The Type Ia supernova, known as SN 2020eyj, was first detected on 7 March 2020, but its true origins were unknown, until now.<\/p>\n
![\""Type\"](\""https:\/\/images.immediate.co.uk\/production\/volatile\/sites\/25\/2021\/03\/Type-1-a-supernova-step-01-1a50e47.jpg?quality=90&resize=620%2C389"\" "\\"\"Type\\"\/")
<\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/picture><\/div>Type Ia supernovae explained<\/strong><\/h2>\nType Ia supernovae occur in binary star<\/a> systems \u2013 where two stars orbit each other \u2013 in which one of the stars is a white dwarf<\/a>.<\/p>\nThe white dwarf consumes material from its companion star until it reaches its critical mass, which triggers a stellar explosion known as a supernova.<\/p>\n
And because an explosion\u2019s brightness depends on the star\u2019s mass, Type Ia supernovae always have the same luminosity.<\/p>\n
By comparing a Type Ia supernova\u2019s apparent brightness as seen from Earth with its actual brightness, it can be used to calculate distances in space<\/a>.<\/p>\nInvestigating SN 2020eyj<\/strong><\/h2>\nSupernova 2020eyj was first discovered by the Zwicky Transient Facility<\/a> camera on Palomar mountain in California, USA.<\/p>\nThat study was led by Erik Kool, researcher at the University of Stockholm<\/a>, in collaboration with research institutes across the world.<\/p>\nFor this latest discovery, astronomers using the\u00a0e-MERLIN<\/a>\u00a0telescope network operated by Jodrell Bank at The University of Manchester were able to study SN2020eyj and conclude that its binary star system was composed of a white dwarf and a Sun-like star.<\/p>\nRadio telescopes enable astronomers to detect and amplify radio waves originating in space, interpreting them to study the Universe.<\/p>\n
The team behind this discovery studied the supernova\u2019s light curve and infrared<\/a> emission, narrow helium emission lines and radio counterpart.<\/p>\nThe results have been published in the journal\u00a0Nature.<\/p>\n
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<\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/picture><\/div> The Lovell Telescope at Jodrell Bank Observatory, Cheshire. Credit:Dr David Williams, e-MERLIN Operations Support Scientist at\u00a0The University of Manchester<\/a>, says: \u201cAstronomers have been trying to detect radio emission from a Type Ia supernova for a few decades.<\/p>\n\u201cUsing e-MERLIN, the observatory staff were able to react quickly when we first heard of the potential interesting nature of this source from the authors of this study.<\/p>\n
\u201cThe exquisite angular resolution of e-MERLIN combined with its high sensitivity enabled the radio emission to be pinpointed to the supernova, which is critical for establishing that the multi-wavelength emission was linked and attributed to the same source.\u201d<\/p>\n
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<\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/picture><\/div> An artist\u2019s impression of a white dwarf star. Credit:Javier Mold\u00f3n, who participated in the discovery, says: \u201cThis first radio detection of a Type Ia supernova is a milestone that has allowed us to demonstrate that the exploded white dwarf was accompanied by a normal, non-degenerate star before the explosion.<\/p>\n
\u201cIn addition, with these observations, we can estimate the mass and geometry of the material surrounding the supernova, which allows us to better understand what the system was like before the explosion.<\/p>\n
\u201cNow that we have demonstrated that radio observations can provide direct and unique information to understand this type of supernova, a path is opened to study these systems with the new generation of radio instruments, such as the Square Kilometre Array Observatory<\/a> in the future.\u201d<\/p>\n
The white dwarf consumes material from its companion star until it reaches its critical mass, which triggers a stellar explosion known as a supernova.<\/p>\n
And because an explosion\u2019s brightness depends on the star\u2019s mass, Type Ia supernovae always have the same luminosity.<\/p>\n
By comparing a Type Ia supernova\u2019s apparent brightness as seen from Earth with its actual brightness, it can be used to calculate distances in space<\/a>.<\/p>\n Supernova 2020eyj was first discovered by the Zwicky Transient Facility<\/a> camera on Palomar mountain in California, USA.<\/p>\n That study was led by Erik Kool, researcher at the University of Stockholm<\/a>, in collaboration with research institutes across the world.<\/p>\n For this latest discovery, astronomers using the\u00a0e-MERLIN<\/a>\u00a0telescope network operated by Jodrell Bank at The University of Manchester were able to study SN2020eyj and conclude that its binary star system was composed of a white dwarf and a Sun-like star.<\/p>\n Radio telescopes enable astronomers to detect and amplify radio waves originating in space, interpreting them to study the Universe.<\/p>\n The team behind this discovery studied the supernova\u2019s light curve and infrared<\/a> emission, narrow helium emission lines and radio counterpart.<\/p>\n The results have been published in the journal\u00a0Nature.<\/p>\n Dr David Williams, e-MERLIN Operations Support Scientist at\u00a0The University of Manchester<\/a>, says: \u201cAstronomers have been trying to detect radio emission from a Type Ia supernova for a few decades.<\/p>\n \u201cUsing e-MERLIN, the observatory staff were able to react quickly when we first heard of the potential interesting nature of this source from the authors of this study.<\/p>\n \u201cThe exquisite angular resolution of e-MERLIN combined with its high sensitivity enabled the radio emission to be pinpointed to the supernova, which is critical for establishing that the multi-wavelength emission was linked and attributed to the same source.\u201d<\/p>\n Javier Mold\u00f3n, who participated in the discovery, says: \u201cThis first radio detection of a Type Ia supernova is a milestone that has allowed us to demonstrate that the exploded white dwarf was accompanied by a normal, non-degenerate star before the explosion.<\/p>\n \u201cIn addition, with these observations, we can estimate the mass and geometry of the material surrounding the supernova, which allows us to better understand what the system was like before the explosion.<\/p>\n \u201cNow that we have demonstrated that radio observations can provide direct and unique information to understand this type of supernova, a path is opened to study these systems with the new generation of radio instruments, such as the Square Kilometre Array Observatory<\/a> in the future.\u201d<\/p>\nInvestigating SN 2020eyj<\/strong><\/h2>\n
![\""The\"](\""https:\/\/images.immediate.co.uk\/production\/volatile\/sites\/25\/2020\/09\/GettyImages-dv1254092-8a737a2-e1600690095251.jpg?quality=90&resize=620%2C413"\" "\\"\"The\\"\/")
<\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/source><\/picture><\/div>![\""An\"](\""https:\/\/images.immediate.co.uk\/production\/volatile\/sites\/25\/2019\/08\/WhiteDwarf-05b5823-e1565773489259.jpg?quality=90&resize=620%2C451"\" "\\"\"An\\"\/")
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