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Pair-production supernovae: Theory and observation

Published online by Cambridge University Press:  04 August 2010

Evan. Scannapieco
Affiliation:
Kavli Institute for Theoretical Physics, Kohn Hall, University of California–Santa Barbara, Santa Barbara, CA 93106, USA
Mario Livio
Affiliation:
Space Telescope Science Institute, Baltimore
Eva Villaver
Affiliation:
Space Telescope Science Institute, Baltimore
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Summary

Nonrotating stars that end their lives with masses 140 MM* ≤ 260 M should explode as pair-production supernovae (PPSNe). Here I review the physical properties of these objects, as well as the prospects for them to be observationally constrained.

In very massive stars, much of the pressure support comes from the radiation field, meaning that they are loosely bound, and that (d lgp/d lg Ρ)adiabatic near the center is close to the minimum value necessary for stability. Near the end of C/O burning, the central temperature increases to the point that photons begin to be converted into electron–positron pairs, softening the equation of state below this critical value. The result is a runaway collapse, followed by explosive burning that completely obliterates the loosely bound star. While these explosions can be up to 100 times more energetic than core collapse and Type Ia supernovae, their peak luminosities are only slightly greater. However, due both to copious Ni56 production and hydrogen recombination, they are brighter much longer, and remain observable for ≈1 year.

Since metal enrichment is a local process, PPSNe should occur in pockets of metal-free gas over a broad range of redshifts, greatly enhancing their detectability, and distributing their nucleosynthetic products about the Milky Way. This means that measurements of the abundances of metal-free stars should be thought of as directly constraining these objects.

Type
Chapter
Information
Massive Stars
From Pop III and GRBs to the Milky Way
, pp. 209 - 227
Publisher: Cambridge University Press
Print publication year: 2009

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