Peer Reviewed

Ab initio many-body calculation of the ⁷Be(p, γ )⁸B radiative capture

We apply the ab initio no-core shell model/resonating group method (NCSM/RGM) approach to calculate

the cross section of the ⁷Be(p,γ )⁸B radiative capture. This reaction is important for understanding the

solar neutrino flux. Starting from a selected similarity-transformed chiral nucleon–nucleon interaction

that accurately describes two-nucleon data, we performed many-body calculations that simultaneously

predict both the normalization and the shape of the S-factor. We study the dependence on the number

of ⁷Be eigenstates included in the coupled-channel equations and on the size of the harmonic oscillator

basis used for the expansion of the eigenstates and of the localized parts of the integration kernels. Our

S-factor result at zero energy is on the lower side of, but consistent with, the latest evaluation.

plb_704_379_2011.pdf

Author: Petr Navratil, Robert Roth, Sofia Quaglioni

Journal: Physics Letters B

Recoil separators for radiative capture using radioactive ion beams

Radiative capture reactions involving the fusion of hydrogen or helium are ubiquitous in the stellar history of the universe, and are some of the most important reactions in the processes that govern nucleosynthesis and energy generation in both static and explosive scenarios. However, radiative capture reactions pose some of the most difficult experimental challenges due to extremely small cross sections.

With the advent of recoil separators and techniques in inverse kinematics, it is now possible to measure radiative capture reactions on very short-lived radioactive nuclei, and in the presence of high experimental backgrounds. In this paper we review the experimental needs for making measurements of astrophysical importance on radiative capture reactions. We also review some of the important historical advances in the field of recoil separators as well as describe current techniques and performance milestones, including descriptions of some of the separators most recently working at radioactive ion beam facilities, such as DRAGON at TRIUMF and the DRS at the Holifield Radioactive Ion Beam Facility.We will also summarize some of the scientific highlight measurements at the RIB facilities.

ruiz_epja_2014.pdf

Author: C. Ruiz, U. Greife, U. Hager

Journal: European Physical Journal A

Measurement of Radiative Proton Capture on ¹⁸F and Implications for Oxygen-Neon Novae

The rate of the ¹⁸F(p,g)¹⁹Ne reaction affects the ﬁnal abundance of the gamma-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,g)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 of¹⁸F at any astrophysical

energy

physrevlett.110.262502.pdf

Author: C. Akers

Journal: Phys. Rev. C

Strength of the E_c.m. = 1113 keV resonance in ²⁰Ne(p, γ)²¹Na

The ²⁰Ne(p, γ)²¹Na reaction is the starting point of the NeNa cycle, which is an important process for the production of intermediate mass elements. The E_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, ωγ = 1.13±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_c.m. = 1113 keV resonance strength in ²⁰Ne(p, γ)²¹Na using the DRAGON recoil mass spectrometer. The DRAGON result, 0.972 ± 0.11 eV, is in good agreement with the accepted value when both are calculated in the same frame of reference.

christian_20ne.pdf

Author: G. Christian, D. Hutcheon, C. Akers, D. Connolly, J. Fallis, and C. Ruiz

Journal: Phys. Rev. C, Brief Reports

Solar fusion cross sections II: the pp chain and CNO cycles

The available data on nuclear fusion cross sections important to energy generation in the Sun and other hydrogen-burning stars and to solar neutrino production are summarized and critically evaluated. Recommended values and uncertainties are provided for key cross sections, and a recommended spectrum is given for 8B solar neutrinos. Opportunities for further increasing the precision of key rates are also discussed, including new facilities, new experimental techniques, and improvements in theory. This review, which summarizes the conclusions of a workshop held at the Institute for Nuclear Theory, Seattle, in January 2009, is intended as a 10-year update and supplement to 1998, Rev. Mod. Phys. 70, 1265.

adelberger11.pdf

Author: Adelberger, E. G.; García, A.; Robertson, R. G. Hamish; Snover, K. A.; Balantekin, A. B.; Heeger, K.; Ramsey-Musolf, M. J.; Bemmerer, D.; Junghans, A.; Bertulani, C. A.; Chen, J.-W.; Costantini, H.; Prati, P.; Couder, M.; Uberseder, E.; Wiescher, M.; Cyburt, R.; Davids, B.; Freedman, S. J.; Gai, M.; Gazit, D.; Gialanella, L.; Imbriani, G.; Greife, U.; Hass, M.; Haxton, W. C.; Itahashi, T.; Kubodera, K.; Langanke, K.; Leitner, D.; Leitner, M.; Vetter, P.; Winslow, L.; Marcucci, L. E.; Motobayashi, T.; Mukhamedzhanov, A.; Tribble, R. E.; Nollett, Kenneth M.; Nunes, F. M.; Park, T.-S.; Parker, P. D.; Schiavilla, R.; Simpson, E. C.; Spitaleri, C.; Strieder, F.; Trautvetter, H.-P.; Suemmerer, K.; Typel, S.

Journal: Review of Modern Physics, vol. 83, Issue 1, pp. 195-246

Direct Measurements of Na22(p,γ)Mg23 Resonances and Consequences for Na22 Production in Classical Novae

The radionuclide Na22 is a potential astronomical observable that is expected to be produced in classical novae in quantities that depend on the thermonuclear rate of the Na22(p,γ)Mg23 reaction. We have measured the strengths of low-energy Na22(p,γ)Mg23 resonances directly and absolutely using a radioactive Na22 target. We find the strengths of resonances at E_p=213, 288, 454, and 610 keV to be higher than previous measurements by factors of 2.4-3.2, and we exclude important contributions to the rate from proposed resonances at E_p=198, 209, and 232 keV. The Na22 abundances expected in the ejecta of classical novae are reduced by a factor of ≈2.

physrevlett.105.152501.pdf

Author: Sallaska, A. L.; Wrede, C.; García, A.; Storm, D. W.; Brown, T. A. D.; Ruiz, C.; Snover, K. A.; Ottewell, D. F.; Buchmann, L.; Vockenhuber, C.; Hutcheon, D. A.; Caggiano, J. A.

Journal: Physical Review Letters, vol. 105, Issue 15, id. 152501 (2010)

Absolute determination of the Na22(p,γ)Mg23 reaction rate in novae

Gamma-ray telescopes in orbit around the earth are searching for evidence of the elusive radionuclide Na22 produced in novae. Previously published uncertainties in the dominant destructive reaction, Na22(p,γ)Mg23, indicated new measurements in the proton energy range of 150 to 300 keV were needed to constrain predictions. We have measured the resonance strengths, energies, and branches directly and absolutely by using protons from the University of Washington accelerator with a specially designed beam line, which included beam rastering and cold vacuum protection of the Na22 implanted targets. The targets, fabricated at TRIUMF-ISAC, displayed minimal degradation over a ~20 C bombardment as a result of protective layers. We avoided the need to know the absolute stopping power, and hence the target composition, by extracting resonance strengths from excitation functions integrated over proton energy. Our measurements revealed that resonance strengths for E_p=213, 288, 454, and 610 keV are stronger by factors of 2.4-3.2 than previously reported. Upper limits have been placed on proposed resonances at 198, 209, and 232 keV. These substantially reduce the uncertainty in the reaction rate. We have re-evaluated the Na22(p,γ) reaction rate, and our measurements indicate the resonance at 213 keV makes the most significant contribution to Na22 destruction in novae. Hydrodynamic simulations including our rate indicate that the expected abundance of Na22 ejecta from a classical nova is reduced by factors between 1.5 and 2, depending on the mass of the white-dwarf star hosting the nova explosion.

physrevc.83.034611.pdf

Author: Sallaska, A. L.; Wrede, C.; García, A.; Storm, D. W.; Brown, T. A. D.; Ruiz, C.; Snover, K. A.; Ottewell, D. F.; Buchmann, L.; Vockenhuber, C.; Hutcheon, D. A.; Caggiano, J. A.; José, J.

Journal: Physical Review C, vol. 83, Issue 3, id. 034611 (2011)

Direct measurement of the 18F(p,α)15O reaction at nova temperatures

The ¹⁸F(p,α)¹⁵O reaction rate is crucial for understanding the final abundance of ¹⁸F predicted by nova models. The γ-ray emission in the first few hours after a nova outburst is expected to be dominated by 511 keV annihilation photons from the decay of ¹⁸F, and so understanding its production can provide important constraints on the conditions during the outburst when compared with observations. Results are presented from the lowest-energy direct measurement to date, performed at the Isotope Separator and Accelerator radioactive beam facility at the TRIUMF laboratory, Canada. Cross section measurements at center-of-mass energies of 250, 330, 453, and 673 keV are obtained and the results compared to previous data and R-matrix calculations. The implications for the overall reaction rate in the context of nova explosions have been discussed.

physrevc.83.042801_2.pdf

Author: C. E. Beer, A. M. Laird, A. St. J. Murphy, M. A. Bentley, L. Buchman, B. Davids, T. Davinson, C. A. Diget, S. P. Fox, B. R. Fulton, U. Hager, D. Howell, L. Martin, C. Ruiz, G. Ruprecht, P. Salter, C. Vockenhuber, and P. Walden

Journal: Phys. Rev. C 83, 042801(R) (2011) [4 pages]

First direct measurement of the ²³Mg(p,γ)²⁴Al reaction

The lowest-energy resonance in the ²³Mg(p,γ)²⁴Al reaction, which is dominant at classical nova temperatures, has been measured directly for the first time using the DRAGON recoil spectrometer. The experiment used a radioactive ²³Mg beam (mixed within a significantly stronger ²³Na beam) of peak intensity 5×10⁷ s^-1, at the ISAC facility at TRIUMF. We extract values of E_R=485.7_-1.8^+1.3keV and ωγ=38_-15⁺²¹ meV from our data (all values in the center-of-mass frame unless otherwise stated). In addition, the experiment prompted a recalculation of the Q value for this reaction based on a revision of the ²⁴Al mass. The effect on the uncertainties in the quantities of ejected ²²Na and ²⁶Al from oxygen-neon classical novae is discussed.

erikson_23mgpg_2010.pdf

Author: Erikson, L. et al.

Journal: Physical Review C

Measurement of the ⁴⁰Ca(α,γ) ⁴⁴Ti reaction relevant for supernova nucleosynthesis

The short-lived nuclide 44 Ti is an important nuclide for the understanding of explosive nucle-osynthesis. The main production reaction, 40 Ca(α, γ)44 Ti, has been studied in inverse kinematics with the recoil mass spectrometer DRAGON located at the TRIUMF-ISAC facility in Vancouver, Canada. The temperature range relevant for α-rich freeze-out during a core-collapse supernova has been covered entirely with a 40 Ca beam of 0.60 to 1.15 MeV/nucleon. All relevant quantities for the calculation of the astrophysical reaction rate have been measured directly. Due to many previously undiscovered resonances, the reaction rate derived from the energy dependent 44 Ti yield is higher than the one based on previous prompt γ-ray studies commonly used in supernova models. The presented new rate results in an increased 44 Ti production in supernovae.

VockenhuberPRC2007_40Ca_ag_44Ti_preprint.pdf

Author: See Paper Document

Journal: Phys. Rev. C 76 035801 (2007).