The calculated Q values and half widths of α-decay of superheavy elements using both the S-matrix and the WKB methods are analyzed. The calculations are carried out using the microscopically derived α-daughter potentials for the parents appearing in the α-decay chain of super heavy element (A = 277, Z = 112). Both the S-matrix and the WKB methods though yield comparable results for smaller, in fact negative log τ 1/2 values, the former is superior. However, for the case of positive log τ 1/2 it is found that the S-matrix method though exact, runs into some numerical difficulties. With the discovery of many superheavy elements beyond Z = 100 and their decay processes involving, among others, α-decay chains have revived interest in the careful analysis of Q value of α-decay and the corresponding decay constant. The α-decay of super heavy nuclei has been intensively investigated in recent years [1][2][3][4][5][6][7][8][9][10][11]. If α-decay is understood as a two body phenomena involving the daughter and parent nucleus, a proper approach requires a reliable input of α-daughter nucleus potential. These potentials are introduced either phenomenological [e.g., Woods-Saxon (WS) shape with adjustable parameters] or are generated microscopically in the tρρ approximation (double folding model) using explicitly the calculated nuclear (both proton and neutron) densities. Once such a potential is given the usual procedure of calculating Q value and decay constant is to use WKB type approximations to obtain the energies of long-lived states of the effective potential. In the α-decay problem, the effective potential is the sum of the nuclear potential, electrostatic potential and the centrifugal term. This potential generates a huge pocket in between the Coulomb barrier and the centrifugal barrier and in principle can generate bound states with E < 0 and resonant states with E > 0 with finite lifetime. For a typical α-decay system of our interest, the Coulomb barrier height is about 25 MeV, whereas Q values are in the range 5-10 MeV. Because of the long Coulomb tail, at energies near Q value, the barrier width is quite large of the order of 7-8 fm. As a result the resonance which pertains to α-decay will have in most cases, extremely narrow width. Hence resonance energies can be calculated using WKB method applicable for bound states. Thus in such cases, the positive energy resonant states and bound state energies can be expected to satisfy the equationwhere k 2 and V eff (r) are energy and effective potential respectively inh 2 = 2m = 1 units; they have dimension L −2 . The effective potential V eff includes the centrifugal term (l + 1/2 ) 2 /r 2 , as required in the WKB formula. Here r 1 and r 2 denote the two inner turning points.When this formula is used, in general, one gets a number of positive eigenvalues; however, for the study of α-decay, the eigenvalue which corresponds to the Q value of the α-decay is to be identified. Once this eigenvalue is identified, the decay constant can be calculated using the WKB formula in...
In analogy with the definition of resonant or quasi-bound states used in three-dimensional quantal scattering, we define the quasi-bound states that occur in onedimensional transmission generated by twin symmetric potential barriers and evaluate their energies and widths using two typical examples: (i) twin rectangular barrier and (ii) twin Gaussian-type barrier. The energies at which reflectionless transmission occurs correspond to these states and the widths of the transmission peaks are also the same as those of quasi-bound states. We compare the behaviour of the magnitude of wave functions of quasi-bound states with those for bound states and with the above-barrier state wave function. We deduce a Breit-Wigner-type resonance formula which neatly describes the variation of transmission coefficient as a function of energy at below-barrier energies. Similar formula with additional empirical term explains approximately the peaks of transmission coefficients at above-barrier energies as well. Further, we study the variation of tunnelling time as a function of energy and compare the same with transmission, reflection time and Breit-Wigner delay time around a quasi-bound state energy. We also find that tunnelling time is of the same order of magnitude as lifetime of the quasi-bound state, but somewhat larger.
A comparative study of the S-matrix and the WKB methods for the calculation of the half widths of alpha decay of super heavy elements is presented. The extent of the reliability of the WKB methods is demonstrated through simple illustrative examples. Detailed calculations have been carried out using the microscopic alpha-daughter potentials generated in the framework of the double-folding model using densities obtained in the relativistic mean field theories. We consider alpha-nucleus systems appearing in the decay chains of super heavy parent elements having A = 277, Z = 112 and A = 269, Z = 110. For negative and small positive log τ 1/2 values the results from both methods are similar even though the S-matrix results should be considered to be more accurate. However, when log τ 1/2 values are large and positive, the width associated with such state is infinitesimally small and hence calculation of such width by the S-matrix pole search method becomes a numerically difficult problem. We find that overall, the WKB method is reliable for the calculation of half lives of alpha decay from heavy nuclei.
We examine the behavior of transmission coefficient T across the rectangular barrier when attractive potential well is present on one or both sides and also the same is studied for a smoother barrier with smooth adjacent wells having Woods-Saxon shape. We find that presence of well with suitable width and depth can substantially alter T at energies below the barrier height leading to resonant-like structures. In a sense, this work is complementary to the resonant tunneling of particles across two rectangular barriers, which is being studied in detail in recent years with possible applications in mind. We interpret our results as due to resonant-like positive energy states generated by the adjacent wells. We describe in detail the possible potential application of these results in electronic devices using n-type oxygen-doped gallium arsenide and silicon dioxide. It is envisaged that these results will have applications in the design of tunneling devices.
Analysis of16O +28Si elastic scattering in the laboratory energy range 50.0 MeV to 142.5 MeV
We have successfully carried out an optical model analysis of 16O + 28Si differential scattering cross section σ(θ) in the laboratory energy range EL from 50.0 MeV to 142.5 MeV and angular range θ from 0° to 100° using the LC potential suggested by Lee and Chan. This potential is very successful in explaining the differential cross section σ(θ) at EL = 50.0 and 55.0 MeV in the entire centre of mass angle range reproducing the enhanced back angle oscillations correctly. The LC potential has only seven parameters, including the Coulomb radius parameter, which is much smaller than the number of parameters used in recent calculations on the system. In the light of an excellent fit to the data, we make a detailed analysis of different features of the LC potential and compare it with the typical heavy-ion potential having a Woods–Saxon (WS) form factor used in the analysis of 18O + 58Ni at EL = 60.0 MeV. These features include the behaviour of the real effective potential around grazing partial wave (ℓg), angular momentum (ℓ) dependence of classical deflection function (Θ), reflection function |Sℓ| and the term |1 − Sℓ|2 governing the total partial wave elastic cross section. We also calculate the barrier region resonance positions generated by the partial waves around ℓg. We find that the orbiting phenomenon generated by the flatter, surface transparent effective potential and the resulting coherent behaviour of only a small number of partial waves in the surface region, resulting in the interference of absorptive region and Coulombic region amplitudes, are primarily responsible for back angle oscillations. As a quantum-mechanical consequence of orbiting behaviour, we find close clustering of resonances corresponding to a set of partial waves around ℓg which is the special feature of the LC potential. On the basis of this, we envisage that 16O + 28Si is likely to show large enhanced back angle oscillations at EL = 66.0 and 72.0 MeV. It will be interesting if this is experimentally investigated.
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