Pairing correlations, orientations and quantum fluctuations in one- and two-nucleon transfer reactions at sub-barrier energies

TL;DR

This study uses advanced microscopic models to analyze one- and two-neutron transfer reactions at sub-barrier energies, highlighting the importance of quantum fluctuations and nuclear deformation effects.

Contribution

It demonstrates the significance of quantum fluctuations in accurately modeling two-neutron transfer reactions using a combination of TD-CDFT and TDGCM methods.

Findings

Pairing correlations significantly enhance two-neutron transfer probabilities.

Orientation effects cause large variations in transfer probabilities due to nuclear deformation.

Quantum fluctuations are crucial for correctly describing sub-barrier two-neutron transfer dynamics.

Abstract

This work investigates one- and two-neutron transfer in the $^{96}\text{Zr} + {}^{40}\text{Ca}$ reaction at sub-barrier energies using a microscopic framework based on time-dependent covariant density functional theory (TD-CDFT). Pairing correlations are incorporated via the time-dependent BCS approximation, which is shown to significantly enhance pair transfer, as evidenced by an increased two-neutron transfer probability. The oblate deformation of $^{96}$Zr causes the transfer probabilities to vary by orders of magnitude with orientation; a direct comparison with experiment is enabled by averaging results over thirteen systematically chosen orientations. While the orientation-averaged one-neutron transfer probabilities agree well with data, the two-neutron channel is suppressed below the Coulomb barrier. This suppression is attributed to missing quantum fluctuations in the semiclassical TD-CDFT approach. To test this, we employ the generalized time-dependent generator coordinate method (TDGCM), which confirms that quantum fluctuations are essential for an accurate description of sub-barrier two-neutron transfer dynamics.