Programs in Physics & Physical Chemistry
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Programs in Physics & Physical Chemistry |
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| PROGRAM SUMMARY | ||
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| Manuscript Title: RADCAP: a potential model tool for direct capture reactions. | ||
| Authors: C.A. Bertulani | ||
| Program title: RADCAP | ||
| Catalogue identifier: ADSH | ||
| Journal reference: Comput. Phys. Commun. 156(2003)123 | ||
| Programming language: Fortran 77. | ||
| Computer: IBM-PC and UNIX machines. | ||
| Operating system: Windows, UNIX. | ||
| RAM: 1M words | ||
| Keywords: Potential model, Photodissociation, Radiative capture, Astrophysical S-factors, Nuclear Physics, Direct reactions. | ||
| Classification: 17.11. | ||
Nature of problem: The program calculates bound and continuum wavefunctions, phase-shifts and resonance widths, astrophysical S-factors, and other quantities of interest for direct capture reactions. | ||
Solution method: Solves the radial Schrodinger equation for bound and for continuum states. First the eigenenergy is estimated by using the WKB method. Then a Numerov integration is used outwardly and inwardly and a matching at the nuclear surface is done to obtain the energy and the bound state wavefunction with good accuracy. The continuum states are obtained by a Runge-Kutta integration, matching the Coulomb wavefunctions at large distances outside the range of the nuclear potential. | ||
Running time: Almost all the CPU time is consumed by the solution of the radial Schrodinger equation. It is about 1 minute on a 1GHz Intel P4-processor machine for a Woods-Saxon potential. |
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