The Astrophysical Implications of Dust Formation during the Eruptions of Hot, Massive Stars

The Astrophysical Implications of Dust Formation during the Eruptions of Hot, Massive Stars

Dust formation in the winds of hot stars is inextricably linked to the classic eruptive state of luminous blue variables because it requires very high mass-loss rates, year--1, for grains to grow and for the non-dust optical depth of the wind to shield the dust formation region from the true stellar...

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Bibliographic Details
Published in:The Astrophysical journal Vol. 743; no. 1; pp. 73 - jQuery1323900926551='48'
Main Author: Kochanek, C. S
Format: Journal Article
Language:English
Published: Bristol IOP Publishing 10-12-2011
IOP
Subjects:
Astronomy
ASTROPHYSICS
ASTROPHYSICS, COSMOLOGY AND ASTRONOMY
DUSTS
Earth, ocean, space
ERUPTION
Exact sciences and technology
GALAXIES
INSTABILITY
LIFETIME
PHOTOSPHERE
STAR EVOLUTION
SUPERNOVAE
Stellar winds
Dust shell
Galaxies
Supernovae
Loss rate
Burnup
Massive stars
Shell stars
extinction
Stellar photospheres
stars: mass-loss
stars: massive
Optical thickness
dust
Age
stars: evolution
Selection effect
Mass loss
Stellar evolution
M stars
stars: winds, outflows
supernovae: general
Luminous blue variable star
Lifetime
Stellar mass
Hot star
Instability
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Summary:Dust formation in the winds of hot stars is inextricably linked to the classic eruptive state of luminous blue variables because it requires very high mass-loss rates, year--1, for grains to grow and for the non-dust optical depth of the wind to shield the dust formation region from the true stellar photosphere. Thus, dusty shells around hot stars trace the history of 'great' eruptions, and the statistics of such shells in the Galaxy indicate that these eruptions are likely the dominant mass-loss mechanism for evolved, M ZAMS 40 M stars. Dust formation at such high also explains why very large grains (a max 1 Delta *mm) are frequently found in these shells, since . The statistics of these shells (numbers, ages, masses, and grain properties such as a max) provide an archaeological record of this mass-loss process. In particular, the velocities v shell, transient durations (where known), and ejected masses M shell of the Galactic shells and the supernova (SN) 'impostors' proposed as their extragalactic counterparts are very different. While much of the difference is a selection effect created by shell lifetimes , more complete Galactic and extragalactic surveys are needed to demonstrate that the two phenomena share a common origin given that their observed properties are essentially disjoint. If even small fractions (1%) of SNe show interactions with such dense shells of ejecta, as is currently believed, then the driving mechanism of the eruptions must be associated with the very final phases of stellar evolution, suggestive of some underlying nuclear burning instability.
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SourceType-Scholarly Journals-1
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content type line 23
ISSN:0004-637X
1538-4357
DOI:10.1088/0004-637X/743/1/73