First Direct Measurement of 
<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mrow><mml:mrow><mml:mmultiscripts><mml:mrow><mml:mi>Mg</mml:mi></mml:mrow><mml:mprescripts /><mml:none /><mml:mrow><mml:mn>22</mml:mn></mml:mrow></mml:mmultiscripts></mml:mrow><mml:mo stretchy="false">(</mml:mo><mml:mi>α</mml:mi><mml:mo>,</mml:mo><mml:mi>p</mml:mi><mml:mo stretchy="false">)</mml:mo><mml:mmultiscripts><mml:mrow><mml:mi>Al</mml:mi></mml:mrow><mml:mprescripts /><mml:none /><mml:mrow><mm

Randhawa, J. S.; Ayyad, Y.; Mittig, W.; Meisel, Z.; Ahn, T.; Aguilar, Sérgio Luiz Cruz; Álvarez‐Pol, H.; Bardayan, D. W.; Bazin, D.; Beceiro-Novo, S.; Blankstein, D.; Carpenter, Liz P.; Cortesi, M.; Cortina-Gil, D.; Gastis, P.; Hall, M. R.; Henderson, S. L.; Kolata, J. J.; Mijatović, T.; Ndayisabye, F.; O’Malley, P. D.; Pereira, J.; Pierre, ADDA; Robert, H; Santamaria, C.; Schatz, H.; Smith, J. K.; Watwood, N.; Zamora, J. C.

doi:10.1103/physrevlett.125.202701

Cited by 21 publications

(50 citation statements)

References 26 publications

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“…Finally, we note that if we assume that the E x = 8.985(8)-MeV state and the broad E x = 9.029(7)-keV state are the same state, the present data support a stronger p 1 decay branch for this state compared to the p 0 branch. In this case, proton peaks at E x = 3152 (8) keV or E p = 3186 (7) keV (depending on the choice of energy for the initial state) should be observed in the βp decay of 22 Al, which is not the case. This is another inconsistency between the presently observed branching ratios and the 22 Al βp decay data.…”

Section: B States At Ex ∼ 9 Mevmentioning

confidence: 97%

“…Unfortunately, there is some disagreement about the properties of levels at E x ∼ 9 MeV. The ENSDF database [41] gives E x = 8991 (7) keV for a state with a tentative J π = 1 − assignment. The J π = 1 − assignment comes from the 21 Na(p, p) 21 Na resonance scattering experiments of He et al and Zhang et al [26,27] in which a state is observed at E x = 9.050 (30) MeV.…”

Section: B States At Ex ∼ 9 Mevmentioning

confidence: 99%

“…[6]). Simulated X-ray burst lightcurves have shown a dependence on the compactness of neutron stars [7]. Constraints on the compactness from the lightcurve can subsequently be used to limit the range of symmetry-energy parameters of nuclear matter.…”

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confidence: 99%

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confidence: 99%

“…Recent developments have constrained some of these reaction rates [7,[10][11][12][13][14][15][16][17]. For example, the 22 Mg(α, p) 25 Al cross section has been measured using a time-projection chamber at NSCL [7]. The results from this experiment suggest that the 22 Mg(α, p) 25 Al reaction rate is around 8 times smaller than the prediction from the statistical model NON-SMOKER [18] and considerably higher than the rate calculated by Matic et al [19], though the Matic rate was based on only four resonances and should correctly be regarded as a lower limit.…”

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confidence: 99%

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Proton decays from $α$-unbound states in $^{22}$Mg and the $^{18}$Ne($α, p_{0}$)$^{21}$Na cross section

Brümmer¹,

Adsley²,

Rauscher³

et al. 2021

Preprint

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Background: Type I X-ray bursts provide an opportunity to constrain the equation of state of nuclear matter. Observations of the lightcurves from these bursts allow the compactness of neutron stars to be constrained. However, the behaviour of these lightcurves also depends on a number of important thermonuclear reaction rates. One of these reactions, 18 Ne(α, p) 21 Na, has been extensively studied but there is some tension between the rate calculated from spectroscopic information of states above the α-particle threshold in 22 Mg and the rate determined from time-reversed measurements of the cross section.Purpose: The time-reversed measurement of the cross section is only sensitive to the ground state-to-ground state contribution. Therefore, corrections must be made to this reaction rate to account for the contribution of branches to excited states in 21 Na. At present this is done with statistical models which may not be applicable in such light nuclei. Basing the correction of the time-reversed cross section on experimental data is much more robust. Method:The 24 Mg(p, t) 22 Mg reaction was used to populate states in 22 Mg. The reaction products from the reaction were analysed by the K600 magnetic spectrometer at iThemba LABS, South Africa. Protons decaying from excited states of 22 Mg (Sp = 5502 keV) excited states were detected in an array of five double-sided silicon strip detectors placed at backward angles. The branching ratio for proton decays to the ground state of 21 Na, Bp 0 , was determined by comparing the inclusive and exclusive spectra. Results:The experimental proton decay branching ratio to the ground state of 21 Na from excited states in 22 Mg were found to be a factor of about two smaller than the ratios predicted by Hauser-Feshbach models. Using the experimental branchings for a recalculation of the 18 Ne(α,p0) 21 Na cross section leads to a considerably improved agreement with previous reaction data. Updated information on the disputed number of levels around Ex ≈ 9 MeV and on the possible 18 Ne(α,2p) 20 Ne cross section at astrophysical energies is also reported. Conclusions:The proton decay branching of excited states in 22 Mg to the ground state of 21 Na have been measured using the K600 Q2D spectrometer at iThemba LABS coupled to the double-sided silicon-strip detector array CAKE. Using these experimental data, the modeling of the 18 Ne(α,p0) 21 Na cross section has been improved. The result is not only in better agreement with previous cross section data but also consistent with a recent direct measurement of 18 Ne(α,p) 21 Na. This strengthens the case for the application of statistical models for these reactions.

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