1969
DOI: 10.1086/150073
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Experimental Investigation of the Stellar Nuclear Reaction ^{12}C + ^{12}C at Low Energies

Abstract: The reactions 12 C( 12 C,a) 20 Ne, 12 C( 12 C,^) 23 Na, and 12 C( 12 C,w) 23 Mg have been studied to provide reliable predictions of their cross-sections in the energy region of interest in stellar carbon burning. Many excited-state transitions have been observed for the a-particles and protons. Measurements for these particles have been made in the center-of-mass energy range 3.23-8.75 MeV. The relatively small yield of the 12 C( 12 C,w) 23 Mg reaction has been investigated from 4.25 to 6.25 MeV. The new … Show more

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Cited by 228 publications
(189 citation statements)
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“…The evolution of the progenitor WD during the simmering phase (which is difficult to address because it is on the borderline between hydrostatic and hydrodynamic phenomena) is controlled by the competition between cooling processes (neutrino emission and convection) and heating by a dominant nuclear reaction: the fusion of two 12 C nuclei at temperatures in the range 2 × 10 8 −10 9 K. A&A 535, A114 (2011) The experimental measurement of the cross-section of the 12 C + 12 C reaction (carbon fusion reaction) at low energies has advanced slowly in the past few decades. At the time of formulation of the carbon detonation model for SNIa (Arnett 1969), the latest known experimental results extended down to a center of mass energy E cm = 3.23 MeV (Patterson et al 1969). Seven years later, when the deflagration model was proposed, the reference 12 C + 12 C reaction rate evaluated by Fowler et al (1975, hereafter FCZ75) was based on experimental measurements at E cm > 2.45 MeV (Mazarakis & Stephens 1973).…”
Section: Introductionmentioning
confidence: 99%
“…The evolution of the progenitor WD during the simmering phase (which is difficult to address because it is on the borderline between hydrostatic and hydrodynamic phenomena) is controlled by the competition between cooling processes (neutrino emission and convection) and heating by a dominant nuclear reaction: the fusion of two 12 C nuclei at temperatures in the range 2 × 10 8 −10 9 K. A&A 535, A114 (2011) The experimental measurement of the cross-section of the 12 C + 12 C reaction (carbon fusion reaction) at low energies has advanced slowly in the past few decades. At the time of formulation of the carbon detonation model for SNIa (Arnett 1969), the latest known experimental results extended down to a center of mass energy E cm = 3.23 MeV (Patterson et al 1969). Seven years later, when the deflagration model was proposed, the reference 12 C + 12 C reaction rate evaluated by Fowler et al (1975, hereafter FCZ75) was based on experimental measurements at E cm > 2.45 MeV (Mazarakis & Stephens 1973).…”
Section: Introductionmentioning
confidence: 99%
“…The primary impact of the 12 C+ 12 C→ 23 Mg+n reaction (hereafter referred to as CCN) surrounds the component of s-process nucleosynthesis which occurs during convective shell-carbon burning of massive stars. The so-called weak s-process is responsible for the elements between iron and strontium and occurs also during convective core helium burning in massive stars with the neutrons coming mainly from the reaction 22 Ne(α,n) 25 Mg (see Ref.…”
Section: Motivationmentioning
confidence: 99%
“…The fusion reaction proceeds through the formation of the 24 Mg compound nucleus at high excitation energy (∼15 MeV) followed by alpha, proton, or neutron decay to states in the corresponding residual nuclei ( 20 Ne, 23 Na, and 23 Mg respectively). The proton and alpha decay channels are the most probable due to their positive Q-values (Q p =+2.2 MeV and Q α =+4.6 MeV), while the neutron channel comprises less than 1% of the total yield at astrophysical energies [4] due to a negative Q-value (Q n =-2.6 MeV).…”
Section: Introductionmentioning
confidence: 99%
“…12 C + 12 C is the sys-tem with more evidence for quasimolecular structure, derived mainly from excitation function measurements for many of the possible reaction channels [1][2][3][4][5][6][7]. The vast amount of data accumulated in this respect still awaits a sound and comprehensive theoretical model capable of explaining all the observed details.…”
Section: Introductionmentioning
confidence: 99%
“…Below a center of mass energy E cm of 2.5 MeV there is not enough energy to feed 23 Mg even in its ground state and α and p channel are the only relevant ones at low energies. Considerable efforts have been devoted to measure the 12 C + 12 C cross section at astrophysical energies, involving both, charged particle [11][12][13] and gamma ray spectroscopy [14][15][16][17][18][19]. Nevertheless, it has only been previously measured down to E cm = 2.5 MeV, still at the beginning of the region of astrophysical interest.…”
Section: Introductionmentioning
confidence: 99%