Your search keyword '"Brian Moazen"' showing total 3 results

1. Single-neutron excitations in neutron-rich N = 51 nuclei

Author

K. L. Jones, Caroline D Nesaraja, Jeffery C. Blackmon, Ryan P. Fitzgerald, Carl J Gross, Michael Scott Smith, M. S. Johnson, Uwe Greife, J. S. Thomas, D. W. Visser, Brian Moazen, R. L. Kozub, Dan Shapira, R. J. Livesay, Jolie Cizewski, J. F. Liang, D. W. Bardayan, and Zhanwen Ma

Subjects

Physics, Nuclear and High Energy Physics, Ion beam, Inverse kinematics, Nuclear Theory, Hadron, Nuclear physics, Neutron capture, Supernova, Physics::Accelerator Physics, Nuclear fusion, Neutron, Atomic physics, Nuclear Experiment, Excitation

Abstract

Single-neutron transfer reactions have been measured on two N = 50 isotones at the Holifield Radioactive Ion Beam Facility (HRIBF). The single-particle-like states of 83Ge and 85Se have been populated using radioactive ion beams of 82Ge and 84Se and the (d, p) reaction in inverse kinematics. The properties of the lowest-lying states —including excitation energies, orbital angular momenta, and spectroscopic factors— have been determined for these N = 51 nuclei.

Published

2005

2. Direct studies of low-energy resonances in 31P(p, α)28Si and 35Cl(p, α)32S

Author

D. W. Bardayan, Catalin Matei, Kelly Chipps, M. Matos, Caroline D Nesaraja, S. T. Pittman, W. A. Peters, Robert Hatarik, Michael Scott Smith, J. F. Shriner, R. L. Kozub, K. Y. Chae, Timothy Pelham, K. L. Jones, Patrick O'Malley, Brian Moazen, S. D. Pain, and J. C. Blackmon

Subjects

Physics, Nuclear and High Energy Physics, Crystallography, Low energy, Hadron, Nuclear fusion, Resonance, Atomic physics

Abstract

Low-energy resonances in 31P(p, α 28Si and 35Cl(p, α)32S were studied directly in order to gain a better understanding of reaction cycling in the Si-Ar region in novae. New resonance strengths at E c.m. = 600 and 622 keV in 31P(p, α)28Si were measured (ωγ p, α = (2.2#x00B1;0.7) × 10−2 eV and ωγ p, α = (0.99±0.08) eV, respectively) as well as the E c.m. = 610 keV resonance in 35Cl(p, α)32S [ωγ p, α = (1.2±0.2) × 10−2 eV], the lowest energy that any resonance in this reaction has been observed, directly or indirectly. The strengths of these resonances were found to be lower than previously determined, resulting in even weaker cycling in the Si-Ar region.

Published

2011

3. Direct measurements of (p, $ \gamma$ ) cross-sections at astrophysical energies using radioactive beams and the Daresbury Recoil Separator

Author

Ryan P. Fitzgerald, J. F. Shriner, R. L. Kozub, Kelly Chipps, Robert Hatarik, Michael Scott Smith, Brian Moazen, W. A. Peters, Caroline D Nesaraja, K. Y. Chae, J. C. Blackmon, D. W. Bardayan, S. D. Pain, Uwe Greife, Catalin Matei, Arthur E Champagne, and S. T. Pittman

Subjects

Physics, Nuclear and High Energy Physics, Proton, Ion beam, Hadron, Recoil separator, Nuclear physics, Nucleosynthesis, Ionization, Physics::Accelerator Physics, Nuclear fusion, Atomic physics, Nuclear Experiment, Beam (structure)

Abstract

There are a number of astrophysical environments in which the path of nucleosynthesis proceeds through proton-rich nuclei. These nuclei have traditionally not been available as beams, and thus proton-capture reactions on these nuclei could only be studied indirectly. At the Holifield Radioactive Ion Beam Facility (HRIBF), some of the first direct measurements of (p,\( \gamma\)) cross-sections on radioactive beams have been made. The Daresbury Recoil Separator (DRS) has been used to separate the recoils of interest from the unreacted primary beam and identify them in an isobutane-filled ionization counter. First data from 17F (p,\( \gamma\)18Ne and 7Be (p,\( \gamma\)8B measurements are presented.

Published

2009