The Experts below are selected from a list of 44694 Experts worldwide ranked by ideXlab platform
David Vartanyan - One of the best experts on this subject based on the ideXlab platform.
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Three-dimensional supernova explosion simulations of 9-, 10-, 11-, 12-, and 13-M ☉ stars
Monthly Notices of the Royal Astronomical Society, 2019Co-Authors: Adam Burrows, David Radice, David VartanyanAbstract:Using the new state-of-the-art core-collapse supernova (CCSN) code F{\sc{ornax}}, we have simulated the three-dimensional dynamical evolution of the cores of 9-, 10-, 11-, 12-, and 13-M$_{\odot}$ stars from the onset of collapse. Stars from 8-M$_{\odot}$ to 13-M$_{\odot}$ constitute roughly 50% of all massive stars, so the explosive potential for this mass range is important to the overall theory of CCSNe. We find that the 9-, 10-, 11-, and 12-M$_{\odot}$ models explode in 3D easily, but that the 13-M$_{\odot}$ model does not. From these findings, and the fact that slightly more massive progenitors seem to explode \citep{vartanyan2019}, we suggest that there is a gap in explodability near 12-M$_{\odot}$ to 14-M$_{\odot}$ for non-rotating progenitor stars. Factors conducive to explosion are turbulence behind the stalled shock, energy transfer due to neutrino-matter absorption and neutrino-matter scattering, many-body corrections to the neutrino-nucleon scattering rate, and the presence of a sharp silicon-Oxygen Interface in the progenitor. Our 3D exploding models frequently have a dipolar structure, with the two asymmetrical exploding lobes separated by a pinched waist where matter temporarily continues to accrete. This process maintains the driving neutrino luminosty, while partially shunting matter out of the way of the expanding lobes, thereby modestly facilitating explosion. The morphology of all 3D explosions is characterized by multiple bubble structures with a range of low-order harmonic modes. Though much remains to be done in CCSN theory, these and other results in the literature suggest that, at least for these lower-mass progenitors, supernova theory is converging on a credible solution.
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A successful 3D core-collapse supernova explosion model
Monthly Notices of the Royal Astronomical Society, 2018Co-Authors: David Vartanyan, Adam Burrows, David Radice, M. Aaron Skinner, Joshua C. DolenceAbstract:In this paper, we present the results of our three-dimensional, multi-group, multi-neutrino-species radiation/hydrodynamic simulation using the state-of-the-art code F{\sc{ornax}} of the terminal dynamics of the core of a non-rotating 16-M$_{\odot}$ stellar progenitor. The calculation incorporates redistribution by inelastic scattering, a correction for the effect of many-body interactions on the neutrino-nucleon scattering rates, approximate general relativity (including the effects of gravitational redshifts), velocity-dependent frequency advection, and an implementation of initial perturbations in the progenitor core. The model explodes within $\sim$100 milliseconds of bounce (near when the silicon-Oxygen Interface is accreted through the temporarily-stalled shock) and by the end of the simulation (here, $\sim$677 milliseconds after bounce) is accumulating explosion energy at a rate of $\sim$2.5$\times$10$^{50}$ ergs s$^{-1}$. The supernova explosion resembles an asymmetrical multi-plume structure, with one hemisphere predominating. The gravitational mass of the residual proto-neutron star at $\sim$677 milliseconds is $\sim$1.42 M$_{\odot}$. Even at the end of the simulation, explosion in most of the solid angle is accompanied by some accretion in an annular fraction at the wasp-like waist of the debris field. The ejecta electron fraction (Y$_e$) is distributed from $\sim$0.48 to $\sim$0.56, with most of the ejecta mass proton-rich. This may have implications for supernova nucleosynthesis, and could have a bearing on the p- and $\nu$p-processes and on the site of the first peak of the r-process. The ejecta spatial distributions of both Y$_e$ and mass density are predominantly in wide-angle plumes and large-scale structures, but are nevertheless quite patchy.
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Neutrino Signals of Core-Collapse Supernovae in Underground Detectors
Monthly Notices of the Royal Astronomical Society, 2018Co-Authors: Shaquann Seadrow, Adam Burrows, David Vartanyan, David Radice, M. Aaron SkinnerAbstract:For a suite of fourteen core-collapse models during the dynamical first second after bounce, we calculate the detailed neutrino "light" curves expected in the underground neutrino observatories Super-Kamiokande, DUNE, JUNO, and IceCube. These results are given as a function of neutrino-oscillation modality (normal or inverted hierarchy) and progenitor mass (specifically, post-bounce accretion history), and illuminate the differences between the light curves for 1D (spherical) models that don't explode with the corresponding 2D (axisymmetric) models that do. We are able to identify clear signatures of explosion (or non-explosion), the post-bounce accretion phase, and the accretion of the silicon/Oxygen Interface. In addition, we are able to estimate the supernova detection ranges for various physical diagnostics and the distances out to which various temporal features embedded in the light curves might be discerned. We find that the progenitor mass density profile and supernova dynamics during the dynamical explosion stage should be identifiable for a supernova throughout most of the galaxy in all the facilities studied and that detection by any one of them, but in particular more than one in concert, will speak volumes about the internal dynamics of supernovae.
Chen Shen - One of the best experts on this subject based on the ideXlab platform.
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Sulfidation behavior of ZnFe2O4 roasted with pyrite: Sulfur inducing and sulfur-Oxygen Interface exchange mechanism
Applied Surface Science, 2016Co-Authors: Xiaobo Min, Bo-sheng Zhou, Liyuan Chai, Ke Xue, Chun Zhang, Zongwen Zhao, Chen ShenAbstract:The sulfidation roasting behavior was analyzed in detail to reveal the reaction mechanism. Information about the sulfidation reaction, including phase transformation, ionic migration behavior and morphological change, were obtained by XRD, 57Fe Mossbauer spectroscopy, XPS and SEM analysis. The results showed that the sulfidation of zinc ferrite is a process of sulfur inducing and sulfur-Oxygen Interface exchange. This process can be divided into six stages: decomposition of FeS2, formation of the Oxygen-deficient environment, migration of O2− induced by S2(g), formation of ZnFe2O4-δ, migration of Fe2+ accompanied by the precipitation of ZnO, and the sulfur-Oxygen Interface exchange reaction. The sulfidation products were zinc blende, wurtzite, magnetite and a fraction of zinc-bearing magnetite. These findings can provide theoretical support for controlling the process during which the recovery of Zn and Fe is achieved through the combined flotation-magnetic separation process.
Adam Burrows - One of the best experts on this subject based on the ideXlab platform.
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Three-dimensional supernova explosion simulations of 9-, 10-, 11-, 12-, and 13-M ☉ stars
Monthly Notices of the Royal Astronomical Society, 2019Co-Authors: Adam Burrows, David Radice, David VartanyanAbstract:Using the new state-of-the-art core-collapse supernova (CCSN) code F{\sc{ornax}}, we have simulated the three-dimensional dynamical evolution of the cores of 9-, 10-, 11-, 12-, and 13-M$_{\odot}$ stars from the onset of collapse. Stars from 8-M$_{\odot}$ to 13-M$_{\odot}$ constitute roughly 50% of all massive stars, so the explosive potential for this mass range is important to the overall theory of CCSNe. We find that the 9-, 10-, 11-, and 12-M$_{\odot}$ models explode in 3D easily, but that the 13-M$_{\odot}$ model does not. From these findings, and the fact that slightly more massive progenitors seem to explode \citep{vartanyan2019}, we suggest that there is a gap in explodability near 12-M$_{\odot}$ to 14-M$_{\odot}$ for non-rotating progenitor stars. Factors conducive to explosion are turbulence behind the stalled shock, energy transfer due to neutrino-matter absorption and neutrino-matter scattering, many-body corrections to the neutrino-nucleon scattering rate, and the presence of a sharp silicon-Oxygen Interface in the progenitor. Our 3D exploding models frequently have a dipolar structure, with the two asymmetrical exploding lobes separated by a pinched waist where matter temporarily continues to accrete. This process maintains the driving neutrino luminosty, while partially shunting matter out of the way of the expanding lobes, thereby modestly facilitating explosion. The morphology of all 3D explosions is characterized by multiple bubble structures with a range of low-order harmonic modes. Though much remains to be done in CCSN theory, these and other results in the literature suggest that, at least for these lower-mass progenitors, supernova theory is converging on a credible solution.
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A successful 3D core-collapse supernova explosion model
Monthly Notices of the Royal Astronomical Society, 2018Co-Authors: David Vartanyan, Adam Burrows, David Radice, M. Aaron Skinner, Joshua C. DolenceAbstract:In this paper, we present the results of our three-dimensional, multi-group, multi-neutrino-species radiation/hydrodynamic simulation using the state-of-the-art code F{\sc{ornax}} of the terminal dynamics of the core of a non-rotating 16-M$_{\odot}$ stellar progenitor. The calculation incorporates redistribution by inelastic scattering, a correction for the effect of many-body interactions on the neutrino-nucleon scattering rates, approximate general relativity (including the effects of gravitational redshifts), velocity-dependent frequency advection, and an implementation of initial perturbations in the progenitor core. The model explodes within $\sim$100 milliseconds of bounce (near when the silicon-Oxygen Interface is accreted through the temporarily-stalled shock) and by the end of the simulation (here, $\sim$677 milliseconds after bounce) is accumulating explosion energy at a rate of $\sim$2.5$\times$10$^{50}$ ergs s$^{-1}$. The supernova explosion resembles an asymmetrical multi-plume structure, with one hemisphere predominating. The gravitational mass of the residual proto-neutron star at $\sim$677 milliseconds is $\sim$1.42 M$_{\odot}$. Even at the end of the simulation, explosion in most of the solid angle is accompanied by some accretion in an annular fraction at the wasp-like waist of the debris field. The ejecta electron fraction (Y$_e$) is distributed from $\sim$0.48 to $\sim$0.56, with most of the ejecta mass proton-rich. This may have implications for supernova nucleosynthesis, and could have a bearing on the p- and $\nu$p-processes and on the site of the first peak of the r-process. The ejecta spatial distributions of both Y$_e$ and mass density are predominantly in wide-angle plumes and large-scale structures, but are nevertheless quite patchy.
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Neutrino Signals of Core-Collapse Supernovae in Underground Detectors
Monthly Notices of the Royal Astronomical Society, 2018Co-Authors: Shaquann Seadrow, Adam Burrows, David Vartanyan, David Radice, M. Aaron SkinnerAbstract:For a suite of fourteen core-collapse models during the dynamical first second after bounce, we calculate the detailed neutrino "light" curves expected in the underground neutrino observatories Super-Kamiokande, DUNE, JUNO, and IceCube. These results are given as a function of neutrino-oscillation modality (normal or inverted hierarchy) and progenitor mass (specifically, post-bounce accretion history), and illuminate the differences between the light curves for 1D (spherical) models that don't explode with the corresponding 2D (axisymmetric) models that do. We are able to identify clear signatures of explosion (or non-explosion), the post-bounce accretion phase, and the accretion of the silicon/Oxygen Interface. In addition, we are able to estimate the supernova detection ranges for various physical diagnostics and the distances out to which various temporal features embedded in the light curves might be discerned. We find that the progenitor mass density profile and supernova dynamics during the dynamical explosion stage should be identifiable for a supernova throughout most of the galaxy in all the facilities studied and that detection by any one of them, but in particular more than one in concert, will speak volumes about the internal dynamics of supernovae.
David Radice - One of the best experts on this subject based on the ideXlab platform.
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Three-dimensional supernova explosion simulations of 9-, 10-, 11-, 12-, and 13-M ☉ stars
Monthly Notices of the Royal Astronomical Society, 2019Co-Authors: Adam Burrows, David Radice, David VartanyanAbstract:Using the new state-of-the-art core-collapse supernova (CCSN) code F{\sc{ornax}}, we have simulated the three-dimensional dynamical evolution of the cores of 9-, 10-, 11-, 12-, and 13-M$_{\odot}$ stars from the onset of collapse. Stars from 8-M$_{\odot}$ to 13-M$_{\odot}$ constitute roughly 50% of all massive stars, so the explosive potential for this mass range is important to the overall theory of CCSNe. We find that the 9-, 10-, 11-, and 12-M$_{\odot}$ models explode in 3D easily, but that the 13-M$_{\odot}$ model does not. From these findings, and the fact that slightly more massive progenitors seem to explode \citep{vartanyan2019}, we suggest that there is a gap in explodability near 12-M$_{\odot}$ to 14-M$_{\odot}$ for non-rotating progenitor stars. Factors conducive to explosion are turbulence behind the stalled shock, energy transfer due to neutrino-matter absorption and neutrino-matter scattering, many-body corrections to the neutrino-nucleon scattering rate, and the presence of a sharp silicon-Oxygen Interface in the progenitor. Our 3D exploding models frequently have a dipolar structure, with the two asymmetrical exploding lobes separated by a pinched waist where matter temporarily continues to accrete. This process maintains the driving neutrino luminosty, while partially shunting matter out of the way of the expanding lobes, thereby modestly facilitating explosion. The morphology of all 3D explosions is characterized by multiple bubble structures with a range of low-order harmonic modes. Though much remains to be done in CCSN theory, these and other results in the literature suggest that, at least for these lower-mass progenitors, supernova theory is converging on a credible solution.
-
A successful 3D core-collapse supernova explosion model
Monthly Notices of the Royal Astronomical Society, 2018Co-Authors: David Vartanyan, Adam Burrows, David Radice, M. Aaron Skinner, Joshua C. DolenceAbstract:In this paper, we present the results of our three-dimensional, multi-group, multi-neutrino-species radiation/hydrodynamic simulation using the state-of-the-art code F{\sc{ornax}} of the terminal dynamics of the core of a non-rotating 16-M$_{\odot}$ stellar progenitor. The calculation incorporates redistribution by inelastic scattering, a correction for the effect of many-body interactions on the neutrino-nucleon scattering rates, approximate general relativity (including the effects of gravitational redshifts), velocity-dependent frequency advection, and an implementation of initial perturbations in the progenitor core. The model explodes within $\sim$100 milliseconds of bounce (near when the silicon-Oxygen Interface is accreted through the temporarily-stalled shock) and by the end of the simulation (here, $\sim$677 milliseconds after bounce) is accumulating explosion energy at a rate of $\sim$2.5$\times$10$^{50}$ ergs s$^{-1}$. The supernova explosion resembles an asymmetrical multi-plume structure, with one hemisphere predominating. The gravitational mass of the residual proto-neutron star at $\sim$677 milliseconds is $\sim$1.42 M$_{\odot}$. Even at the end of the simulation, explosion in most of the solid angle is accompanied by some accretion in an annular fraction at the wasp-like waist of the debris field. The ejecta electron fraction (Y$_e$) is distributed from $\sim$0.48 to $\sim$0.56, with most of the ejecta mass proton-rich. This may have implications for supernova nucleosynthesis, and could have a bearing on the p- and $\nu$p-processes and on the site of the first peak of the r-process. The ejecta spatial distributions of both Y$_e$ and mass density are predominantly in wide-angle plumes and large-scale structures, but are nevertheless quite patchy.
-
Neutrino Signals of Core-Collapse Supernovae in Underground Detectors
Monthly Notices of the Royal Astronomical Society, 2018Co-Authors: Shaquann Seadrow, Adam Burrows, David Vartanyan, David Radice, M. Aaron SkinnerAbstract:For a suite of fourteen core-collapse models during the dynamical first second after bounce, we calculate the detailed neutrino "light" curves expected in the underground neutrino observatories Super-Kamiokande, DUNE, JUNO, and IceCube. These results are given as a function of neutrino-oscillation modality (normal or inverted hierarchy) and progenitor mass (specifically, post-bounce accretion history), and illuminate the differences between the light curves for 1D (spherical) models that don't explode with the corresponding 2D (axisymmetric) models that do. We are able to identify clear signatures of explosion (or non-explosion), the post-bounce accretion phase, and the accretion of the silicon/Oxygen Interface. In addition, we are able to estimate the supernova detection ranges for various physical diagnostics and the distances out to which various temporal features embedded in the light curves might be discerned. We find that the progenitor mass density profile and supernova dynamics during the dynamical explosion stage should be identifiable for a supernova throughout most of the galaxy in all the facilities studied and that detection by any one of them, but in particular more than one in concert, will speak volumes about the internal dynamics of supernovae.
Xiaobo Min - One of the best experts on this subject based on the ideXlab platform.
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Sulfidation behavior of ZnFe2O4 roasted with pyrite: Sulfur inducing and sulfur-Oxygen Interface exchange mechanism
Applied Surface Science, 2016Co-Authors: Xiaobo Min, Bo-sheng Zhou, Liyuan Chai, Ke Xue, Chun Zhang, Zongwen Zhao, Chen ShenAbstract:The sulfidation roasting behavior was analyzed in detail to reveal the reaction mechanism. Information about the sulfidation reaction, including phase transformation, ionic migration behavior and morphological change, were obtained by XRD, 57Fe Mossbauer spectroscopy, XPS and SEM analysis. The results showed that the sulfidation of zinc ferrite is a process of sulfur inducing and sulfur-Oxygen Interface exchange. This process can be divided into six stages: decomposition of FeS2, formation of the Oxygen-deficient environment, migration of O2− induced by S2(g), formation of ZnFe2O4-δ, migration of Fe2+ accompanied by the precipitation of ZnO, and the sulfur-Oxygen Interface exchange reaction. The sulfidation products were zinc blende, wurtzite, magnetite and a fraction of zinc-bearing magnetite. These findings can provide theoretical support for controlling the process during which the recovery of Zn and Fe is achieved through the combined flotation-magnetic separation process.
