The excitation scheme of the ${}^{63}\mathrm{Cu}$ nucleus has been probed following its population in a light-ion induced fusion-evaporation reaction and using an array of Compton suppressed HPGe clover detectors as the detection system. Apart from ascribing $\gamma$-ray transitions to the level scheme of the nucleus, through $\gamma \text{−}\gamma$ coincidence measurements, and identifying the new transitions in the process, measurements of angular correlation and linear polarization of the $\gamma$ rays have also been carried out towards assigning their multipolarities and electric and magnetic characters. The observed level scheme has been interpreted through shell model calculations in two different model spaces. One of these was the $f5pg9$ space outside the ${}^{56}\mathrm{Ni}$ core while the other included the $f_{7/2}$ orbital for the protons outside the ${}^{48}\mathrm{Ca}$ core and was directed at probing the influence of the $f_{7/2}$ excitations in the regime of spins being investigated. The latter has been found to be of rather modest impact, in general, and the observed level structure can largely be interpreted through particle excitations in the $f5pg9$ model space.

• Received 11 November 2021
• Revised 24 January 2023
• Accepted 13 February 2023

DOI:https://doi.org/10.1103/PhysRevC.107.024312