Enhanced S-factor for the 14N(p,γ)15O reaction and its impact on the solar composition problem

Abstract

The solar composition problem has puzzled astrophysicists for more than 20 years. Recent measurements of carbon-nitrogen-oxygen (CNO) neutrinos by the Borexino experiment show a 2σ tension with the "low-metallicity" determinations. 14N(p,γ)15O, the slowest reaction in the CNO cycle, plays a crucial role in the standard solar model (SSM) calculations of CNO neutrino fluxes. Here we report a direct measurement of the 14N(p,γ)15O reaction, in which S-factors for all transitions were simultaneously determined in the energy range of Ep=110-260 keV for the first time. Our results resolve previous discrepancies in the ground-state transition, yielding a zero-energy S-factor S114(0) = 1.920.08 keV b which is 14% higher than the 1.680.14 keV b recommended in Solar Fusion III (SF-III). With our S114 values, the SSM B23-GS98, and the latest global analysis of solar neutrino measurements, the C and N photospheric abundance determined by the Borexino experiment is updated to NCN=(4.45+0.69-0.61)×10-4. This new NCN value agrees well with latest "high-metallicity" composition, however, is also consistent with the "low-metallicity" determination within 1σ C.L., indicating that the solar metallicity problem remains an open question. In addition, the significant reduction in the uncertainty of S114 paves the way for the precise determination of the CN abundance in future large-volume solar neutrino measurements.

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