Dense matter and the compressible liquid drop model
Lorenz, Carl Philip
This item is only available for download by members of the University of Illinois community. Students, faculty, and staff at the U of I may log in with your NetID and password to view the item. If you are trying to access an Illinois-restricted dissertation or thesis, you can request a copy through your library's Inter-Library Loan office or purchase a copy directly from ProQuest.
Permalink
https://hdl.handle.net/2142/18900
Description
Title
Dense matter and the compressible liquid drop model
Author(s)
Lorenz, Carl Philip
Issue Date
1991
Doctoral Committee Chair(s)
Ravenhall, D.G.
Department of Study
Physics
Discipline
Physics
Degree Name
Ph.D.
Degree Level
Dissertation
Keyword(s)
dense matter
compressible liquid drop model
supernova
neutron star
astrophysics
Language
en
Abstract
We explore the equation of state of dense matter at densities up to nuclear
matter density using the compressible liquid drop model. We consider two primary
areas of application: the collapsing core of supernovae and the inner crust of a cooled
neutron star. The model is generalized to include a refined description of the nuclear
surface properties as well as a number of smaller physical effects. We also adapt it to
accommodate droplet shapes other than the customary spherical clusters in order to
study the phase character of matter in these astrophysical situatipns.
We present the results of a Hartree-Fock finite-temperature calculation of nuclear
surface and curvature thermodynamic potentials, using phenomenological forces. These
are the requisite ingredients needed for the model. For our purposes, we calculate these
properties over the complete range of proton fraction (0 to 0.5). The self-consistent
method is exploited to extract an approximation for neutron evaporation rates from hot
nuclear surfaces.
Dense matter at fixed overall proton fraction of Yp = 0.3 is considered at densities up
to nuclear saturation density at low temperatures. We lay the framework, however, to
explore matter at temperatures that one would expect in the collapsing supernova core.
Matter in beta equilibrium is considered at low temperatures; this is the character of the
matter that one expects to exist in the inner crust of a cooled neutron star. We obtain
for the first time the density range occupied by the non-spherical nuclear shapes.
Use this login method if you
don't
have an
@illinois.edu
email address.
(Oops, I do have one)
IDEALS migrated to a new platform on June 23, 2022. If you created
your account prior to this date, you will have to reset your password
using the forgot-password link below.
