2020
DOI: 10.1103/physrevc.102.041303
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Almost medium-free measurement of the Hoyle state direct-decay component with a TPC

Abstract: Background: The structure of the Hoyle state, a highly α-clustered state at 7.65 MeV in 12 C, has long been the subject of debate. Understanding if the system comprises of three weakly-interacting α-particles in the 0s orbital, known as an α-condensate state, is possible by studying the decay branches of the Hoyle state. Purpose: The direct decay of the Hoyle state into three α-particles, rather than through the 8 Be ground state, can be identified by studying the energy partition of the 3 α-particles arising … Show more

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Cited by 20 publications
(17 citation statements)
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“…Phenomenological Rmatrix models employed in astrophysics typically assume that only two-body effects are important [12,47]. Whilst the direct 3α decay branch has been shown to be small at the primary peak of the Hoyle state [5,6,7,9], at higher excitation energies, the direct branch may be non-negligible due to the enhanced penetrability through the Coulomb barrier (see Ref. [8]).…”
Section: Particle Energy [Mev]mentioning
confidence: 99%
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“…Phenomenological Rmatrix models employed in astrophysics typically assume that only two-body effects are important [12,47]. Whilst the direct 3α decay branch has been shown to be small at the primary peak of the Hoyle state [5,6,7,9], at higher excitation energies, the direct branch may be non-negligible due to the enhanced penetrability through the Coulomb barrier (see Ref. [8]).…”
Section: Particle Energy [Mev]mentioning
confidence: 99%
“…Of particular interest is 12 C, which exhibits shell-model and α-cluster structures. The Hoyle state in 12 C is the archetypal α-cluster state [3], remaining the focus of considerable study, including efforts to measure its direct [4,5,6,7,8,9], γ [10] and E0 decay branching ratios [11]. Such decay branches are astrophysically significant; the Hoyle state mediates the 3α reaction producing 12 C. The 3α reaction rate requires an accurate description of the Hoyle-state properties (e.g., resonance energy E r , partial and total widths, Γ i and Γ) and their evolution with excitation energy.…”
mentioning
confidence: 99%
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“…At this point, the "3α process" becomes significant, which allows carbon to be produced in stars that have an equilibrium concentration of 8 Be (t 1/2 = 10 −16 s) [1]. The small probability of a third α particle to fuse with the 8 Be before it decays enables the production of 12 C, (α + α → 8 Be) + α → 12 C * . The existence of the 0 + 2 state at 7.65 MeV above the ground state of 12 C is crucial for the 3α process.…”
Section: Introductionmentioning
confidence: 99%
“…The Hoyle state disintegrates back to 8 Be+α or 3α with probability > 99.94% [9,10]. Stable carbon is only produced when the Hoyle state instead electromagnetically decays directly to the ground state via an electric monopole (E0) transition, or via the 2 + 1 state by two electric quadrupole (E2) transitions.…”
Section: Introductionmentioning
confidence: 99%