- 1Dipartimento di Fisica “Aldo Pontremoli”, Università degli Studi, Milano, Italy
- 2INFN, Sez. di Milano, Milano, Italy
- 3School of Nuclear Science and Technology, Lanzhou University, Lanzhou, China
- 4Frontiers Science Center for Rare Isotope, Lanzhou University, Lanzhou, China
The study of
1 Introduction
The
One of the reasons why many basic questions like those mentioned above are still unanswered is the lack of a full understanding of the nuclear single
2 Nuclear structure and -decay
Even single-
(we will use the standard nomenclature of “parent” and “daughter” nuclei in what follows). The half-life
where
where
Strictly speaking, Eq. 2 is valid for the one discrete F and GT state. There may be a set of discrete states or, if one goes above the particle threshold, a continuum distribution of strength. By restricting ourselves to the GT case and labeling with the integral symbol, the sum over discrete states or the integral over a continuum GT distribution
Energy conservation dictates the decay is possible when the decay
with the electron energy, momentum, and Fermi function denoted as
Figure 1 (the left panel) shows possible GT transitions in the nucleus presented as an example for our general discussion, i.e., 132Sn. There are many single-particle transitions, but, as is well known, most of their GT strength will be absorbed by the collective Gamow–Teller resonance (GTR) at higher energy, 16.3 MeV, in the daughter nucleus 132Sb (in other words, outside the
Figure 1. (Left panel) Schematic view of the neutron and proton levels, with the possible GT transitions between occupied neutron levels and unoccupied proton levels for 132Sn. The figure is inspired by Figure 8 in the study by Rubio et al. (2020). (Right panel) Schematic view of the different approximations used to calculate the
In the next section, we discuss the capability of our theoretical model to account for this picture in 132Sn and other nuclei. The (quasi-particle) random phase approximation (QRPA) can account for the formation of the GTR but not necessarily for the overall strength distribution as it tends to neglect the spreading and fragmentation of such strength. We shall introduce our model (QRPA + QPVC) and explain how it can account for such fragmentation and increase the strength (also) in the
3 Theory
Calculations of the low-lying GT states, starting from an even–even parent nucleus, can be performed within DFT using the linear response theory. We should stress that this approach is parameter-free, although the results can be sensitive to the choice of the energy density functional (EDF), which is not unique. In this contribution, we discuss the results obtained by using local (i.e., Skyrme) EDFs.
The ground state of an even–even nucleus is obtained by minimizing the total energy,
where
which is an eigenvalue equation in the matrix form.
Our formalism for charge-exchange RPA and QRPA on top of BCS was introduced by Fracasso and Colò (2007) [see also Colò et al. (2013) and the web page ns4exp.mi.infn.it that is part of the Theo4Exp platform developed under the EURO-LABS project implemented with the Horizon Europe in program]. We extended this formalism to HFB plus QRPA by Niu et al. (2016), and we refer to this work for details on the above formulas. Other groups have developed charge-exchange QRPA and applied it to the study of
To remedy this shortcoming, we proposed to extend QRPA to QRPA plus quasi-particle–vibration coupling (QRPA plus QPVC). In it, we go beyond the QRPA “linear” assumption, and we propose a more general ansatz for the excited states that we now label by
In formal terms, the QRPA + QPVC eigenstates
The first two terms in this latter equation are the same as in QRPA [see Eq. 6], while the last two terms take into account coupling with the doorway states. In principle, one should solve the equation of motion for this new operator with the same technique that is used in standard QRPA. This means that one should solve
Here,
where the labels
If we project the full QPVC equation in the subspace spanned by the simple two quasi-particle excitations, that is, the QRPA space, and use the basis of the QRPA eigenstates, we obtain
Due to the projection, the matrix becomes energy-dependent and complex (this means that now,
Figure 2. Diagrammatic representation of the four terms whose sum gives the matrix element
With the eigenvalues and eigenvectors, which are the solutions to Eq. 11, we can determine either the strength associated with a general operator or the beta-decay half-lives. The strength function associated with QRPA + QPVC is given as
As briefly mentioned above, the fine structure of the strength distributions, the widths of giant resonances (GRs), and their decay properties are not well described by QRPA because of the lack of coupling with more complex configurations than the two quasi-particles. The particle–vibration coupling (PVC) effects have been proven to be very effective in reproducing the missing physics mentioned above, so that the strength function (Eq. 12) agrees well with experiment. These particle–vibration coupling effects have been included in a self-consistent way, based on nonrelativistic EDFs, first without pairing effects (Colò et al., 1994; Niu et al., 2012) and then in their version with pairing included (Niu et al., 2016; Li et al., 2023). (Q)PVC effects have also been included on top of the covariant version of DFT (Litvinova et al., 2007; Litvinova et al., 2008). In this work, we review the applications of (Q)RPA + (Q)PVC to the study of
Next, we also mention the second RPA (SRPA). The structure of the model has some analogy with RPA + PVC, but the “doorway states,” instead of being particle–hole plus an extra phonon, are two particle–two holes (2p–2h).
4 Results
The first set of results is shown in Figure 3. In this figure, the RPA and RPA + PVC results are compared with the experiment. We chose different Skyrme EDFs: as said, the calculations contain no adjustable parameter, but the results are sensitive to the choice of the functional. There is a general trend that is almost independent of the chosen EDF: the
Figure 3.
In the figure, the arrows indicate the large or infinite half-lives (larger than 106 in the case of this figure). RPA + PVC solves, at least in many, if not all, cases, the puzzle of the very large half-lives. We qualitatively explained this feature in our discussion of Figure 1. In the paradigmatic case of 132Sn, in which we previously mentioned that two states are experimentally observed in the
When the RPA “puzzle” of very large half-lives has become apparent, different solutions have been proposed. One possibility is to invoke an attractive
In summary, our results hint that PVC effects are genuine many-body effects that should be included in
5 Isoscalar pairing
Although the usual neutron–neutron or proton–proton,
The isoscalar pairing strength cannot be unambiguously fixed, and in all calculations, it is more or less left as a free parameter. Often, a parameter
The main motivation of the work by Niu et al. (2018) was to confirm that the conclusion reached for magic nuclei, i.e., that PVC effects play a substantial role in
The effect of the isovector pairing on the
Figure 4.
We confirmed in our work that isoscalar pairing is more important. As mentioned, we expect that isoscalar pairing has effects when the proton and neutron levels with relative
In summary, the QPVC effects and the isoscalar pairing interaction contribute to a decrease in the
6 Deformation, large-scale calculations, and future prospects
Recently, Liu et al. (2024) also advocated that QPVC effects and isoscalar pairing are indeed relevant. However, it is argued that one can draw firmer quantitative conclusions and build a model with real predictive power by considering a larger sample than spherical nuclei. The deformed charge-exchange QRPA was developed by Sarriguren et al. (1998); Sarriguren et al. (1999); Sarriguren et al. (2001) using the BCS scheme. These studies, as well as more recent works, clarified the sensitivity of
Table 1 in the study by Liu et al. (2024) confirms our main statement that QPVC is a very crucial factor, reducing half-lives and aligning them closer to the experimental data. This is confirmed by a different group that employed a quite different implementation and considered axially deformed nuclei instead of spherical nuclei. The scope of the research reported by Liu et al. (2024) is quite broad and ambitious: the idea is to make the approach even more computationally effective, fit a new EDF at the QPVC level, and test the model on large-scale calculations. It remains an open question whether the assumption of axial symmetry has to be abandoned at some stage.
The conclusion and perspectives presented by Liu et al. (2024) raise interesting questions that lie at the very heart of the nuclear many-body problem. Although QRPA + QPVC can certainly catch the most important correlations that affect low-lying nuclear excitations, we still do not know its limitations in a quantitative way. To date, the parameters of an EDF have not been fit at the level of QPVC. Ultimately, we share the opinion expressed by Liu et al. (2024), that is, that if one does so, the scheme goes in the direction of an ab initio solution to the many-body problem. The added value of
Author contributions
GC: conceptualization, data curation, methodology, supervision, writing–original draft, and writing–review and editing. YN: conceptualization, data curation, methodology, supervision, writing–original draft, and writing–review and editing.
Funding
The author(s) declare that financial support was received for the research, authorship, and/or publication of this article. YN acknowledges funding from the National Key Research and Development (R&D) Program under grant no. 2021YFA1601500 and the Natural Science Foundation of China under grant no. 12075104. GC acknowledges funding from the APC fund of the University of Milan, and from the European Union's Horizon Europe research and innovation programme under grant agreement no. 101057511.
Conflict of interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
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Keywords: nuclear density functional theory, quasi-particle–vibration coupling, Skyrme effective interactions, Gamow–Teller transitions, pairing in nuclei
Citation: Colò G and Niu Y (2024) Quasi-particle–vibration coupling approach for nuclear
Received: 21 May 2024; Accepted: 20 June 2024;
Published: 06 August 2024.
Edited by:
Pedro Sarriguren, Spanish National Research Council (CSIC), SpainReviewed by:
Praveen C. Srivastava, Indian Institute of Technology Roorkee, IndiaMyung-Ki Cheoun, Soongsil University, Republic of Korea
Copyright © 2024 Colò and Niu. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Gianluca Colò, Y29sb0BtaS5pbmZuLml0
†ORCID: Gianluca Colò, orcid.org/0000-0003-0819-1633; Yifei Niu, orcid.org/0000-0003-1029-1887