! history_columns.list -- determines the contents of star history logs ! you can use a non-standard version by setting history_columns_file in your inlist ! units are cgs unless otherwise noted. ! reorder the following names as desired to reorder columns. ! comment out the name to omit a column (fewer columns => less IO => faster running). ! remove '!' to restore a column. ! if you have a situation where you want a non-standard set of columns, ! make a copy of this file, edit as desired, and give the new filename in your inlist ! as history_columns_file. if you are just adding columns, you can 'include' this file, ! and just list the additions in your file. note: to include the standard default ! version, use include '' -- the 0 length string means include the default file. ! blank lines and comments can be used freely. ! if a column name appears more than once in the list, only the first occurrence is used. ! if you need to have something added to the list of options, let me know.... ! the first few lines of the log file contain a few items: ! version_number -- for the version of mesa being used ! burn_min1 -- 1st limit for reported burning, in erg/g/s ! burn_min2 -- 2nd limit for reported burning, in erg/g/s !# other files ! note: you can include another list by doing ! include 'filename' ! include '' means include the default standard list file ! the following lines of the log file contain info about 1 model per row !---------------------------------------------------------------------------------------------- !# general info about the model model_number ! counting from the start of the run num_zones ! number of zones in the model !version_number ! mesa version from file mesa/data/version_number !## age star_age ! elapsed simulated time in years since the start of the run !star_age_sec ! elapsed simulated time in seconds since the start of the run !star_age_min ! elapsed simulated time in minutes since the start of the run !star_age_hr ! elapsed simulated time in hours since the start of the run !star_age_day ! elapsed simulated time in days since the start of the run !log_star_age !log_star_age_sec !## timestep !time_step ! timestep in years since previous model !time_step_sec ! timestep in seconds since previous model log_dt ! log10 time_step in years !log_dt_sec ! log10 time_step in seconds !## mass star_mass ! in Msun units !log_star_mass !star_gravitational_mass ! star_mass is baryonic mass !star_mass_grav_div_mass !delta_mass ! star_mass - initial_mass in Msun units log_xmstar ! log10 mass exterior to M_center (grams) !## mass change !star_mdot ! d(star_mass)/dt (in msolar per year) log_abs_mdot ! log10(abs(star_mdot)) (in msolar per year) !## imposed surface conditions !Tsurf_factor !tau_factor !tau_surface !surface_extra_Pgas !## imposed center conditions !m_center !m_center_gm !r_center !r_center_cm !L_center !log_L_center !log_L_center_ergs_s !v_center !---------------------------------------------------------------------------------------------- !# mixing and convection !max_conv_vel_div_csound !max_gradT_div_grada !max_gradT_sub_grada !min_log_mlt_Gamma !max_conv_dP_term !## mixing regions mass_conv_core ! (Msun) mass coord of top of convective core. 0 if core is not convective ! mx1 refers to the largest (by mass) convective region. ! mx2 is the 2nd largest. ! conv_mx1_top and conv_mx1_bot are the region where mixing_type == convective_mixing. ! mx1_top and mx1_bot are the extent of all kinds of mixing, convective and other. ! values are m/Mstar conv_mx1_top conv_mx1_bot conv_mx2_top conv_mx2_bot mx1_top mx1_bot mx2_top mx2_bot ! radius -- values are radii in Rsun units !conv_mx1_top_r !conv_mx1_bot_r !conv_mx2_top_r !conv_mx2_bot_r !mx1_top_r !mx1_bot_r !mx2_top_r !mx2_bot_r ! you might want to get a more complete list of mixing regions by using the following !mixing_regions ! note: this includes regions where the mixing type is no_mixing. ! the is the number of regions to report ! there will be 2* columns for this in the log file, 2 for each region. ! the first column for a region gives the mixing type as defined in const/public/const_def.f90. ! the second column for a region gives the m/mstar location of the top of the region ! entries for extra columns after the last region in the star will have an invalid mixing_type value of -1. ! mstar is the total mass of the star, so these locations range from 0 to 1 ! all regions are include starting from the center, so the bottom of one region ! is the top of the previous one. since we start at the center, the bottom of the 1st region is 0. ! the columns in the log file will have names like 'mix_type_1' and 'mix_qtop_1' ! if the star has too many regions to report them all, ! the smallest regions will be merged with neighbors for reporting purposes only. !mix_relr_regions ! same as above, but locations given as r/rstar instead of m/mstar. ! the columns in the log file will have names like 'mix_relr_type_1' and 'mix_relr_top_1' !## conditions at base of largest convection zone (by mass) !cz_bot_mass ! mass coordinate of base (Msun) !cz_mass ! mass coordinate of base (Msun) -- same as cz_bot_mass !cz_log_xmass ! mass exterior to base (g) !cz_log_xmsun ! mass exterior to base (Msun) !cz_xm ! mass exterior to base (Msun) !cz_logT !cz_logRho !cz_logP !cz_bot_radius ! Rsun !cz_log_column_depth !cz_log_radial_depth !cz_luminosity ! Lsun !cz_opacity !cz_log_tau !cz_eta !cz_log_eps_nuc ! log10(ergs/g/s) !cz_t_heat ! Cp*T/eps_nuc (seconds) !cz_csound !cz_scale_height !cz_grav !cz_omega !cz_omega_div_omega_crit !cz_zone ! mass fractions at base of largest convection zone (by mass) !cz_log_xa h1 !cz_log_xa he4 !## conditions at top of largest convection zone (by mass) !cz_top_mass ! mass coordinate of top (Msun) !cz_top_log_xmass ! mass exterior to top (g) !cz_top_log_xmsun ! mass exterior to top (Msun) !cz_top_xm ! mass exterior to top (Msun) !cz_top_logT !cz_top_logRho !cz_top_logP !cz_top_radius ! Rsun !cz_top_log_column_depth !cz_top_log_radial_depth !cz_top_luminosity ! Lsun !cz_top_opacity !cz_top_log_tau !cz_top_eta !cz_top_log_eps_nuc ! log10(ergs/g/s) !cz_top_t_heat ! Cp*T/eps_nuc (seconds) !cz_top_csound !cz_top_scale_height !cz_top_grav !cz_top_omega !cz_top_omega_div_omega_crit !cz_top_zone !cz_top_zone_logdq ! mass fractions at top of largest convection zone (by mass) !cz_top_log_xa h1 !cz_top_log_xa he4 !---------------------------------------------------------------------------------------------- !# nuclear reactions !## integrated quantities !power_h_burn ! total thermal power from PP and CNO, excluding neutrinos (in Lsun units) !power_he_burn ! total thermal power from triple-alpha, excluding neutrinos (in Lsun units) !power_c_burn ! total thermal power from carbon burning, excluding neutrinos (in Lsun units) !log_power_nuc_burn ! total thermal power from all burning, excluding photodisintegrations log_LH ! log10 power_h_burn log_LHe ! log10 power_he_burn !log_LC ! log10 power_c_burn log_LZ ! log10 total burning power including LC, but excluding LH and LHe and photodisintegrations log_Lnuc ! log(LH + LHe + LZ) !log_Lnuc_ergs_s !log_Lnuc_sub_log_L !extra_L ! integral of extra_heat in Lsun units !log_extra_L ! log10 extra_L !## neutrino losses !log_Lneu ! log10 power emitted in neutrinos, nuclear and thermal (in Lsun units) !log_Lneu_nuc ! log10 power emitted in neutrinos, nuclear sources only (in Lsun units) !log_Lneu_nonnuc ! log10 power emitted in neutrinos, thermal sources only (in Lsun units) !mass_loc_of_max_eps_nuc ! (in Msun units) !mass_ext_to_max_eps_nuc ! (in Msun units) !eps_grav_integral ! (in Lsun units) !log_abs_Lgrav ! log10 abs(eps_grav_integral) (in Lsun units) !## information about reactions (by category) ! log10 total luminosity for reaction categories (Lsun units) pp cno tri_alfa !burn_c !burn_n !burn_o !burn_ne !burn_na !burn_mg !burn_si !burn_s !burn_ar !burn_ca !burn_ti !burn_cr !burn_fe !c12_c12 !c12_o16 !o16_o16 !photo !pnhe4 !other !## nuclear reactions at center ! center log10 burn erg/g/s for reaction categories !c_log_eps_burn cno !c_log_eps_burn tri_alfa ! center d_eps_nuc_dlnd for reaction categories !c_d_eps_dlnd cno !c_d_eps_dlnd tri_alfa ! center d_eps_nuc_dlnT for reaction categories !c_d_eps_dlnT cno !c_d_eps_dlnT tri_alfa !## regions of strong nuclear burning ! 2 zones where eps_nuc > burn_min1 erg/g/s ! for each zone have 4 numbers: start1, start2, end2, end1 ! start1 is mass of inner edge where first goes > burn_min1 (or -20 if none such) ! start2 is mass of inner edge where first zone reaches burn_min2 erg/g/sec (or -20 if none such) ! end2 is mass of outer edge where first zone drops back below burn_min2 erg/g/s ! end1 is mass of outer edge where first zone ends (i.e. eps_nuc < burn_min1) ! similar for the second zone epsnuc_M_1 ! start1 for 1st zone epsnuc_M_2 ! start2 epsnuc_M_3 ! end2 epsnuc_M_4 ! end1 epsnuc_M_5 ! start1 for 2nd zone epsnuc_M_6 ! start2 epsnuc_M_7 ! end2 epsnuc_M_8 ! end1 ! you might want to get a more complete list of burning regions by using the following !burning_regions ! the is the number of regions to report ! there will be 2* columns for this in the log file, 2 for each region. ! the first column for a region gives int(sign(val)*log10(max(1,abs(val)))) ! where val = ergs/gm/sec nuclear energy minus all neutrino losses. ! the second column for a region gives the q location of the top of the region ! entries for extra columns after the last region in the star will have a value of -9999 ! all regions are included starting from the center, so the bottom of one region ! is the top of the previous one. ! since we start at the center, the bottom of the 1st region is q=0 and top of last is q=1. ! the columns in the log file will have names like 'burn_type_1' and 'burn_qtop_1' ! if the star has too many regions to report them all, ! the smallest regions will be merged with neighbors for reporting purposes only. !---------------------------------------------------------------------------------------------- !# information about core and envelope !## helium core he_core_mass !he_core_radius !he_core_lgT !he_core_lgRho !he_core_L !he_core_v !he_core_omega !he_core_omega_div_omega_crit !he_core_k !## carbon core c_core_mass !c_core_radius !c_core_lgT !c_core_lgRho !c_core_L !c_core_v !c_core_omega !c_core_omega_div_omega_crit !c_core_k !## oxygen core o_core_mass !o_core_radius !o_core_lgT !o_core_lgRho !o_core_L !o_core_v !o_core_omega !o_core_omega_div_omega_crit !o_core_k !## silicon core si_core_mass !si_core_radius !si_core_lgT !si_core_lgRho !si_core_L !si_core_v !si_core_omega !si_core_omega_div_omega_crit !si_core_k !## iron core fe_core_mass !fe_core_radius !fe_core_lgT !fe_core_lgRho !fe_core_L !fe_core_v !fe_core_omega !fe_core_omega_div_omega_crit !fe_core_k !## neuton rich core neutron_rich_core_mass !neutron_rich_core_radius !neutron_rich_core_lgT !neutron_rich_core_lgRho !neutron_rich_core_L !neutron_rich_core_v !neutron_rich_core_omega !neutron_rich_core_omega_div_omega_crit !neutron_rich_core_k !## envelope !envelope_mass ! = star_mass - he_core_mass !envelope_fraction_left ! = envelope_mass / (initial_mass - he_core_mass) !h_rich_layer_mass ! = star_mass - he_core_mass !he_rich_layer_mass ! = he_core_mass - c_core_mass !c_rich_layer_mass ! = c_core_mass - o_core_mass !o_rich_layer_mass ! = o_core_mass - si_core_mass !si_rich_layer_mass ! = si_core_mass - fe_core_mass !---------------------------------------------------------------------------------------------- !# timescales !dynamic_timescale ! dynamic timescale (seconds) -- estimated by 2*pi*sqrt(r^3/(G*m)) !kh_timescale ! kelvin-helmholtz timescale (years) !mdot_timescale ! star_mass/abs(star_mdot) (years) !kh_div_mdot_timescales ! kh_timescale/mdot_timescale !nuc_timescale ! nuclear timescale (years) -- proportional to mass divided by luminosity !log_chem_timescale ! burn+mix timescale (years) ! approximately min over all cells k and species i of x(i,k)/abs(dxdt_mix + dxdt_burn) !log_chem_timescale_div_time_step !log_cell_collapse_timescale !dt_cell_collapse ! min time for any cell to collapse at current velocities !dt_div_dt_cell_collapse !min_dr_div_cs ! min over all cells of dr/csound (seconds) !min_dr_div_cs_k ! location of min !log_min_dr_div_cs ! log10 min dr_div_csound (seconds) !min_dr_div_cs_yr ! min over all cells of dr/csound (years) !log_min_dr_div_cs_yr ! log10 min dr_div_csound (years) !dt_div_min_dr_div_cs !log_dt_div_min_dr_div_cs !min_t_eddy ! minimum value of scale_height/conv_velocity !---------------------------------------------------------------------------------------------- !# conditions at or near the surface of the model !## conditions at the photosphere !effective_T log_Teff ! log10 effective temperature !photosphere_black_body_T !photosphere_cell_T !photosphere_cell_log_T !photosphere_cell_density !photosphere_cell_log_density !photosphere_cell_opacity !photosphere_cell_log_opacity !photosphere_L ! Lsun units !photosphere_log_L ! Lsun units !photosphere_r ! Rsun units !photosphere_log_r ! Rsun units !photosphere_m ! Msun units !photosphere_v_km_s !photosphere_cell_k !photosphere_column_density !photosphere_csound !photosphere_log_column_density !photosphere_opacity !photosphere_v_div_cs !photosphere_xm !## conditions at or near the surface of the model (outer edge of outer cell) !luminosity ! luminosity in Lsun units !luminosity_ergs_s ! luminosity in cgs units log_L ! log10 luminosity in Lsun units !log_L_ergs_s ! log10 luminosity in cgs units !radius ! Rsun log_R ! log10 radius in Rsun units !radius_cm !log_R_cm log_g ! log10 gravity !gravity !log_Ledd !log_L_div_Ledd ! log10(L/Leddington) !lum_div_Ledd !log_surf_optical_depth !surface_optical_depth !log_surf_cell_opacity ! old name was log_surf_opacity !log_surf_cell_P ! old name was log_surf_P !log_surf_cell_pressure ! old name was log_surf_pressure !log_surf_cell_density ! old name was log_surf_density !log_surf_cell_temperature ! old name was log_surf_temperature !surface_cell_temperature ! old name was surface_temperature !log_surf_cell_z ! old name was log_surf_z !surface_cell_entropy ! in units of kerg per baryon ! old name was surface_entropy !v_surf ! (cm/s) !v_surf_km_s ! (km/s) v_div_csound_surf ! velocity divided by sound speed at outermost grid point !v_div_csound_max ! max value of velocity divided by sound speed at face !v_surf_div_v_kh ! v_surf/(photosphere_r/kh_timescale) !surface_accel_div_grav ! (v - v_old)/dt divided by GM/R^2 at outermost grid point !surf_avg_j_rot !surf_avg_omega !surf_avg_omega_crit !surf_avg_omega_div_omega_crit !surf_avg_v_rot ! km/sec rotational velocity at equator !surf_avg_v_crit ! critical rotational velocity at equator !surf_avg_v_div_v_crit !surf_avg_Lrad_div_Ledd !surf_avg_logT !surf_avg_logRho !surf_avg_opacity !Gravity Darkening, reports the surface averaged L/Lsun and Teff (K) caused by !gravity darkening in rotating stars. Based on the model of Espinosa Lara & Rieutord (2011) !'polar' refers to the line of sight being directed along the rotation axis of the star !'equatorial' refers to the line of sight coincident with the stellar equator !grav_dark_L_polar !Lsun !grav_dark_Teff_polar !K !grav_dark_L_equatorial !Lsun !grav_dark_Teff_equatorial !K !surf_escape_v ! cm/s !v_wind_Km_per_s ! Km/s ! = 1d-5*s% opacity(1)*max(0d0,-s% mstar_dot)/ & ! (4*pi*s% photosphere_r*Rsun*s% tau_base) ! Lars says: ! wind_mdot = 4*pi*R^2*rho*v_wind ! tau = integral(opacity*rho*dr) from R to infinity ! so tau = opacity*wind_mdot/(4*pi*R*v_wind) at photosphere ! or v_wind = opacity*wind_mdot/(4*pi*R*tau) at photosphere !rotational_mdot_boost ! factor for increase in mass loss mdot due to rotation !log_rotational_mdot_boost ! log factor for increase in mass loss mdot due to rotation !surf_r_equatorial_div_r_polar !surf_r_equatorial_div_r !surf_r_polar_div_r !## info about location where optical depth is 10 !tau10_mass ! mass in solar units where optical depth = 10 !tau10_radius ! radius in solar units where optical depth = 10 !tau10_lgP ! estimate for log10(P) at tau = 10 !tau10_T ! estimate for T at tau = 10 !tau10_lgT ! estimate for log10(T) at tau = 10 !tau10_lgRho ! estimate for log10(density) at tau = 10 !tau10_L ! estimate for L/Lsun at tau = 10 !## info about location where optical depth is 100 !tau100_mass ! location in solar units where optical depth = 100 !tau100_radius ! location in solar units where optical depth = 100 !tau100_lgP ! estimates for values at tau = 100 !tau100_T !tau100_lgT !tau100_lgRho !tau100_L !---------------------------------------------------------------------------------------------- !# conditions near center log_center_T ! temperature log_center_Rho ! density !log_center_P ! pressure ! shorter names for above log_cntr_P log_cntr_Rho log_cntr_T !center_T ! temperature !center_Rho ! density !center_P ! pressure !center_degeneracy ! the electron chemical potential in units of k*T !center_gamma ! plasma interaction parameter center_mu center_ye center_abar !center_zbar !center_eps_grav !center_dL_dm !center_dlnT_dt !center_dlnd_dt !center_dlogRho !center_dlogT !center_non_nuc_neu !center_eps_nuc !d_center_eps_nuc_dlnT !d_center_eps_nuc_dlnd !log_center_eps_nuc !center_entropy ! in units of kerg per baryon !max_entropy ! in units of kerg per baryon !fe_core_infall !non_fe_core_infall !max_infall_speed_mass !compactness_parameter ! (m/Msun)/(R(m)/1000km) for m = 2.5 Msun !center_omega !center_omega_div_omega_crit !---------------------------------------------------------------------------------------------- !# abundances !species ! size of net !## mass fractions near center ! the following controls automatically add columns for all of the isos that are in the current net !add_center_abundances !add_log_center_abundances ! individual central mass fractions (as many as desired) center h1 center he4 center c12 center o16 ! individual log10 central mass fractions (as many as desired) !log_center h1 !log_center he4 ! etc. !## mass fractions near surface ! the following controls automatically add columns for all of the isos that are in the current net !add_surface_abundances !add_log_surface_abundances ! individual surface mass fractions (as many as desired) !surface h1 !surface he4 surface c12 surface o16 ! etc. ! individual log10 surface mass fractions (as many as desired) !log_surface h1 !log_surface he4 !## mass fractions for entire star ! the following controls automatically add columns for all of the isos that are in the current net !add_average_abundances !add_log_average_abundances ! individual average mass fractions (as many as desired) !average h1 !average he4 ! etc. ! individual log10 average mass fractions (as many as desired) !log_average h1 !log_average he4 ! etc. !## mass totals for entire star (in Msun units) ! the following controls automatically add columns for all of the isos that are in the current net !add_total_mass !add_log_total_mass ! individual mass totals for entire star (as many as desired) total_mass h1 total_mass he4 ! etc. !individial log10 mass totals for entire star (in Msun units) !log_total_mass h1 !log_total_mass he4 ! etc. !---------------------------------------------------------------------------------------------- !# info at specific locations !## info at a specified mass coordinate (given by trace_mass_location) !trace_mass_location ! (Msun) !trace_mass_radius ! (Rsun) !trace_mass_lgT !trace_mass_lgRho !trace_mass_L ! (Lsun) !trace_mass_v !trace_mass_lgP !trace_mass_g !trace_mass_X !trace_mass_Y !trace_mass_edv_H !trace_mass_edv_He !trace_mass_scale_height !trace_mass_dlnX_dr !trace_mass_dlnY_dr !trace_mass_dlnRho_dr !trace_mass_omega !trace_mass_omega_div_omega_crit !## info at location of max temperature !max_T !log_max_T !max_T_lgT ! equivalent to above !max_T_mass ! (Msun) !max_T_radius ! (Rsun) !max_T_lgRho !max_T_lgP !max_T_entropy !max_T_L ! (Lsun) !max_T_eps_nuc ! (erg/g/s) !max_T_lgP_thin_shell ! log10(G*Mcore*Menv/(4*pi*Rcore^4)) ! Mcore = Msun*max_T_mass, ! Menv = Msun*(star_mass - max_T_mass), ! Rcore = Rsun*max_T_radius !max_T_shell_binding_energy ! integral from max_T out !## info about location where have max rate of hydrogen burning (PP and CNO) !max_eps_h ! erg/g/s !max_eps_h_lgT ! log10 temperature at location of max burn !max_eps_h_lgRho ! log10 density at location of max burn !max_eps_h_m ! mass coordinate at location of max burn (Msun units) !max_eps_h_xm ! mass exterior to location of max burn (Msun units) !max_eps_h_lgP ! log10 pressure at location of max burn !max_eps_h_lgR ! log10 radius at location of max burn !max_eps_h_opacity ! opacity at location of max burn !## info about location where have max rate of helium burning ! triple-alpha plus alpha capture on C12, N14, O16, and Ne20. !max_eps_he ! erg/g/s !max_eps_he_lgT ! log10 temperature at location of max_eps_he !max_eps_he_lgRho ! log10 density at location of max burn !max_eps_he_m ! mass coordinate at location of max burn (Msun units) !max_eps_he_xm ! mass exterior to location of max burn (Msun units) !max_eps_he_lgP ! log10 pressure at location of max burn !max_eps_he_lgR ! log10 radius at location of max burn !max_eps_he_opacity ! opacity at location of max burn !## info about location where have max rate of burning of metals ! alpha capture on heavy elements plus C+C, C+O, O+O, etc. !max_eps_z ! erg/g/s !max_eps_z_lgT ! log10 temperature at location of max burn !max_eps_z_lgRho ! log10 density at location of max burn !max_eps_z_m ! mass coordinate at location of max burn (Msun units) !max_eps_z_xm ! mass exterior to location of max burn (Msun units) !max_eps_z_lgP ! log10 pressure at location of max burn !max_eps_z_lgR ! log10 radius at location of max burn !max_eps_z_opacity ! opacity at location of max burn !## info about location where have max rate of burning of all types !max_eps_nuc ! erg/g/s !max_eps_nuc_lgT ! log10 temperature at location of max burn !max_eps_nuc_lgRho ! log10 density at location of max burn !max_eps_nuc_m ! mass coordinate at location of max burn (Msun units) !max_eps_nuc_xm ! mass exterior to location of max burn (Msun units) !max_eps_nuc_lgP ! log10 pressure at location of max burn !max_eps_nuc_lgR ! log10 radius at location of max burn !max_eps_nuc_opacity ! opacity at location of max burn !max_eps_nuc_cp ! Cp at location of max burn !max_eps_nuc_t_heat ! Cp*T/eps_nuc at location of max burn !max_eps_nuc_csound !max_eps_nuc_pi_r_div_cs !max_eps_nuc_H ! pressure scale height !max_eps_nuc_H_div_cs !max_eps_nuc_log_xa he4 ! any species !## info at location of max abs velocity ! note: can use control "min_tau_for_max_abs_v_location" to exclude surface !max_abs_v_velocity !max_abs_v_csound !max_abs_v_v_div_cs !max_abs_v_lgT !max_abs_v_lgRho !max_abs_v_lgP !max_abs_v_gamma1 !max_abs_v_mass !max_abs_v_radius !max_abs_v_radius_cm !max_abs_v_lgR ! Rsun !max_abs_v_lgR_cm !max_abs_v_L ! Lsun !max_abs_v_entropy !max_abs_v_eps_nuc !max_abs_v_E0 ! 4/3 pi R^3 crad T^4 at max_abs_v_location !---------------------------------------------------------------------------------------------- !# information about shocks !## info about outermost outward moving shock ! excluding locations with q > max_q_for_outer_mach1_location ! returns values at location of max velocity !shock_mass ! baryonic (Msun) !shock_mass_gm ! baryonic (grams) !shock_q !shock_radius ! (Rsun) !shock_radius_cm ! (cm) !shock_velocity !shock_csound !shock_v_div_cs !shock_lgT !shock_lgRho !shock_lgP !shock_gamma1 !shock_entropy !shock_tau !shock_E0 ! 4/3 pi R^3 crad T^4 at shock location !shock_k !## info at innermost mach 1 location ! excluding locations with q < min_q_for_inner_mach1_location !inner_mach1_mass ! baryonic (Msun) !inner_mach1_q !inner_mach1_radius ! (Rsun) !inner_mach1_velocity !inner_mach1_csound !inner_mach1_v_div_cs !inner_mach1_lgT !inner_mach1_lgRho !inner_mach1_lgP !inner_mach1_gamma1 !inner_mach1_entropy !inner_mach1_tau !inner_mach1_k !## info at outermost mach 1 location ! excluding locations with q > max_q_for_outer_mach1_location !outer_mach1_mass ! baryonic (Msun) !outer_mach1_q !outer_mach1_radius ! (Rsun) !outer_mach1_velocity !outer_mach1_csound !outer_mach1_v_div_cs !outer_mach1_lgT !outer_mach1_lgRho !outer_mach1_lgP !outer_mach1_gamma1 !outer_mach1_entropy !outer_mach1_tau !outer_mach1_k !---------------------------------------------------------------------------------------------- !# asteroseismology !delta_nu ! large frequency separation for p-modes (microHz) ! 1e6/(seconds for sound to cross diameter of star) !delta_Pg ! g-mode period spacing for l=1 (seconds) ! sqrt(2) pi^2/(integral of brunt_N/r dr) !log_delta_Pg !nu_max ! estimate from scaling relation (microHz) ! nu_max = nu_max_sun * M/Msun / ((R/Rsun)^3 (Teff/Teff_sun)^0.5) ! with nu_max_sun = 3100 microHz, Teff_sun = 5777 !nu_max_3_4th_div_delta_nu ! nu_max^0.75/delta_nu !acoustic_cutoff ! 0.5*g*sqrt(gamma1*rho/P) at surface !acoustic_radius ! integral of dr/csound (seconds) !ng_for_nu_max ! = 1 / (nu_max*delta_Pg) ! period for g-mode with frequency nu_max = nu_max_ng*delta_Pg !gs_per_delta_nu ! delta_nu / (nu_max**2*delta_Pg) ! number of g-modes per delta_nu at nu_max !int_k_r_dr_nu_max_Sl1 ! integral of k_r*dr where nu < N < Sl for nu = nu_max, l=1 !int_k_r_dr_2pt0_nu_max_Sl1 ! integral of k_r*dr where nu < N < Sl for nu = nu_max*2, l=1 !int_k_r_dr_0pt5_nu_max_Sl1 ! integral of k_r*dr where nu < N < Sl for nu = nu_max/2, l=1 !int_k_r_dr_nu_max_Sl2 ! integral of k_r*dr where nu < N < Sl for nu = nu_max, l=2 !int_k_r_dr_2pt0_nu_max_Sl2 ! integral of k_r*dr where nu < N < Sl for nu = nu_max*2, l=2 !int_k_r_dr_0pt5_nu_max_Sl2 ! integral of k_r*dr where nu < N < Sl for nu = nu_max/2, l=2 !int_k_r_dr_nu_max_Sl3 ! integral of k_r*dr where nu < N < Sl for nu = nu_max, l=3 !int_k_r_dr_2pt0_nu_max_Sl3 ! integral of k_r*dr where nu < N < Sl for nu = nu_max*2, l=3 !int_k_r_dr_0pt5_nu_max_Sl3 ! integral of k_r*dr where nu < N < Sl for nu = nu_max/2, l=3 !---------------------------------------------------------------------------------------------- !# energy information !total_energy ! at end of step !log_total_energy ! log(abs(total_energy)) !total_energy_start ! at start of step !total_energy_change ! end - start ! shorter versions of above !tot_E !log_tot_E !tot_E_change !tot_E_start !total_gravitational_energy !log_total_gravitational_energy ! log(abs(total_gravitational_energy)) !total_gravitational_energy_start !total_gravitational_energy_change ! shorter versions of above !tot_PE !log_tot_PE !tot_PE_start !tot_PE_change !total_internal_energy !log_total_internal_energy !total_internal_energy_start !total_internal_energy_change ! shorter versions of above !tot_IE !log_tot_IE !tot_IE_start !tot_IE_change !total_linear_kinetic_energy !log_total_linear_kinetic_energy !total_linear_kinetic_energy_start !total_linear_kinetic_energy_change ! shorter versions of above (does not include rot KE) !tot_KE !log_tot_KE !tot_KE_start !tot_KE_change !tot_IE_div_IE_plus_KE !total_IE_div_IE_plus_KE !total_IE_plus_KE !log_total_IE_plus_KE !total_IE_plus_KE_change !total_IE_plus_KE_start !total_energy_minus_sources_and_sinks !total_energy_plus_L_surf !total_entropy !total_eps_grav !total_energy_sources_and_sinks ! for this step !total_nuclear_heating !total_non_nuc_neu_cooling !total_irradiation_heating !total_extra_heating !total_Ne22_sedimentation_heating !cumulative_sources_and_sinks !cumulative_L_center !cumulative_L_surf !cumulative_acoustic_L !cumulative_acoustic_L_center !cumulative_delta_total_energy !cumulative_eps_grav !cumulative_extra_heating !cumulative_irradiation_heating !cumulative_non_nuc_neu_cooling !cumulative_nuclear_heating !cumulative_Ne22_sedimentation_heating !run_deltaE !rel_run_E_err !rel_run_deltaE !log_rel_run_deltaE !rel_E_err !abs_rel_E_err !log_rel_E_err !rel_cumulative_delta_total_energy !log_rel_cumulative_delta_total_energy !error_in_energy_conservation ! for this step ! = total_energy - (total_energy_start + total_energy_sources_and_sinks) !cumulative_energy_error ! = sum over all steps of error_in_energy_conservation !rel_cumulative_energy_error ! = cumulative_energy_error/total_energy !log_rel_cumulative_energy_error ! = log10 of rel_cumulative_energy_error !log_rel_run_E_err ! shorter name for rel_cumulative_energy_error !rel_error_in_energy_conservation ! = error_in_energy_conservation/total_energy !log_rel_error_in_energy_conservation !total_energy_and_integrated_fluxes ! = total_energy + cumulative_sources_and_sinks !total_radiation !total_energy_plus_total_radiation !---------------------------------------------------------------------------------------------- !# rotation !total_angular_momentum !log_total_angular_momentum !total_rotational_kinetic_energy !log_total_rotational_kinetic_energy !total_rotational_kinetic_energy_start !total_rotational_kinetic_energy_change !---------------------------------------------------------------------------------------------- !# velocities !avg_abs_v_div_cs !log_avg_abs_v_div_cs !max_abs_v_div_cs !log_max_abs_v_div_cs !avg_abs_v !log_avg_abs_v !max_abs_v !log_max_abs_v !u_surf !u_surf_km_s !u_div_csound_surf !u_div_csound_max !---------------------------------------------------------------------------------------------- !# misc !e_thermal ! sum over all zones of Cp*T*dm !## eos !logQ_max ! logQ = logRho - 2*logT + 12 !logQ_min !acoustic_L !acoustic_L_center !## core mixing !core_overshoot_Hp !core_overshoot_f !core_overshoot_f0 !core_overshoot_hstep !core_overshoot_r0 !mass_bdy_core_overshooting !radius_bdy_core_overshooting !mass_semiconv_core !## H-He boundary !diffusion_time_H_He_bdy !temperature_H_He_bdy !## optical depth and opacity !one_div_yphot !log_one_div_yphot !min_kap_floor !log_min_kap_floor !log_min_opacity !min_opacity !log_tau_center !## other !Lsurf_m !dlnR_dlnM !h1_czb_mass ! location (in Msun units) of base of 1st convection zone above he core !kh_mdot_limit !log_cntr_dr_cm !min_L !min_Pgas_div_P !min_dL_dm !min_dL_dm_m !rms_dvdt_div_v !split_mixing_choice !surf_c12_minus_o16 ! this is useful for seeing effects of dredge up on AGB !surf_num_c12_div_num_o16 !## MLT++ !gradT_excess_alpha !gradT_excess_min_beta !gradT_excess_max_lambda !max_L_rad_div_Ledd !max_L_rad_div_Ledd_div_phi_Joss !## RTI !rti_regions !alpha_RTI_avg_by_mass !## Ni & Co !total_ni_co_56 !nico_escape_ergs_s !log_nico_escape_ergs_s !---------------------------------------------------------------------------------------------- !# accretion !k_below_Eulerian_eps_grav !q_below_Eulerian_eps_grav !logxq_below_Eulerian_eps_grav !k_Lagrangian_eps_grav !q_Lagrangian_eps_grav !logxq_Lagrangian_eps_grav !k_below_const_q !q_below_const_q !logxq_below_const_q !k_const_mass !q_const_mass !logxq_const_mass !k_below_just_added !q_below_just_added !logxq_below_just_added !k_for_test_CpT_absMdot_div_L !q_for_test_CpT_absMdot_div_L !logxq_for_test_CpT_absMdot_div_L !k_CpTMdot_lt_L !q_CpTMdot_lt_L !logxq_CpTMdot_lt_L !---------------------------------------------------------------------------------------------- !# Color output ! Outputs the bolometric correction (bc) for the star in filter band ``filter'' (case sensitive) !bc filter ! Outputs the absolute magnitude for the star in filter band ``filter'' (case sensitive) !abs_mag filter ! Adds all the bc's to the output !add_bc ! Adds all the absolute magnitudes to the output !add_abs_mag ! Outputs luminosity in filter band ``filter'' (lsun) (case sensitive) ! lum_band filter ! Adds all the filter band luminosities to the output (lsun) ! add_lum_band ! Outputs log luminosity in filter band ``filter'' (log lsun) (case sensitive) ! log_lum_band filter ! Adds all the filter band luminosities to the output (log lsun) ! add_log_lum_band !---------------------------------------------------------------------------------------------- !# debugging !## backups and retries num_retries ! total during the run num_backups ! total during the run !## solver iterations num_iters ! same as num_newton_iterations !num_newton_iterations ! iterations at this step !total_num_newton_iterations ! total iterations during the run !rotation_solver_steps !diffusion_solver_steps !diffusion_solver_iters !## maximum solver residuals !log_max_abs_lgE_residual !log_max_abs_v_residual !log_max_dlnEdt_residual !log_max_drdt_residual !log_max_dvdt_residual !log_max_lnd_residual !avg_lgE_residual !avg_v_residual !log_avg_lgE_residual !log_avg_v_residual !max_abs_lgE_residual !max_abs_v_residual !## conservation during mesh adjust !log_mesh_adjust_IE_conservation !log_mesh_adjust_KE_conservation !log_mesh_adjust_PE_conservation !## amr !num_hydro_merges !num_hydro_splits !## timing !elapsed_time ! time since start of run (seconds)