Cococubed.com dS/dT from the LS and an NSE EOS
Home Teaching materials Astronomy research Astronomy codes ... Stellar equation of states ... EOS with ionization ... EOS for supernovae ... Chemical potentials ... Stellar atmospheres ... Voigt Function ... Polytropic stars ... Cold white dwarfs ... Hotter white dwarfs ... Cold neutron stars ... Stellar opacities ... Neutrino energy loss rates ... Ephemeris routines ... Fermi-Dirac functions ... Galactic chemical evolution ... Nuclear reaction networks ... Nuclear statistical equilibrium ... Laminar deflagrations ... CJ detonations ... ZND detonations ... Fitting to conic sections ... Unusual linear algebra ... Derivatives on uneven grids ... Pentadiagonal solver ... Quadratics, Cubics, Quartics ... Supernova light curves ... Exact Riemann solutions ... 1D PPM Hydrodynamics ... Verification problems ... EZ stellar evolution ... FLASH code ... Mesa code Astronomy talks Astronomy images Outreach Family album Bicycle adventures Artwork Contact us: J.D. Maldonado F.X.Timmes, my vitae	The electron-positron portion of the two equations of state are identical. Differences between the two EOS routines originate from the model used for nucleons (interacting nucleons in a liquid dropish model versus non-interacting Boltzmann nucleons), and the model used for the composition. LS Baryonic dS/dT: dS/dT from baryons Ye=0.5 dS/dT from baryons Ye=0.4 dS/dT from baryons Ye=0.3 dS/dT from baryons Ye=0.2 LS Total dS/dT: Total dS/dT Ye=0.5 Total dS/dT Ye=0.4 Total dS/dT Ye=0.3 Total dS/dT Ye=0.2 NSE Baryonic dS/dT: dS/dT from baryons Ye=0.5 dS/dT from baryons Ye=0.4 dS/dT from baryons Ye=0.3 dS/dT from baryons Ye=0.2 NSE Total dS/dT: Total dS/dT Ye=0.5 Total dS/dT Ye=0.4 Total dS/dT Ye=0.3 Total dS/dT Ye=0.2 LS and NSE dS/dT Compared: dS/dT Ye=0.5 dS/dT Ye=0.4 dS/dT Ye=0.3 dS/dT Ye=0.2 dS/dT differences Ye=0.5 dS/dT differences Ye=0.4 dS/dT differences Ye=0.3 dS/dT differences Ye=0.2