Hiding in the Shadows. Ii. Collisional Dust as Exoplanet Markers

Dobinson, Jack; Leinhardt, Z. M.; Lines, Stefan; Carter, Philip J.; Dodson-Robinson, Sarah; Teanby, N. A.

doi:10.3847/0004-637x/820/1/29

Cited by 29 publications

(6 citation statements)

References 66 publications

(108 reference statements)

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“…Compared to using the corotating gap opened by the planet as a diagnostic (Dobinson et al 2013(Dobinson et al , 2016, measuring variations in the dust emission near MMRs is much more subtle and requires much higher spatial resolution and sensitivity. As we have shown, the bump vs dip feature near the 2:1 MMR is marginally detectable with ALMA for the nearest protoplanetary discs, so long as the dust profile closely matches the collisional profile of the planetesimals.…”

Section: Discussionmentioning

confidence: 99%

“…Dobinson et al (2013) showed that collisional dust that is generated near the gap opened by a giant planet in the inner regions of a transition disc should produce a distinct observable marker that could be used to infer the presence of the planet. In a followup study, it was found that morphological differences in the dust emission could be used to determine whether the planet had a circular or eccentric orbit (Dobinson et al 2016). Moreover, substructure due to mean-motion resonances (MMRs) with a giant planet may hold additional clues that could be used to constrain the properties of the planet.…”

Section: Introductionmentioning

confidence: 99%

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Collision rates of planetesimals near mean-motion resonances

Wallace,

Quinn,

Boley

2021

Preprint

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In circumstellar discs, collisional grinding of planetesimals produces second-generation dust. While it remains unclear whether this ever becomes a major component of the total dust content, the presence of such dust, and potentially the substructure within, it can be used to explore a disc's physical conditions. A perturbing planet produces nonaxisymmetric structures and gaps in the dust, regardless of its origin. The dynamics of planetesimals, however, will be very different than that of small dust grains due to weaker gas interactions. Therefore, planetesimal collisions could create dusty disc structures that would not exist otherwise. In this work, we use N-body simulations to investigate the collision rate profile of planetesimals near mean-motion resonances. We find that a distinct bump or dip feature is produced in the collision profile, the presence of which depends on the libration width of the resonance and the separation between the peri-and apocenter distances of the edges of the resonance. The presence of one of these two features depends on the mass and eccentricity of the planet. Assuming that the radial dust emission traces the planetesimal collision profile, the presence of a bump or dip feature in the dust emission at the 2:1 mean-motion resonance can constrain the orbital properties of the perturbing planet. This assumption is valid, so long as radial drift does not play a significant role during the collisional cascade process. Under this assumption, these features in the dust emission should be marginally observable in nearby protoplanetary disks with ALMA.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Collision rates of planetesimals near mean-motion resonances

Wallace,

Quinn,

Boley

2021

Preprint

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“…Likewise, we have not included planetesimal formation or planet growth, though large bodies increase the velocity distributions of nearby objects, leading to more destructive collisions (e.g. Dobinson et al 2016). Our simulations only apply to young disks at the very beginning of disk evolution.…”

Section: Only Sticking and Fragmentation (Sf) Collision Outcomesmentioning

confidence: 99%

Growth and Settling of Dust Particles in Protoplanetary Nebulae: Implications for Opacity, Thermal Profile, and Gravitational Instability

Sengupta

Dodson-Robinson

Hasegawa

et al. 2019

ApJ

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In spite of making a small contribution to total protoplanetary disk mass, dust affects the disk temperature by controlling absorption of starlight. As grains grow from their initial ISM-like size distribution, settling depletes the disk's upper layers of dust and decreases the optical depth, cooling the interior. Here we investigate the effect of collisional growth of dust grains and their dynamics on the thermal and optical profile of the disk, and explore the possibility that cooling induced by grain growth and settling could lead to gravitational instability. We develop a Monte Carlo dust collision model with a weighting technique and allow particles to collisionally evolve through sticking and fragmentation, along with vertical settling and turbulent mixing. We explore two disk models, the MMEN (minimum-mass extrasolar nebula), and a "heavy" disk with higher surface density than the MMEN, and perform simulations for both constant and spatially variable turbulence efficiency profile α(R, z). We then calculate mean wavelength-dependent opacities for the evolving disks and perform radiative transfer to calculate the temperature profile T (R, z). Finally, we calculate the Toomre Q parameter, a measure of the disk's stability against self-gravity, for each disk model after it reaches a steady state dust-size distribution. We find that even weak turbulence can keep sub-micron sized particles stirred in the disk's upper layer, affecting its optical and thermal profiles, and the growth of large particles in the midplane can make a massive disk optically thick at millimeter wavelengths, making it difficult to calculate the surface density of dust available for planet formation in the inner disk. Also, for an initially massive disk, grain settling and growth can produce a drop in the Toomre Q parameter, driving the disk to Q < 1.4 and possibly triggering spiral instabilities.

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“…Because debris disks traditionally are associated with collisional erosion of planetsimals (a relatively slow process) they are generally treated as a steady state. Other dynamical activities such as extra perturbations due to newly formed planets or on-going planet accretion through collisions can also potentially produce additional source material for a dusty observable debris disk (Dobinson et al 2016). Particularly, most giant impacts are not perfect merging events even if they result in substantial growth of the tar-get.…”

Section: Introductionmentioning

confidence: 99%

Planetary Embryo Collisions and the Wiggly Nature of Extreme Debris Disks

Watt,

Leinhardt,

2021

Preprint

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In this paper, we present results from a multi-stage numerical campaign to begin to explain and determine why extreme debris disk detections are rare, what types of impacts will result in extreme debris disks and what we can learn about the parameters of the collision from the extreme debris disks. We begin by simulating many giant impacts using a smoothed particle hydrodynamical code with tabulated equations of state and track the escaping vapour from the collision. Using an 𝑁-body code, we simulate the spatial evolution of the vapour generated dust post-impact.We show that impacts release vapour anisotropically not isotropically as has been assumed previously and that the distribution of the resulting generated dust is dependent on the mass ratio and impact angle of the collision. In addition, we show that the anisotropic distribution of post-collision dust can cause the formation or lack of formation of the short-term variation in flux depending on the orientation of the collision with respect to the orbit around the central star. Finally, our results suggest that there is a narrow region of semi-major axis where a vapour generated disk would be observable for any significant amount of time implying that giant impacts where most of the escaping mass is in vapour would not be observed often but this does not mean that the collisions are not occurring.

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Hiding in the Shadows. Ii. Collisional Dust as Exoplanet Markers

Cited by 29 publications

References 66 publications

Collision rates of planetesimals near mean-motion resonances

Collision rates of planetesimals near mean-motion resonances

Growth and Settling of Dust Particles in Protoplanetary Nebulae: Implications for Opacity, Thermal Profile, and Gravitational Instability

Planetary Embryo Collisions and the Wiggly Nature of Extreme Debris Disks

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