Abstract: We present a catalog of gravitational wave background (GWB) signal templates from cosmic-string networks, based on relevant models proposed in the literature. We classify templates as conventional, based on standard cosmology and Nambu-Goto results (VOS and BOS), and beyond conventional, based on modifications of a) the loop number density (LRS, super, metastable, current-carrying strings), b) the expansion history (nonstandard cosmologies, extra degrees of freedom, either thermal or secluded), or c) the loop properties (birth length, power emission). Using the SBI package GWBackFinder: https://github.com/AndronikiDimitriou/GWBackFinder, we quantify the reconstruction precision of each signal by LISA, scanning over their parameter space, and performing model comparisons. For conventional signals, LISA reconstructs the tension G & micro; with an error less than or similar to 10% for G & micro; >= 5 & centerdot;10-15, which decreases down to 2-3% for G & micro; >= 10-12. BOS and VOS modelings become distinguishable confidently for G & micro; >= 5 & centerdot; 10-13. For beyond-conventional signals, we identify SNR and error-threshold intervals for each parameter, and determine (for few examples) the regions where they can be distinguished from conventional signals. Analogous quality reconstruction studies of cosmic-string GWBs, superimposed over leading astrophysical foregrounds in the LISA window, will be presented in a series of upcoming papers.

Abstract: The top-quark mass is measured using top-quark decays producing an isolated lepton and J/psi meson reconstructed in its mu(+)mu(-) decay mode. The data sample was recorded with the ATLAS detector in proton-proton collisions at a centre-of-mass energy of root s = 13 TeV during Run 2 of the Large Hadron Collider, corresponding to an integrated luminosity of 140 fb(-1). The measurement is based on the invariant mass m(l mu(+)mu(-)) of the system made of the isolated lepton l from the W boson decay and the non-isolated mu(+)mu(-) pair from a J/psi decay of a b-hadron, exploiting its sensitivity to the top-quark mass. An unbinned maximum-likelihood fit to the m(l mu(+)mu(-)) distribution is performed to extract the top-quark mass. The top-quark mass is measured to be m(top) = 172.17 +/- 0.80 (stat) +/- 0.81 (syst) +/- 1.07 (recoil) GeV, with a total uncertainty of 1.56 GeV. The third uncertainty arises from changing the dipole parton shower gluon-recoil scheme used in top-quark decays.

Abstract: Energy-differential cross section of the C-nat(n, p) and C-nat(n,d) reactions was measured at the neutron time-of-flight facility nTOF at CERN. The measurement was performed in the first experimental area (EAR1; flight path of 182.5 m). Two position-sensitive Delta E-E silicon telescopes were used. Two naturally occurring carbon isotopes, C-12 and C-13, contribute to the reactions on natural carbon, with the (n,p) reaction threshold at 13.7 MeV and the (n,d) threshold at 14.9 MeV (determined by the C-12 isotope for both reactions). This paper provides the details of the analysis leading to the final results published previously as a Letter. The cross-section results are reported up to 25 MeV. During the data analysis the population of the excited states in the daughter nuclei B-11, B-12, and B-13 had to be considered, requiring the adoption of the branching ratios and angular distributions of the emitted particles from an external source of information. TALYS-2.0 calculations were used as the main source and an in-depth analysis of the model-related uncertainties was performed. The nTOF results are largely inconsistent with the major evaluation libraries. On the other hand, an unexpected agreement is found with TALYS-2.0 calculations. Specifically, the obtained cross section for the (n,p) reaction is significantly higher than in the available evaluations, fully supporting the earlier finding from an integral measurement at n_TOF.