, History, Time projection chamber, Proton, Astrophysics::High Energy Astrophysical Phenomena, Gamma ray, Neutron radiation, Computer Science Applications, Education, Nuclear physics, Stars, Neutron capture, Astrophysics::Solar and Stellar Astrophysics, Neutron, Nuclear Experiment, Astrophysics::Galaxy Astrophysics

Abstract

Observations from gamma ray telescopes indicate that most of the galactic 26Al originates in massive stars. Several sites have been discussed for its production, including proton burning in the winds of very massive stars, and the later, explosive burning stages of these stars. Observations from the RHESSI and INTEGRAL missions currently seem to point to the latter scenario. In the advanced burning stages of massive stars the presence of neutrons becomes an important factor in nuclear reaction networks, so in addition to the 26Al(p,¿) 27Si reaction the neutron capture reactions 26Al(n,p) 26Mg and 26Al(n,¿) 23Na can lead to the destruction of 26Al, and thus alter the observed 26Al abundance. NEURAL is a detector design to measure the excitation functions of these reactions over a wide range of energies. 26Al targets implanted at TRIUMF will be exposed to a pulsed neutron beam at the neutron time-of-flight facility at LANSCE (Los Alamos Neutron Science CEnter). NEURAL is designed to detect all charged reaction products, combining a time projection chamber for the heavy ions, and Si detectors for the light particles mounted around the target. A first prototype has been built and partially tested at TRIUMF and LANSCE in December 2009.

Published

2011

38. Precision Mass Measurements of Heavy 252Cf Fission Fragments Near the r-process Path

Author

A. F. Levand, K. S. Sharma, Daniel Lascar, Jason A. Clark, Guy Savard, Gang Li, T. Sun, John P. Greene, Shane Caldwell, Bruce J. Zabransky, Jennifer Fallis, Jonathon Van Schelt, Matthew Sternberg, and Ralph Segel

Subjects

Physics, Nuclear physics, Fission, Path (graph theory), r-process

Published

2009

39. Mass Measurements of Proton-Rich Isotopes in the Vicinity of 92Ru and 93Rh for 'nu'p-process Models

Author

Jennifer Fallis

Subjects

Proton, Isotope, Chemistry, Radiochemistry, p-process

Published

2009

40. From the Sun to supernovae: experimental determinations of stellar reaction rates at TRIUMF

Author

Jennifer Fallis

Subjects

Physics, History, Solar neutrino, Astrophysics, Resonance (particle physics), Computer Science Applications, Education, Nuclear physics, Reaction rate, Stars, Supernova, Nucleosynthesis, Astrophysics::Solar and Stellar Astrophysics, Physics::Accelerator Physics, Asymptotic giant branch

Abstract

The ongoing goal of the TRIUMF astrophysics group is to measure resonance strengths and cross sections for reactions of astrophysical importance. This is done using accelerated radioactive and stable beams from ISAC I and II delivered to the DRAGON and TUDA facilities. The wide range of available beams at the energies provided by the ISAC I and II accelerators enable us to measure reaction rates of interest in many different astrophysical environments. Experiments in the past year have studied reactions important for understanding the production of solar neutrinos as well as nucleosynthesis in the Big Bang, Asymptotic Giant Branch (AGB) stars, novae, and supernovae. These experiments and the various techniques required for these measurements will be discussed.

Published

2013

41. 44Ti,26Al and53Mn samples for nuclear astrophysics: the needs, the possibilities and the sources

Author

Dorothea Schumann, C. Lederer, P. J. Woods, Friedrich-Karl Thielemann, M. Ayranov, Thierry Stora, Marco Pignatari, Y. Dai, M. Bunka, Daniel Bemmerer, A. St. J. Murphy, T. Stowasser, Jennifer Fallis, and Rugard Dressler

Subjects

Nuclear reaction, Physics, Nuclear and High Energy Physics, Radionuclide, Isotope, 01 natural sciences, 7. Clean energy, Nuclear physics, 0103 physical sciences, Nuclear astrophysics, Neutron, Irradiation, 010306 general physics, 010303 astronomy & astrophysics, Wet chemistry

Abstract

Exploration of the physics involved in the production of cosmogenic radionuclides requires experiments using the same rare, radioactive nuclei in sufficient quantities. For this work, such exotic radionuclides have been extracted from previously proton-irradiated stainless steel samples using wet chemistry separation techniques. The irradiated construction material has arisen from an extended material research programme at the Paul Scherrer Institute, called STIP (SINQ Target Irradiation Program), where several thousand samples of different materials were irradiated with protons and neutrons of energies up to 570 MeV. In total, 8 × 1017 atoms of 44Ti, ∼1016 atoms of 26Al and ∼1019 atoms of 53Mn are available from selected samples. These materials may now be used to produce targets or radioactive beams for nuclear reaction studies with protons, neutrons and α-particles. The work is part of the ERAWAST initiative (Exotic Radionuclides from Accelerator Waste for Science and Technology), aimed at facilitating new collaborations between the isotope producers and users from different scientific fields including nuclear astrophysics.

Published

2012