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Global comparison of core-collapse supernova simulations in spherical symmetry

Author(s): O Connor, Evan; Bollig, Robert; Burrows, Adam S.; Couch, Sean; Fischer, Tobias; et al

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dc.contributor.authorO Connor, Evan-
dc.contributor.authorBollig, Robert-
dc.contributor.authorBurrows, Adam S.-
dc.contributor.authorCouch, Sean-
dc.contributor.authorFischer, Tobias-
dc.contributor.authorJanka, Hans-Thomas-
dc.contributor.authorKotake, Kei-
dc.contributor.authorLentz, Eric J-
dc.contributor.authorLiebendörfer, Matthias-
dc.contributor.authorMesser, OE Bronson-
dc.contributor.authorMezzacappa, Anthony-
dc.contributor.authorTakiwaki, Tomoya-
dc.contributor.authorVartanyan, David-
dc.date.accessioned2019-04-10T19:32:21Z-
dc.date.available2019-04-10T19:32:21Z-
dc.date.issued2018-10en_US
dc.identifier.citationO Connor, Evan, Bollig, Robert, Burrows, Adam, Couch, Sean, Fischer, Tobias, Janka, Hans-Thomas, Kotake, Kei, Lentz, Eric J, Liebendörfer, Matthias, Messer, OE Bronson, Mezzacappa, Anthony, Takiwaki, Tomoya, Vartanyan, David. (2018). Global comparison of core-collapse supernova simulations in spherical symmetry. Journal of Physics G Nuclear Physics, 45 (104001 - 104001. doi:10.1088/1361-6471/aadeaeen_US
dc.identifier.urihttp://arks.princeton.edu/ark:/88435/pr1sh8n-
dc.description.abstractWe present a comparison between several simulation codes designed to studythe core-collapse supernova mechanism. We pay close attention to controllingthe initial conditions and input physics in order to ensure a meaningful andinformative comparison. Our goal is three-fold. First, we aim to demonstratethe current level of agreement between various groups studying the core-collapse supernova central engine. Second, we desire to form a strong basis forfuture simulation codes and methods to compare to. Lastly, we want this workto be a stepping stone for future work exploring more complex simulations ofcore-collapse supernovae, i.e., simulations in multiple dimensions and simu-lations with modern neutrino and nuclear physics. We compare the early(first∼500 ms after core bounce)spherically-symmetric evolution of a 20Meprogenitor star from six different core-collapse supernovae codes: 3DnSNe-IDSA, AGILE-BOLTZTRAN, FLASH, FORNAX, GR1D, and PRO-METHEUS-VERTEX. Given the diversity of neutrino transport and hydro-dynamic methods employed, wefind excellent agreement in many criticalquantities, including the shock radius evolution and the amount of neutrinoheating. Our results provide an excellent starting point from which to extendthis comparison to higher dimensions and compare the development ofhydrodynamic instabilities that are crucial to the supernova explosion mech-anism, such as turbulence and convection.en_US
dc.language.isoen_USen_US
dc.relation.ispartofJournal of Physics G Nuclear Physicsen_US
dc.rightsFinal published version. This is an open access article.en_US
dc.titleGlobal comparison of core-collapse supernova simulations in spherical symmetryen_US
dc.typeJournal Articleen_US
dc.identifier.doidoi:10.1088/1361-6471/aadeae-
dc.date.eissued2018-09-14en_US
pu.type.symplectichttp://www.symplectic.co.uk/publications/atom-terms/1.0/journal-articleen_US

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O’Connor_2018_J._Phys._G _Nucl._Part._Phys._45_104001.pdf1.61 MBAdobe PDFView/Download
01_shock.dat25.03 kBUnknownView/Download
02_PNS_radius.dat27.62 kBUnknownView/Download
README.txt89 BTextView/Download
Quantities_s20.0_SFHo_with_escat_final.txt598.75 kBTextView/Download
smooth.py1.77 kBUnknownView/Download
datareaders.py10.45 kBUnknownView/Download
1Dplotter.py10.27 kBUnknownView/Download
shock_radius.pdf50.66 kBAdobe PDFView/Download
mass_accretion.pdf43.5 kBAdobe PDFView/Download
lums.pdf144.19 kBAdobe PDFView/Download
heating.pdf67.05 kBAdobe PDFView/Download
detection.pdf59.04 kBAdobe PDFView/Download
avee.pdf117.16 kBAdobe PDFView/Download
tprof(1).dat249.53 kBUnknownView/Download
tbounce(1).dat25 BUnknownView/Download
shock_radius_t_corrected(1).dat212.08 kBUnknownView/Download
s20_18_finalJPG_small(1).dat15.08 MBUnknownView/Download
rmsenergy_rest(1).dat37.41 kBUnknownView/Download
r_rho1e11(1).dat318.69 kBUnknownView/Download
nosmooth_anti_fix_20_SFHO_noINS_bruenn.new_brem1_nr16(1).dat188.87 kBUnknownView/Download
tprof.dat249.53 kBUnknownView/Download
tbounce.dat25 BUnknownView/Download
shock_radius_t_corrected.dat212.08 kBUnknownView/Download
s20_18_finalJPG_small.dat15.08 MBUnknownView/Download
rmsenergy_rest.dat37.41 kBUnknownView/Download
r_rho1e11.dat318.69 kBUnknownView/Download
nosmooth_anti_fix_20_SFHO_noINS_bruenn.new_brem1_nr16.dat188.87 kBUnknownView/Download
menergy_rest.dat37.41 kBUnknownView/Download
M1_net_heating.dat938.85 kBUnknownView/Download
M1_flux_rmsenergy_lab.dat628.77 kBUnknownView/Download
M1_net_heating.dat938.85 kBUnknownView/Download
M1_flux_rmsenergy_lab.dat628.77 kBUnknownView/Download
M1_flux_lum.dat628.77 kBUnknownView/Download
M1_flux_aveenergy_lab.dat628.77 kBUnknownView/Download
luminosity_rest.dat37.41 kBUnknownView/Download
heating_from_rates.dat19.45 kBUnknownView/Download
accretion_rates.dat1.87 MBUnknownView/Download
20_SFHO_noINS_bruenn.new_brem1_nr16_Qdot.dat30.44 kBUnknownView/Download
03_mdot.dat32.5 kBUnknownView/Download


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