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It is well known that the extracted values for spectroscopic amplitudes from scattering and transfer reactions are highly dependent on the potential parameters used in the various analyses. Based on this fact, the experimental data for the 14N+10B nuclear system were first analyzed under the assumption of pure potential scattering. In this case, the differential cross sections were calculated in the framework of the phenomenological optical model and the interaction potential was found by fitting the calculated cross sections to the experimental data. The considered total potential is the sum of three terms: a)
${V_C}(R)$ : Coulomb potential of a uniform charged sphere with radius parameter fixed at 1.3 fm; b) real volume part; and c) an imaginary volume part of nuclear potential with both Woods-Saxon shapes. Thus, the total potential has the following shape:$\begin{split} U{\rm{(}}R{\rm{)}} =& {V_C}(R) - {\rm{ }}{V_0}{\left[ {1 + \exp \left( {\frac{{r - {R_V}}}{{{a_V}}}} \right)} \right]^{ - 1}} \\&- {\rm i}{W_0}{\left[ {1 + \exp \left( {\frac{{r - {R_W}}}{{{a_W}}}} \right)} \right]^{ - 1}}, \end{split}$
(1) where V0, aV and W0, aW are the depths and diffusenesses of the real and imaginary parts of the nuclear potential, respectively. Radii in these expressions are defined as
${{R}_{V,W,C}}={{r}_{V,W,C}}{\rm{ x }}\left( {\rm{A}}_{\rm{p}}^{{}^{\rm{1}}\!\!\diagup\!\!{}_{3}\;}+{\rm{A}}_{\rm{t}}^{{}^{\rm{1}}\!\!\diagup\!\!{}_{3}\;} \right)$ . In addition to our measurements for 14N+10B elastic scattering angular distributions at Elab=21.0 and 24.5 MeV, we also reanalyzed data at all the available energies: at Elab=38.1, 42.0, 46.0, and 50.0 MeV, taken from Ref. [2], and at Elab= 73.92 and 93.6 MeV, taken from Ref. [8], in order to obtain energy-dependent potential parameters for this nuclear system. We performed OM calculations using starting parameters taken from Ref. [8], and only the three parameters V0, W0, and aW were varied and the other three, rV, rW, and aV, were fixed at 0.92, 1.29, and 0.77 fm, respectively.Angular distributions at energies of 24.5–50.0 MeV showed a significant increase in differential cross sections at backward angles, which was assumed to arise from the contribution of α-cluster transfer between 14N and 10B. The experimental data at 21.0 MeV, which is closer to the Coulomb barrier energy for the 14N+10B nuclear system, only showed a slight increase in cross sections at backward angles. However, a rise is already observed at energy 24.5 MeV, confirming that the transfer phenomenon is highly dependent on the projectile’s energy. The angular distributions at the two higher energies 73.92 and 93.6 MeV were measured in a limited angular range and did not extend beyond ~ 50°, and thus, the transfer phenomenon is not presented.
As mentioned above, experimental data in the energy range 21–50 MeV showed a significant increase in cross sections at backward angles, except at Elab=21.0 MeV, which showed a slight increase. Such increase in cross sections could not be reproduced by the simple OM, and its origin was investigated in terms of α-cluster transfer implemented through the distorted waves Born approximation (DWBA) method. As the ground state spin-parity of 14N is Jπ=1+, an alpha particle coupled to a 10B core with Jπ=3+ can be found in two differential orbitals with angular momentum L=2 or L=4. The configuration with the higher angular momentum should be favored as the cluster configuration with L=4 has a theoretical spectroscopic factor much larger than that of the one with L=2 (SA2=0.11 and SA4=0.83) [10]. However, two possible configurations have been taken into account. The experimental angular distributions at the different energies were analyzed up to angles 90° by the optical model to exclude the effect of cluster transfer and other effects that could affect the cross sections at backward angles using the FRESCO code [11]. The comparisons between the experimental angular distributions in the energy range 21–93.6 MeV and theoretical calculations using both OM and DWBA, incorporated in the Coupled Reactions Channels program (FRESCO) [11], are shown in Figs. 3-5 with the potential parameters listed in Table 1.
E/MeV Model V0/MeV W0/MeV aW/fm χ2/N SA σR/mb 21.0 OM 98.02±5.0 14.39±0.7 0.39 0.18 623.4±30 DWBA – L=2 0.21 0.69±0.04 DWBA – L=4 0.47 0.93±0.04
24.5 OM 99.33±5.0 14.51±0.7 0.44 0.57 789.4±39 DWBA – L=2 1.25 0.42±0.04 DWBA – L=4 2.4 0.77±0.04
38.1 OM 87.24±4.3 17.0±0.8 0.45 5.8 1121±56 DWBA – L=2 18.6 0.61±0.033 DWBA – L=4 7.9 0.8±0.033
42.0 OM 86.8±4.3 18.0±0.9 0.476 6.54 1198±60 DWBA – L=2 42.2 0.62±0.02 DWBA – L=4 23.6 0.78±0.02
46.0 OM 84.35±4.2 22.0±1.1 0.402 4.3 1173±60 DWBA – L=2 14.3 0.59± 0.03 DWBA – L=4 6.7 0.76± 0.03
50.0 OM 83.15±4.2 23.0±1.2 0.393 9.3 1197±60 DWBA – L=2 17.5 0.56±0.03 DWBA – L=4 15.5 0.81±0.03
73.9 OM 76±3.8 28.0±1.4 0.373 4.3 1288±60
93.6 OM 64±3.2 33.0±1.6 0.358 11.3 1313±60 Table 1. Optical potential parameters for the 14N+10B system at different energies, together with spectroscopic amplitudes extracted from the DWBA analysis. Note that χ2/N values (normalized per number of experimental points) refer to θc.m.<90° for the elastic scattering and the full angular range for the DWBA calculations. The parametersrV, rW, and aV were fixed at 0.92, 1.29, and 0.77 fm, respectively.
Figure 3. (color online) Comparison between the experimental data (black circles) and calculations for the 10B(14N,14N)10B elastic scattering at Elab= 21.0, 24.5, and 38.1 MeV. The dashed black curves denote pure optical model fits to the data for angles θc.m.< 90◦. The dashed red and solid blue curves denote the results of calculations taking into account the process of elastic transfer of the α-particle in the10B(14N,10B)14N reaction to L= 2 and L= 4 orbitals, respectively.
Figure 4. (color online) Same as Fig. 3 but at energies 42.0, 46.0, and 50.0 MeV.
Figure 5. Comparison between experimental angular distributions for 10B(14N,14N)10B elastic scattering at Elab= 73.92 and 93.6 MeV (black circles) and the theoretical calculations (dashed curves) using OM.
The significant increase in differential cross sections at large angles can be explained as arising from α-cluster transfer as shown by DWBA calculations that were performed to explore this possibility. In this case, the exchange of the α-cluster between the two interacting nuclei 14N, to be treated as (10B – Core) + (α-particle – valence), leads to an exit channel that is physically indistinguishable from the entrance channel. Therefore, the differential cross section is the square of the sum of amplitudes from the pure elastic scattering and the exchange mechanism of the cluster transfer, as follows [12, 13]:
$ \frac{{{\rm d}{\sigma _{el}}}}{{{\rm d}\Omega }} = {\left| {{f_{el}}\left( \theta \right) + {{\rm e}^{{\rm i}\alpha }}S{f_{\rm DWBA}}\left( {\pi - \theta } \right)} \right|^2}, $
(2) where
${f_{el}}(\theta )$ is the elastic scattering amplitude,${f_{\rm DWBA}}(\pi - \theta )$ is the amplitude calculated using the distorted wave method with the replacement$\theta \to \pi - \theta $ , parameter α = pi (coherence of amplitudes), and S is the product of the two spectroscopic amplitudes (SA) of the transferred particle in the entrance and exit channels, which are the same in the case of elastic transfer.Calculations of transfer are performed using the optical potential parameters obtained from fitting the data in the forward hemisphere up to 90°. The bound state wave function for the relative motion of the α-particle and 10B in the 14N configuration cluster plus core is defined by a Woods-Saxon potential with fixed radius
$R=1.25{\rm{x }} $ $\left( 4_{{}}^{{}^{1}\!\!\diagup\!\!{}_{3}\;}+10_{{}}^{{}^{1}\!\!\diagup\!\!{}_{3}\;} \right)$ fm and the diffuseness a = 0.65 fm. The potential depth was adjusted to reproduce the binding energy of the cluster (11.612 MeV). The quantum numbers of the radial motion of the clusters relative to the core were determined from the following expression of the shell model [13, 14]:$ 2(N - 1) + L = \sum\limits_{i = 1}^n {2({n_i}} - 1) + {l_i}, $
(3) where N is the number of nodes of the radial wave function of relative motion (taking into account the node at r = 0) and L is the corresponding orbital momentum of the cluster; Σ denotes the sums of similar quantities for nucleons entering a cluster in a bound state. Two different sets for cluster quantum numbers for the overlaps
$\left\langle {{{}^{{\rm{14}}}{\rm{N}}}} | {{\alpha { + ^{{\rm{10}}}}{\rm{B}}}} \right\rangle $ are used in our calculations, as listed in Table 2, due to the two possibilities of transfer to L=2 and L=4 orbitals. The same potential parameters are taken for the entrance channel (14N+10B) and the exit channel (10B+14N). The spectroscopic amplitude was taken as a free parameter that is varied to give the best agreement between the theoretical calculations and the experimental data. The variation of the extracted SA2 and SA4 with χ2/N at Elab= 21–50 MeV is shown in Figs. 6 and 7, respectively. The values of SA2 and SA4 at the different energies are listed in Table 1. As can be seen, the average values of SA2 and SA4 are 0.58 ± 0.10 and 0.81 ± 0.12, respectively. The obtained SA2 value overestimates the theoretical value calculated by Kurath [10] in the framework of the shell model, whereas the extracted SA4 is in good agreement.Overlap N(Number of nodes) L S J = L+S Binding energy/MeV $\left\langle {{{}^{{\rm{14}}}{\rm{N}}}} / {{^{{\rm{10}}}{\rm{B}} + \alpha }} \right\rangle $ 2 2 0 2 11.612 1 4 0 4 Table 2. Cluster quantum numbers for the overlaps used in our calculations.
Figure 6. (color online) Variation of χ2/N with extracted SA2 at Elab = 21, 24.5, 38.1, 42.0, 46.0, and 50.0 MeV.
Figure 7. (color online) Variation of χ2/N with extracted SA4 at Elab= 21, 24.5, 38.1, 42.0, 46.0, and 50.0 MeV.
As can be seen from Figs. 3 and 4 and Table 1, the values of dσ/dσRU at the largest angles (dσ/dσRU~0.2) and the spectroscopic amplitudes are practically independent of the beam energy. The same result was obtained in Ref. [2].
The contribution of the α-cluster in forming the cross sections at backward angles at E = 46.0 MeV, measured by Takai et al. [2], was analyzed within the framework of the DWBA method by code LOLA [15]. Their and our analyses are compatible at the forward angles region, but there is a significant difference at the backward angles, as shown in Fig. 8. However, in Ref. [2], they did not present χ2/N when comparing both theoretical calculations. However, it is clearly shown in Fig. 8 that the current analysis is much better. Our analysis at 46.0 MeV could reproduce the experimental data well, especially at angles > 160°, whereas in the previous analysis the data and the calculations are completely out of phase at large angles (> 160°). It is noteworthy that the extracted SA4 at E = 46.0 MeV from the current work (0.76) is so close to the used SA4 (0.806) in Ref. [2].
Figure 8. (color online) Comparison between the experimental angular distribution for 14N+10B elastic transfer at large angles region (black circles) and the current DWBA calculations (solid red curves). The dashed black curve displays the results of Ref. [2].
As mentioned before, the investigation of the 10B(14N,10B)14N α-cluster transfer process to L=2 and L=4 orbitals individually leads to an extracted SA4 value of “0.81 ± 0.12”, which is close to the theoretical value calculated by Kurath [10], whereas the extracted SA2 exceeds the theoretical value. Therefore, further calculations were performed to study the 10B(14N,10B)14N α-cluster transfer process by taking into consideration the transfer to L=2 and L=4 orbitals simultaneously. The potential parameters listed in Table 1 are used in the theoretical calculations. The optimal SA2 and SA4 values were searched using the SFRESCO search code [11]. During the search process, SA2 and SA4 were allowed to be changed freely in the range 0.05–0.7 and 0.6–0.95, respectively, till the best agreement between experimental data and calculations was reached. The starting parameters for SA2 and SA4 are 0.1 and 0.83, respectively; these values are adopted from the work of Kurath [10]. The optimal extracted values for SA2 and SA4,as well as the χ2 / N values, at different concerned energies using this technique are listed in Table 3. The comparison between the experimental data and the theoretical calculations using this method are shown in Figs. 9 and 10. Although in an elastic transfer process the entrance and exit channels are identical and consequently the same SA should be taken for both channels, in this case the value of SA2 was used as the spectroscopic amplitude for the entrance channel and the value of SA4 was used as the spectroscopic amplitude for the exit channel. Thus, the experimental differential cross sections
${\left( {\dfrac{{{\rm d}\sigma }}{{{\rm d}\Omega }}} \right)_{\exp }}$ are assumed to be described as a coherent sum:E/MeV SA2 SA4 χ2/N 21.0 0.7±0.11 0.81±0.02 0.26 24.5 0.2±0.04 0.65±0.01 2.3 38.1 0.54±0.01 0.75±0.02 10.9 42.0 0.47±0.01 0.81±0.02 31.7 46.0 0.57±0.01 0.79±0.01 17.3 50.0 0.5±0.01 0.65±0.01 15.4 Table 3. Optimal extracted values for SA2 and SA4 at the different energies (E), taking into account the contribution from L=2 and L=4 orbitals simultaneously as well as the χ2/N values.
Figure 9. Comparison between the experimental data (black circles) and DWBA calculations including the 10B(14N,10B)14N elastic transfer process to L=2 and L=4 orbitals simultaneously at energies 21.0, 24.5, and 38.1 MeV.
Figure 10. Same as Fig. 9 but at energies 42.0, 46.0, and 50.0 MeV.
$ {\left( {\frac{{{\rm d}\sigma }}{{{\rm d}\Omega }}} \right)_{{\rm{exp}}}} = {\left( {\frac{{{\rm d}\sigma }}{{{\rm d}\Omega }}} \right)_{{\rm{DWBA (}}L = {\rm{2)}}}} + {\left( {\frac{{{\rm d}\sigma }}{{{\rm d}\Omega }}} \right)_{{\rm{DWBA (}}L = 4{\rm{)}}}}. $
(4) As mentioned above, in the work of Takai et al. [2], the spectroscopic amplitude close to our value was used to reproduce the experimental angular distributions for 10B(14N,10B)14N elastic transfer at all the considered energies. Nevertheless, in the work of Motoboyashi [8], the extracted SA was 1.3. This discrepancy between the spectroscopic amplitudes predicted by theory and those deduced by a DWBA analysis was reported early by many authors (see, for example, [16, 17]) and points to the need for further experimental as well as theoretical exploration of scattering the 1p-shell nuclei.
Figure 11 shows the energy dependence of the found by us potentials, which are listed in Table 1. It is seen that a linear function is a fair approximation for the energy dependence for the depths of the real and imaginary parts of the optical potentials in the energy range from 20 to 100 MeV for the 10B+14N system. With increasing energy, the depth of the real potential decreases and can be approximated by the formula V0 = 107.2-0.46E, and the depth of the imaginary potential increases and is well described by the formula W0 = 8.19+0.268E.
An important and useful characteristic of optical potentials is the volume integrals over V(r) and W(r),
$ {J}_{V}=\frac{1}{{A}_{p}{A}_{t}}\int V\left(r\right)4\pi {r}^{2}{\rm d}r \;\;\;\;{\rm{and}}\;\;\;\;{J}_{W}=\frac{1}{{A}_{p}{A}_{t}}\int W\left(r\right)4\pi {r}^{2}{\rm d}r. $
(5) where Ap and At denote the masses of projectile (p) and target nucleus (t), respectively.
The volume integrals corresponding to the found potentials, as well as the depths, smoothly vary depending on the energy within 200–300 MeV fm3 for JV and 70–210 MeV fm3 for JW. This is consistent with similar dependencies known from the scattering of p + 12С, 3He + 12С, α + 12С, and 12С + 12С [18-20]. Our potentials are physically reasonable, as their volume integrals (JV) are close to that calculated by microscopic models [18].
The energy dependence of the total reaction cross sections σR obtained in this work is presented in Fig. 12. It can be seen that the rapid growth of cross sections at energies in the range of 20–40 MeV is replaced by a slower one at Е greater than 50 MeV.
Figure 12. (color online) Energy dependence of the extracted total reaction cross sections for the 10B(14N, 14N)10B elastic scattering from the current work.
It is well known that the total reaction cross section calculated in the framework of the optical model is practically independent of the details of the real part of the optical potential and is mainly determined by the parameters of its imaginary part, the depth of which, as can be seen from Table 1, increases from 14 to 33 MeV with increasing energy up to 93 MeV. The calculated energy dependence of the total cross sections is adequately approximated by the expression:
${{\sigma }_{R}}(E)=1.3 \pi {{\left( A_{P}^{{}^{1}\!\!\diagup\!\!{}_{3}\;}+A_{T}^{{}^{1}\!\!\diagup\!\!{}_{3}\;} \right)}^{2}}\left( 15.97-\frac{12.25}{E}-\frac{3595.1}{{{E}^{2}}} \right).$
(6)
New measurements and reanalysis of 14N elastic scattering on 10B target
- Received Date: 2020-03-16
- Accepted Date: 2020-05-30
- Available Online: 2020-10-01
Abstract: The angular distributions of elastic scattering of 14N ions on 10B targets have been measured at incident beam energies of 21.0 and 24.5 MeV. Angular distributions at higher energies 38–94.0 MeV (previously measured) were also included in the analysis. All data were analyzed within the framework of the optical model and the distorted waves Born approximation method. The observed rise in cross sections at large angles was interpreted as a possible contribution of the α-cluster exchange mechanism. Spectroscopic amplitudes SA2 and SA4 for the configuration 14N→ 10B +α were extracted. Their average values are 0.58±0.10 and 0.81±0.12 for SA2 and SA4, respectively, suggesting that the exchange mechanism is a major component of the elastic scattering for this system. The energy dependence of the depths for the real and imaginary potentials was found.