For typical models of binary statistics, 50%–80 % of core-collapse supernova (ccSN) progenitors are members of a stellar binary at the time of the explosion. Independent of any consequences of mass transfer, this has observational consequences that can be used to study the binary properties of massive stars. In particular, the secondary companion to the progenitor of a Type Ib/c SN is frequently (∼50%) the more optically luminous star since the high effective temperatures of the stripped progenitors make it relatively easy for a lower luminosity, cooler secondary to emit more optical light. Secondaries to the lower mass progenitors of Type II SN will frequently produce excess blue emission relative to the spectral energy distribution of the...
As many young massive stars are found in close binaries, many core-collapse supernova progenitors ar...
Core-collapse supernovae (CCSNe) are an important part of the stellar evolution of massive stars. Ce...
Many core-collapse supernova progenitors are presumed to be in binary systems. If a star explodes in...
For typical models of binary statistics, 50%-80% of core-collapse supernova (ccSN) progenitors are m...
The progenitors of core-collapse supernovae are stars with an initial mass greater than about 8M⊙. U...
Massive stars that lose their hydrogen-rich envelope down to a few tenths of a solar mass explode as...
The majority of massive stars, which are the progenitors of core-collapse supernovae (SNe), are foun...
To place core-collapse supernovae (SNe) in context with the evolution of massive stars, it is necess...
Hydrogen-rich supernovae, known as Type II (SNe II), are the most common class of explosions observe...
Supernovae of both Type I (hydrogen-poor) and Type II (hydrogen-rich) can be expected to occur among...
Many young, massive stars are found in close binaries. Using population synthesis simulations. we pr...
We investigate the evolution of Type Ib/c supernova (SN Ib/c) progenitors in close binary systems, u...
Hydrogen-rich supernovae, known as Type II (SNe II), are the most common class of explosions observe...
As many young massive stars are found in close binaries, many core-collapse supernova progenitors ar...
Core-collapse supernovae (CCSNe) are an important part of the stellar evolution of massive stars. Ce...
Many core-collapse supernova progenitors are presumed to be in binary systems. If a star explodes in...
For typical models of binary statistics, 50%-80% of core-collapse supernova (ccSN) progenitors are m...
The progenitors of core-collapse supernovae are stars with an initial mass greater than about 8M⊙. U...
Massive stars that lose their hydrogen-rich envelope down to a few tenths of a solar mass explode as...
The majority of massive stars, which are the progenitors of core-collapse supernovae (SNe), are foun...
To place core-collapse supernovae (SNe) in context with the evolution of massive stars, it is necess...
Hydrogen-rich supernovae, known as Type II (SNe II), are the most common class of explosions observe...
Supernovae of both Type I (hydrogen-poor) and Type II (hydrogen-rich) can be expected to occur among...
Many young, massive stars are found in close binaries. Using population synthesis simulations. we pr...
We investigate the evolution of Type Ib/c supernova (SN Ib/c) progenitors in close binary systems, u...
Hydrogen-rich supernovae, known as Type II (SNe II), are the most common class of explosions observe...
As many young massive stars are found in close binaries, many core-collapse supernova progenitors ar...
Core-collapse supernovae (CCSNe) are an important part of the stellar evolution of massive stars. Ce...
Many core-collapse supernova progenitors are presumed to be in binary systems. If a star explodes in...
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