Abstract: The Cl-35(n, p)S-35 reaction plays a key role in neutron dosimetry for Boron Neutron Capture Therapy, in the synthesis of the isotope S-36, whose astrophysical origin remains unresolved, and in the design of next-generation molten-salt reactors. Its relevance has motivated its inclusion in the High Priority Request List (HPRL) of NEA. The goal of this work is to determine the Cl-35(n, p)S-35 cross-section from thermal energy to 120 keV for the first time ever in a single measurement, thus reducing systematic uncertainties related to the normalization to the thermal value. This had been a subject of concern in previous evaluations of this reaction. We made use of the Time-of-Flight technique with microMEGAS detectors at Experimental Area 2 (EAR-2) of n_TOF facility at CERN. The B-10 (n , alpha)Li-7 and U-235(n, f) reactions were used as references. Rutherford Back-scattering Spectrometry was performed at Centro Nacional de Aceleradores (CNA) in Sevilla, in order to accurately determine the masses of the irradiated samples. We obtained a thermal cross-section of 0.470 +/- 0.009 barns. The 1/v energy dependence of the cross-section is observed up to the first resonance at 0.398 keV, the resonances up to 120 keV are analyzed and resonance parameters extracted using SAMMY. Maxwellian Averaged Cross-Section (MACS) was calculated for k(B)T from 1 to 100 keV, and lower values compared to estimations from ENDF were found, e.g., 1.07 +/- 0.20 mb at k(B)T = 30 keV. The thermal cross-section and first two resonances are in agreement with the latest evaluation in ENDF/B-VIII.1, while remarkably lower resonance strengths were found for high energy resonances.

Abstract: We investigate the sensitivity of present and future direct detection experiments to generalized neutrino interactions (GNI) with electrons through elastic neutrino-electron scattering. Using data from LUX-ZEPLIN, PandaX-4T, and XENONnT, we derive constraints on vector, axial-vector, scalar, and tensor effective couplings, and compare them with existing limits. Our results show that current xenon-based detectors already provide competitive bounds, with XENONnT offering the most stringent constraints due to its larger exposure and reduced backgrounds. Among the GNI couplings, the scalar contributions remain more weakly constrained, while tensor interactions yield the strongest limits. We also present projected sensitivities for the DARWIN experiment, showing potential improvements. These results demonstrate the capability of direct detection experiments, originally designed for dark matter searches, to provide complementary and competitive constraints on generalized neutrino interactions.

Abstract: Motivated by recent BESIII measurements of the singly Cabibbo-suppressed processes Lambda c+->Lambda K+pi 0 and Lambda c+->Lambda KS0 pi+ , we investigate the process Lambda c+->Lambda K0 pi+ by taking into account the contribution from the low-lying excited baryon Sigma*(1/2-), dynamically generated via the S-wave pseudoscalar meson-octet baryon interaction, as well as from the intermediate resonances K*(892) and N (1535). Our model successfully reproduces the BESIII pi+K0 invariant mass distribution, and predicts a distinct cusp structure around 1.43 GeV in the pi+Lambda invariant mass distribution, which is associated with the predicted Sigma*(1/2-). Future high-precise measurements of this process at BESIII, Belle II, and the proposed Super Tau-Charm Facility experiments will be crucial for testing the existence of Sigma*(1/2-) and advancing our understanding of the light baryon spectrum.