Effectiveness of using a magnetic spectrograph with the Trojan Horse method

Manwell, S. ; Parikh, A. ; Chen, A. A. ; De Sereville, N. ; Adsley, P. ; Irvine, D. ; Hammache, F. ; Stefan, I. ; Longland, R. F. ; Tomlinson, J. ; Morfuace, P. ; Le Crom, B. (2018)

CITATION: Manwell, S., et al. 2018. Effectiveness of using a magnetic spectrograph with the Trojan Horse method. Journal of Physics: Conference Series, 940:012046, doi:10.1088/1742-6596/940/1/012046.

The original publication is available at https://iopscience.iop.org

Conference Paper

The Trojan Horse method relies on performing reactions in a specific kinematic phase space that maximizes contributions of a quasi-free reaction mechanism. The hallmark of this method is that the incident particle can be accelerated to high enough energies to overcome the Coulomb barrier of the target, but once inside the target nucleus the relative motion of the clustered nuclei allows the reaction of interest to proceed at energies below this Coulomb Barrier. This method allows the experimentalist to probe reactions that have significance in astrophysics at low reaction energies that would otherwise be impossible due to the vanishing cross section. Traditionally the Trojan Horse method has been applied with the use of silicon detectors to observe the reaction products. In this study we apply the Trojan Horse method to a well studied reaction to examine the potential benefits of using a splitpole magnetic spectrograph to detect one of the reaction products. We have measure the three body 7Li(d,αn)α reaction to constrain the energy 7Li(d,α)α cross section. Measurements were first made using two silicon detectors, and then by replacing one detector with the magnetic spectrograph. The experimental design, limitations, and early results are discussed.

Please refer to this item in SUNScholar by using the following persistent URL: http://hdl.handle.net/10019.1/106720
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