2015
DOI: 10.1007/s10509-015-2315-6
|View full text |Cite
|
Sign up to set email alerts
|

Five steps in the evolution from protoplanetary to debris disk

Abstract: The protoplanetary disks seen around Herbig Ae stars eventually dissipate leaving just a tenuous debris disk, comprised of planetesimals and the dust derived from them, as well as possibly gas and planets. This paper uses the properties of the youngest (10-20 Myr) A star debris disks to consider the transition from protoplanetary to debris disk. It is argued that the physical distinction between these two classes should rest on the presence of primordial gas in sufficient quantities to dominate the motion of s… Show more

Help me understand this report
View preprint versions

Search citation statements

Order By: Relevance

Paper Sections

Select...
2
1
1
1

Citation Types

5
90
0

Year Published

2015
2015
2018
2018

Publication Types

Select...
5
4

Relationship

0
9

Authors

Journals

citations
Cited by 97 publications
(95 citation statements)
references
References 208 publications
(262 reference statements)
5
90
0
Order By: Relevance
“…Ercolano et al 2011, Koepferl et al 2015 for a theoretical perspective). Similarly, Wyatt (2008) argues that the disk mass derived from the sub-mm remains more or less constant (albeit with a wide dispersion, see Carpenter et al 2014) and shows a sharp decline at 10 Myr, perhaps again indicating this transition to the debris disk phase (see also Wyatt et al 2014). Since debris disks are almost always gas-free, the 10 Myr time also serves as an upper limit on the gas disk dispersal time, which is also consistent with gas observations (Zuckerman et al 1995, Dent et al 2013.…”
Section: Disk Lifetimesmentioning
confidence: 86%
See 1 more Smart Citation
“…Ercolano et al 2011, Koepferl et al 2015 for a theoretical perspective). Similarly, Wyatt (2008) argues that the disk mass derived from the sub-mm remains more or less constant (albeit with a wide dispersion, see Carpenter et al 2014) and shows a sharp decline at 10 Myr, perhaps again indicating this transition to the debris disk phase (see also Wyatt et al 2014). Since debris disks are almost always gas-free, the 10 Myr time also serves as an upper limit on the gas disk dispersal time, which is also consistent with gas observations (Zuckerman et al 1995, Dent et al 2013.…”
Section: Disk Lifetimesmentioning
confidence: 86%
“…This conversion needs to be rapid and highly efficient, if not, substantial amounts of dust may remain after gas disk removal. Debris disk processes such as PR drag could remove the remnant primordial dust (see chapter by Wyatt et al ), but these mechanisms act on Myr timescales and are not consistent with the rapid transition to the debris disk stage (e.g., Luhman et al 2010, Wyatt et al 2014. The most likely scenario is that planet formation has already removed most of the dust before gas disk dispersal, although this suggests a causal link between these two processes (see discussion in Gorti et al 2015).…”
Section: Disk Lifetimesmentioning
confidence: 99%
“…Its young age, gas disk, and active accretion are reminiscent of a protoplanetary disk, although the strength of the infrared excess is much more typical of a debris disk. With constraints on the temperature and density structure of the gas we can compare to typical protoplanetary disks and debris disks to gain insight as to the origin of the gas and dust in the system, as well as their influence on each other (e.g., Wyatt et al 2015).…”
Section: Discussionmentioning
confidence: 99%
“…Several sources are in the 10 Myr regime. At such ages, many systems already show low emission levels consistent with debris disks (e.g., Hardy et al 2015;Wyatt et al 2015). This is particularly surprising since A stars are thought to lose their disks faster (Ribas et al 2015) and suggests that the giant planet systems responsible for clearing large portions of the inner disk may contribute to disk longevity by trapping material in the outer disk.…”
Section: The Longevity Of B a F Star Disksmentioning
confidence: 99%