Investigation of entanglement in N = Z nuclei within no-core shell model
Abstract
In this work, we explore the entanglement structure of two N = Z nuclei, 20Ne and 22Na using single-orbital entanglement entropy within the No-Core Shell Model (NCSM) framework for two realistic interactions, INOY and N3LO. We begin with the determination of the optimal frequencies based on the variation of ground-state (g.s.) binding energy with NCSM parameters, Nmax and , followed by an analysis of the total single-orbital entanglement entropy, Stot, for the g.s. of 20Ne and 22Na. Our results show that Stot increases with Nmax and decreases with after reaching a maximum. We use Stot to guide the selection of an additional set of optimal frequencies that can enhance electromagnetic transition strengths. We also calculate the low-energy spectra and Stot for four low-lying states of 20Ne and six low-lying states of 22Na. Finally, we calculate a few E2 and one M1 transition strengths, finding that N3LO provides better results for B(E2; 5+1 3+1) and INOY performs well for the B(M1; 01+ 11+) transition in the 22Na nucleus while considering the first set of optimal frequencies. We also observe that the second set of optimal frequencies enhances electromagnetic transition strengths, particularly for the states with large and comparable Stot. Also, for both nuclei, the Stot for INOY and N3LO are close while considering the second set of optimal frequencies, suggesting that the calculated Stot are more dependent on than the interactions employed for the same model space defined by the Nmax parameter.
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