FUSION OF 6 He + 238 U SYSTEM: HALO AND BREAKUP EFFECTS

This paper addresses the validity of the static Woods-Saxon potential and the energy dependent Woods-Saxon potential (EDWSP) for description of sub-barrier fusion dynamics. The low lying surface vibrations of colliding nuclei and neutron transfer channels are found to be major factors responsible for fusion enhancement at sub-barrier energies. Theoretical calculations based upon the static Woods-Saxon potential obtained using the one-dimensional Wong formula fail to explain the energy dependence of the sub-barrier fusion cross-section of + Ca Ti 40 20 46,48,50 22 Keywords: depth and diffuseness of Woods-Saxon potential, coupled channel equations, heavyion sub-barrier fusion reactions, diffuseness anomaly

Section: Introductionmentioning

confidence: 99%

Systematic failure of static nucleus–nucleus potential to explore sub-barrier fusion dynamics

Gautam

2015

“…Among various parameterizations of nuclear potential that have been used in the literature to explain the variety of different phenomena in connection with the heavy ion reactions , the three parametric Woods-Saxon potential is the most widely used. The diffuseness parameter of the Woods-Saxon potential is related to the slope of the nuclear potential in the tail region of the Coulomb barrier and, hence, defines the rate of fall of the fusion excitation function data at sub-barrier energies [34]. A value for the diffuseness parameter = a 0.65 fm has been deduced from the elastic scattering data and it is quite interesting to note that a wide range, = a 0.75 fm to = a 1.5 fm, of values of the diffuseness parameter is required to explore the sub-barrier fusion data [1][2][3][4][5].…”

Section: Introductionmentioning

confidence: 99%

Neutron transfer versus inelastic surface vibrations in the enhancement of sub-barrier fusion excitation function data and the energy dependent Woods–Saxon potential

Gautam¹

2015

This work deeply analyzed the relative importance of the neutron transfer channels and inelastic surface vibrations of colliding nuclei in the sub-barrier fusion enhancement of various heavy ion systems using an energy dependent Woods-Saxon potential (EDWSP) model in conjunction with a one-dimensional Wong formula and the coupled channel formulation using the code CCFULL. The multi-phonon vibrational states of colliding nuclei and the nucleon transfer channels are found to be dominant internal degrees of freedom. The coupling between the relative motion of reactants and these relevant channels produces anomalously large sub-barrier fusion enhancement over the expectations of the one-dimensional barrier penetration model. In some cases, the influence of neutron transfer dominates over the couplings to low lying surface vibrational states of collision partners. Furthermore, the effects of coupling to inelastic surface excitations and the impact of neutron transfer channels with positive ground state Q-values are imitated due to energy dependence in the Woods-Saxon potential. In the EDWSP model calculations, a wide range for the diffuseness parameter, which is much larger than the value extracted from the elastic scattering data, is needed to account for the observed fusion enhancement in the close vicinity of the Coulomb barrier. Keywords: heavy-ion near-barrier fusion reactions, depth and diffuseness of Woods-Saxon potential, coupled channel equations, diffuseness anomaly

“…The existing literature [18][19][20][21][26][27][28][29][30][31][32][33][34][35][36] have cleared that the selection of nucleus-nucleus potential is critical for the understanding the fusion reaction kinetics. Among various nuclear potentials reported in the literature [18][19][20][21][26][27][28][29][30][31][32][33][34][35][36], the simple energy independent Woods-Saxon potential had enjoyed its status to analyze the nuclear interactions.…”

Section: Introductionmentioning

confidence: 99%

Comprehensive analysis of heavy-ion fusion reactions around the Coulomb barrier

Gautam¹,

Ghanghas²,

Chahal³

et al. 2022

We have investigated the fusion dynamics of 12C + 92Zr, 16O + 92Zr, 28Si + 92Zr, 35Cl + 92Zr, 16O + 60Ni, 18O + 58Ni, 12C + 194,198Pt, 16O + 144,148,154Sm and 17O + 144Sm reactions in the close vicinity of the Coulomb barrier. For this purpose, we have opted one-dimensional Wong formula, coupled channel approach, and symmetric-asymmetric Gaussian barrier distribution (SAGBD) model to analyze the fusion data for above mentioned reactions. For all studied systems, the theoretical results obtained from the one-dimensional Wong formula are unable to reproduce the fusion data especially at incident energies lying below the nominal barrier. This appeals for the inclusion of intrinsic degrees of freedom which have been originated from the nuclear structure of fusing nuclei, and thus essentially required to explain the experimental data at energies lying in the sub-barrier realm. For the chosen reactions, the coupled channel analysis suggests that the coupling of relative motion with the inelastic surface excitations and/or nucleon transfer channels associated with the reaction partners have produced a remarkable fusion enhancement at energies lying near and below the nominal barrier. It is particularly intriguing that the SAGBD model can replicate the impacts of dominant intrinsic reaction channels such as multi-phonon quantum states and/or nucleon transfer channels via Gaussian type of weight function. The predictions of the SAGBD approach appropriately reproduce the fusion cross-sections data and related barrier distributions data for the selected reactions due the fact that the multi-dimensional nature induces the barrier lowering effects and subsequently reduces the effective fusion barrier between the participants. In the SAGBD approach, the channel coupling effects are quantitively measured in terms of channel coupling parameter (λ) and percentage decrement in height of effective fusion barrier with respect to the Coulomb barrier (VCBRED ) . Furthermore, the recovered x 2-values for selected reactions are found to be smaller and hence clearly demonstrate the applicability of the model outcomes to explore the fusion dynamics of the studied systems.