Standard

Inverse methods and nuclear radii. / Hefter, E. F.; De Llano, M.; Mitropolsky, I. A.

In: Physical Review C, Vol. 30, No. 6, 01.01.1984, p. 2042-2049.

Research output: Contribution to journalArticlepeer-review

Harvard

Hefter, EF, De Llano, M & Mitropolsky, IA 1984, 'Inverse methods and nuclear radii', Physical Review C, vol. 30, no. 6, pp. 2042-2049. https://doi.org/10.1103/PhysRevC.30.2042

APA

Hefter, E. F., De Llano, M., & Mitropolsky, I. A. (1984). Inverse methods and nuclear radii. Physical Review C, 30(6), 2042-2049. https://doi.org/10.1103/PhysRevC.30.2042

Vancouver

Hefter EF, De Llano M, Mitropolsky IA. Inverse methods and nuclear radii. Physical Review C. 1984 Jan 1;30(6):2042-2049. https://doi.org/10.1103/PhysRevC.30.2042

Author

Hefter, E. F. ; De Llano, M. ; Mitropolsky, I. A. / Inverse methods and nuclear radii. In: Physical Review C. 1984 ; Vol. 30, No. 6. pp. 2042-2049.

BibTeX

@article{f5f607377df44825b573052979f7a95c,
title = "Inverse methods and nuclear radii",
abstract = "In considering spherically symmetric three-dimensional systems, inverse methods are applied to the nuclear bound-state problem. While retaining only the self-interactions of the (occupied) bound-state levels, an analytical solution is obtained for the potential. The simplest possible approximation to it corresponding to a single fictitious bound state is used to evaluate (root mean square) radii. Combining this formula with the well-known A13 dependence of the nuclear radii, a new formula is obtained containing the collective binding energy effect and the one of the saturation of nuclear forces. For absolute and relative radii (of isotopes of Sn, Xe, Nd, Dy, Yb, Os, Hg, Pb, and Pu), the results compare favorably with experiment. In spite of the crude approximations made, this approach yields the typical curvature of the plot of the experimental relative radii as a function of the mass number. The extreme simplicity of the formula recommends its use for global discussions or predictions. Yet, for a correct description of the finer details it is necessary to account explicitly for shell effects and deformations.",
author = "Hefter, {E. F.} and {De Llano}, M. and Mitropolsky, {I. A.}",
year = "1984",
month = jan,
day = "1",
doi = "10.1103/PhysRevC.30.2042",
language = "English",
volume = "30",
pages = "2042--2049",
journal = "Physical Review C - Nuclear Physics",
issn = "0556-2813",
publisher = "American Physical Society",
number = "6",

}

RIS

TY - JOUR

T1 - Inverse methods and nuclear radii

AU - Hefter, E. F.

AU - De Llano, M.

AU - Mitropolsky, I. A.

PY - 1984/1/1

Y1 - 1984/1/1

N2 - In considering spherically symmetric three-dimensional systems, inverse methods are applied to the nuclear bound-state problem. While retaining only the self-interactions of the (occupied) bound-state levels, an analytical solution is obtained for the potential. The simplest possible approximation to it corresponding to a single fictitious bound state is used to evaluate (root mean square) radii. Combining this formula with the well-known A13 dependence of the nuclear radii, a new formula is obtained containing the collective binding energy effect and the one of the saturation of nuclear forces. For absolute and relative radii (of isotopes of Sn, Xe, Nd, Dy, Yb, Os, Hg, Pb, and Pu), the results compare favorably with experiment. In spite of the crude approximations made, this approach yields the typical curvature of the plot of the experimental relative radii as a function of the mass number. The extreme simplicity of the formula recommends its use for global discussions or predictions. Yet, for a correct description of the finer details it is necessary to account explicitly for shell effects and deformations.

AB - In considering spherically symmetric three-dimensional systems, inverse methods are applied to the nuclear bound-state problem. While retaining only the self-interactions of the (occupied) bound-state levels, an analytical solution is obtained for the potential. The simplest possible approximation to it corresponding to a single fictitious bound state is used to evaluate (root mean square) radii. Combining this formula with the well-known A13 dependence of the nuclear radii, a new formula is obtained containing the collective binding energy effect and the one of the saturation of nuclear forces. For absolute and relative radii (of isotopes of Sn, Xe, Nd, Dy, Yb, Os, Hg, Pb, and Pu), the results compare favorably with experiment. In spite of the crude approximations made, this approach yields the typical curvature of the plot of the experimental relative radii as a function of the mass number. The extreme simplicity of the formula recommends its use for global discussions or predictions. Yet, for a correct description of the finer details it is necessary to account explicitly for shell effects and deformations.

UR - http://www.scopus.com/inward/record.url?scp=24444470040&partnerID=8YFLogxK

U2 - 10.1103/PhysRevC.30.2042

DO - 10.1103/PhysRevC.30.2042

M3 - Article

AN - SCOPUS:24444470040

VL - 30

SP - 2042

EP - 2049

JO - Physical Review C - Nuclear Physics

JF - Physical Review C - Nuclear Physics

SN - 0556-2813

IS - 6

ER -

ID: 42280050