Nuclear properties for astrophysical and radioactiveionbeam applications (II)
We tabulate the groundstate oddproton and oddneutron spins and parities, proton and neutron pairing gaps, one and twoneutron separation energies, quantities related to βdelayed one and twoneutron emission probabilities, average energy and average number of emitted neutrons, βdecay energy release and halflife with respect to Gamow–Teller decay with a phenomenological treatment of firstforbidden decays, one and twoproton separation energies, and αdecay energy release and halflife for 9318 nuclei ranging from ^{16}O to ^{339}136 and extending from the proton drip line to the neutron drip line. This work is a new and improved version of Atomic Data And Nuclear Data Tables [66 131 (1997)]. The starting point of our present work is the new study (FRDM(2012)) of nuclear groundstate masses and deformations based on the finiterange droplet model and foldedYukawa singleparticle potential published in a previous issue of Atomic Data And Nuclear Data Tables [109–110, 1 (2016)]. The βdelayed neutronemission probabilities and Gamow–Teller βdecay rates are obtained from a quasiparticle randomphase approximation with singleparticle levels and wave functions at the calculated nuclear groundstate shapes as input quantities. A development since 1997 is we now use a Hauser–Feshbach approach to account for (n, γ) competition and treat firstforbidden decay in a phenomenologicalmore »
 Authors:

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 Los Alamos National Lab. (LANL), Los Alamos, NM (United States)
 Publication Date:
 Report Number(s):
 LAUR1821307
Journal ID: ISSN 0092640X
 Grant/Contract Number:
 AC5206NA25396
 Type:
 Accepted Manuscript
 Journal Name:
 Atomic Data and Nuclear Data Tables
 Additional Journal Information:
 Journal Name: Atomic Data and Nuclear Data Tables; Journal ID: ISSN 0092640X
 Publisher:
 Elsevier
 Research Org:
 Los Alamos National Lab. (LANL), Los Alamos, NM (United States)
 Sponsoring Org:
 USDOE National Nuclear Security Administration (NNSA)
 Country of Publication:
 United States
 Language:
 English
 Subject:
 73 NUCLEAR PHYSICS AND RADIATION PHYSICS; 79 ASTRONOMY AND ASTROPHYSICS
 OSTI Identifier:
 1460654
Moller, P., Mumpower, M. R., Kawano, T., and Myers, W. D.. Nuclear properties for astrophysical and radioactiveionbeam applications (II). United States: N. p.,
Web. doi:10.1016/j.adt.2018.03.003.
Moller, P., Mumpower, M. R., Kawano, T., & Myers, W. D.. Nuclear properties for astrophysical and radioactiveionbeam applications (II). United States. doi:10.1016/j.adt.2018.03.003.
Moller, P., Mumpower, M. R., Kawano, T., and Myers, W. D.. 2018.
"Nuclear properties for astrophysical and radioactiveionbeam applications (II)". United States.
doi:10.1016/j.adt.2018.03.003.
@article{osti_1460654,
title = {Nuclear properties for astrophysical and radioactiveionbeam applications (II)},
author = {Moller, P. and Mumpower, M. R. and Kawano, T. and Myers, W. D.},
abstractNote = {We tabulate the groundstate oddproton and oddneutron spins and parities, proton and neutron pairing gaps, one and twoneutron separation energies, quantities related to βdelayed one and twoneutron emission probabilities, average energy and average number of emitted neutrons, βdecay energy release and halflife with respect to Gamow–Teller decay with a phenomenological treatment of firstforbidden decays, one and twoproton separation energies, and αdecay energy release and halflife for 9318 nuclei ranging from 16O to 339136 and extending from the proton drip line to the neutron drip line. This work is a new and improved version of Atomic Data And Nuclear Data Tables [66 131 (1997)]. The starting point of our present work is the new study (FRDM(2012)) of nuclear groundstate masses and deformations based on the finiterange droplet model and foldedYukawa singleparticle potential published in a previous issue of Atomic Data And Nuclear Data Tables [109–110, 1 (2016)]. The βdelayed neutronemission probabilities and Gamow–Teller βdecay rates are obtained from a quasiparticle randomphase approximation with singleparticle levels and wave functions at the calculated nuclear groundstate shapes as input quantities. A development since 1997 is we now use a Hauser–Feshbach approach to account for (n, γ) competition and treat firstforbidden decay in a phenomenological approach.},
doi = {10.1016/j.adt.2018.03.003},
journal = {Atomic Data and Nuclear Data Tables},
number = ,
volume = ,
place = {United States},
year = {2018},
month = {7}
}