2,099 research outputs found
Microscopic calculation of 240Pu scission with a finite-range effective force
Hartree-Fock-Bogoliubov calculations of hot fission in
have been performed with a newly-implemented code that uses the D1S
finite-range effective interaction. The hot-scission line is identified in the
quadrupole-octupole-moment coordinate space. Fission-fragment shapes are
extracted from the calculations. A benchmark calculation for
is obtained and compared to results in the literature. In
addition, technical aspects of the use of HFB calculations for fission studies
are examined in detail. In particular, the identification of scission
configurations, the sensitivity of near-scission calculations to the choice of
collective coordinates in the HFB iterations, and the formalism for the
adjustment of collective-variable constraints are discussed. The power of the
constraint-adjustment algorithm is illustrated with calculations near the
critical scission configurations with up to seven simultaneous constraints.Comment: 18 pages, 24 figures, to be published in Physical Review
Event-by-event study of prompt neutrons from 239Pu(n,f)
Employing a recently developed Monte Carlo model, we study the fission of
240Pu induced by neutrons with energies from thermal to just below the
threshold for second chance fission. Current measurements of the mean number of
prompt neutrons emitted in fission, together with less accurate measurements of
the neutron energy spectra, place remarkably fine constraints on predictions of
microscopic calculations. In particular, the total excitation energy of the
nascent fragments must be specified to within 1 MeV to avoid disagreement with
measurements of the mean neutron multiplicity. The combination of the Monte
Carlo fission model with a statistical likelihood analysis also presents a
powerful tool for the evaluation of fission neutron data. Of particular
importance is the fission spectrum, which plays a key role in determining
reactor criticality. We show that our approach can be used to develop an
estimate of the fission spectrum with uncertainties several times smaller than
current experimental uncertainties for outgoing neutron energies up to 2 MeV.Comment: 17 pages, 20 figure
The microscopic theory of fission
Fission-fragment properties have been calculated for thermal neutron-induced
fission on a target, using constrained
Hartree-Fock-Bogoliubov calculations with a finite-range effective interaction.
A quantitative criterion based on the interaction energy between the nascent
fragments is introduced to define the scission configurations. The validity of
this criterion is benchmarked against experimental measurements of the kinetic
energies and of multiplicities of neutrons emitted by the fragments.Comment: 8 page, 4 figures, to be published in Proceedings of the 4th
International Workshop on Fission and Fission Product Spectroscop
Least Upper Bounds of the Powers Extracted and Scattered by Bi-anisotropic Particles
The least upper bounds of the powers extracted and scattered by
bi-anisotropic particles are investigated analytically. A rigorous derivation
for particles having invertible polarizability tensors is presented, and the
particles with singular polarizability tensors that have been reported in the
literature are treated explicitly. The analysis concludes that previous upper
bounds presented for isotropic particles can be extrapolated to bi-anisotropic
particles. In particular, it is shown that neither nonreciprocal nor
magnetoelectric coupling phenomena can further increase those upper bounds on
the extracted and scattered powers. The outcomes are illustrated further with
approximate circuit model examples of two dipole antennas connected via a
generic lossless network.Comment: 9 pages, 1 figure
A MICROSCOPIC THEORY OF LOW ENERGY FISSION: FRAGMENT PROPERTIES
Abstract not provide
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