Flavigny, FreddyJongile, SandileWiedeking, Michael2026-06-302026-06-302026Jongile, S., Wiedeking, M., Sorlin, O., Neveling, R., Hebborn, C., Keeley, N., Nowacki, F., Somà, V., Lemasson, A., Papka, P. and Adsley, P., 2026. Probing the j dependence of angular distributions and N= 20 shell rigidity via the S 36 (p, d) S 35 reaction. Physical Review C, 113(2), p.024323.https://doi.org/10.1103/HRD3-246Dhttps://hdl.handle.net/10566/24772An investigation of the 𝑁=2036S nucleus has been performed through a detailed study of the 36S(𝑝,𝑑)35S neutron-removal reaction, employing a 66-MeV proton beam at iThemba Laboratory for Accelerator Based Sciences and an innovative target design. Using the high-resolution 𝐾 = 600 magnetic spectrometer, 98 states in 35S were identified up to 16-MeV excitation energy, including 47 previously unobserved states. Angular distributions and spectroscopic factors, including isobaric analog-state contributions, were extracted for 81 levels. A pronounced 𝑗 dependence in the angular distributions of ℓ=2 states provide refined insights into the spin-orbit splitting. Finite-range adiabatic distorted-wave approximation calculations qualitatively reproduce the observed 𝑗 dependence. Comparisons of the measured 1𝑑5/2 spectroscopic strength distribution with large-scale shell-model and ab initio calculations show good agreement overall, and the robustness of the 𝑁=20 shell closure in 36S is confirmed when comparing the relatively low 𝑓𝑝 orbital occupancies in 40Ca and 36S across the Fermi surface. This study underscores the utility of neutron-removal reactions in probing nuclear structure and the Fermi surface of 𝑠𝑑 nuclei and beyond. The findings advance our understanding of shell evolution and offer constraining data for theoretical models.enSulfur-35 (³⁵S)Proton-Deuteron ReactionsN=20 Shell ClosureNuclear SpectroscopySpin-Orbit SplittingProbing the j dependence of angular distributions and N = 20 shell rigidity via the 36S(p, d) 35S reactionArticle