generating vortices with slowly-growing gas giant planets(2) then, add a giant planet at r = 1 and...
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Generating Vortices withSlowly-growing Gas Giant Planets
Michael HammerCollaborators: Kaitlin Kratter, Paola Pinilla, Min-Kai Lin
University of Arizona
van der Marel, N., et al. 2013
![Page 2: Generating Vortices with Slowly-growing Gas Giant Planets(2) Then, add a giant planet at r = 1 and run the simulation. Gap Two -Fluid (Gas + Dust) Simulations Zhu, Z. et al. 2012 (1b)](https://reader033.vdocument.in/reader033/viewer/2022060514/5f82ae4b9ce2596f2c3d7803/html5/thumbnails/2.jpg)
Generating Vortices withSlowly-growing Gas Giant Planets
Michael HammerCollaborators: Kaitlin Kratter, Paola Pinilla, Min-Kai Lin
University of Arizona
van der Marel, N., et al. 2013
![Page 3: Generating Vortices with Slowly-growing Gas Giant Planets(2) Then, add a giant planet at r = 1 and run the simulation. Gap Two -Fluid (Gas + Dust) Simulations Zhu, Z. et al. 2012 (1b)](https://reader033.vdocument.in/reader033/viewer/2022060514/5f82ae4b9ce2596f2c3d7803/html5/thumbnails/3.jpg)
Why so asymmetric?
ALMA Observations Hydrodynamic Simulation
Jupiter-mass Planet
SR 21(Dust)
This resemblance is well-known; e.g. (Li, H., et al. 2005; Zhu, Z. + Stone, J. 2014).
Oph IRS 48(Dust)
Perez, L., et al. 2014
Gap
~35 AU
van der Marel, N., et al. 2013
GasHigher Density
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Dust_____
Why so asymmetric?
ALMA Observations Hydrodynamic Simulation
Jupiter-mass Planet
SR 21(Dust)
Oph IRS 48(Dust)
Perez, L., et al. 2014
~35 AU
van der Marel, N., et al. 2013
This resemblance is well-known; e.g. (Li, H., et al. 2005; Zhu, Z. + Stone, J. 2014).
Higher Density
![Page 5: Generating Vortices with Slowly-growing Gas Giant Planets(2) Then, add a giant planet at r = 1 and run the simulation. Gap Two -Fluid (Gas + Dust) Simulations Zhu, Z. et al. 2012 (1b)](https://reader033.vdocument.in/reader033/viewer/2022060514/5f82ae4b9ce2596f2c3d7803/html5/thumbnails/5.jpg)
Why so asymmetric?
ALMA Observations Synthetic Image
Jupiter-mass Planet
SR 21(Dust)
Oph IRS 48(Dust)
Perez, L., et al. 2014
~35 AU
van der Marel, N., et al. 2013
Beam
Higher IntensityThis resemblance is well-known; e.g.
(Li, H., et al. 2005; Zhu, Z. + Stone, J. 2014).
![Page 6: Generating Vortices with Slowly-growing Gas Giant Planets(2) Then, add a giant planet at r = 1 and run the simulation. Gap Two -Fluid (Gas + Dust) Simulations Zhu, Z. et al. 2012 (1b)](https://reader033.vdocument.in/reader033/viewer/2022060514/5f82ae4b9ce2596f2c3d7803/html5/thumbnails/6.jpg)
How can gap-opening planets create vortices?
(1) Start with a gas disk with this radial density profile.To simulate this with FARGO (hydrodynamic code):
Sharp density peaks can make disks unstable(to the RossbyWave Instability)
(2) Then, add a giant planet at r = 1 and run the simulation.
Sharp Peak inRadial Density
Profile
Gap
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Notice:
Vortex Evolution (with Instant Planet Growth)
MH, Kratter, K., Lin, M.-K. 2017, MNRAS, 466, 3533
(1) Extent: The vortex spans 120 degrees near the beginning.
(2) Density: It reaches an over-density of
more than twice the initial density.
(3) Lifetime: It lasts for ~8000 orbits, making
it observable.
![Page 8: Generating Vortices with Slowly-growing Gas Giant Planets(2) Then, add a giant planet at r = 1 and run the simulation. Gap Two -Fluid (Gas + Dust) Simulations Zhu, Z. et al. 2012 (1b)](https://reader033.vdocument.in/reader033/viewer/2022060514/5f82ae4b9ce2596f2c3d7803/html5/thumbnails/8.jpg)
Notice:
(1) Extent: The vortex spans 120 degrees near the beginning.
(2) Density: It reaches an over-density of
more than twice the initial density.
(3) Lifetime: It lasts for ~8000 orbits, making
it observable.
Vortex Evolution (with Instant Planet Growth)
MH, Kratter, K., Lin, M.-K. 2017, MNRAS, 466, 3533
![Page 9: Generating Vortices with Slowly-growing Gas Giant Planets(2) Then, add a giant planet at r = 1 and run the simulation. Gap Two -Fluid (Gas + Dust) Simulations Zhu, Z. et al. 2012 (1b)](https://reader033.vdocument.in/reader033/viewer/2022060514/5f82ae4b9ce2596f2c3d7803/html5/thumbnails/9.jpg)
How fast do giant planets grow?
Core Accretion Model for Giant Planet Formation:Runaway Gas Accretion Phase
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How fast do giant planets grow?
The runaway gas accretion phase can last for thousands of orbits.
Adapted from Lissauer et al. 2009
Growth Models for Jupiter’s Runaway Gas Accretion Phase
Growth Times
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Notice:
(1) Extent: The vortex spans about 240
degrees.
(2) Density: It never reaches double the
initial density.
(3) Lifetime: It lasts for only ~1500 orbits.
Then, it forms a ring.
Vortex Evolution (with Slower Planet Growth)
MH, Kratter, K., Lin, M.-K. 2017, MNRAS, 466, 3533
![Page 12: Generating Vortices with Slowly-growing Gas Giant Planets(2) Then, add a giant planet at r = 1 and run the simulation. Gap Two -Fluid (Gas + Dust) Simulations Zhu, Z. et al. 2012 (1b)](https://reader033.vdocument.in/reader033/viewer/2022060514/5f82ae4b9ce2596f2c3d7803/html5/thumbnails/12.jpg)
Early Vortex Evolution
…with Instant Growth: …with Slower Growth:
(1) Planet grows to full size.
(2) Disk becomes unstable.
(3) A strong vortex forms.
(4) Vortex smooths gap edge.
(1) Disk becomes unstable.
(2) A weak vortex forms.
(3) Vortex smooths gap edge.
(4) Planet grows to full size.
![Page 13: Generating Vortices with Slowly-growing Gas Giant Planets(2) Then, add a giant planet at r = 1 and run the simulation. Gap Two -Fluid (Gas + Dust) Simulations Zhu, Z. et al. 2012 (1b)](https://reader033.vdocument.in/reader033/viewer/2022060514/5f82ae4b9ce2596f2c3d7803/html5/thumbnails/13.jpg)
Vortex Extents with Slower Planet Growth
MH, Kratter, K., Lin, M.-K. 2017, MNRAS, 466, 3533
Concentrated(< 120°)
180 degrees
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Vortex Extents with Slower Planet Growth
MH, Kratter, K., Lin, M.-K. 2017, MNRAS, 466, 3533
Concentrated(< 120°)
180 degrees
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Vortex Extents with Slower Planet Growth
MH, Kratter, K., Lin, M.-K. 2017, MNRAS, 466, 3533
Concentrated(< 120°)
Elongated (> 240°)
180 degrees
![Page 16: Generating Vortices with Slowly-growing Gas Giant Planets(2) Then, add a giant planet at r = 1 and run the simulation. Gap Two -Fluid (Gas + Dust) Simulations Zhu, Z. et al. 2012 (1b)](https://reader033.vdocument.in/reader033/viewer/2022060514/5f82ae4b9ce2596f2c3d7803/html5/thumbnails/16.jpg)
Vortex Extents with Slower Planet Growth
MH, Kratter, K., Lin, M.-K. 2017, MNRAS, 466, 3533
Concentrated(< 120°)
Elongated (> 240°)
180 degrees
![Page 17: Generating Vortices with Slowly-growing Gas Giant Planets(2) Then, add a giant planet at r = 1 and run the simulation. Gap Two -Fluid (Gas + Dust) Simulations Zhu, Z. et al. 2012 (1b)](https://reader033.vdocument.in/reader033/viewer/2022060514/5f82ae4b9ce2596f2c3d7803/html5/thumbnails/17.jpg)
Vortex Extents with Slower Planet Growth
MH, Kratter, K., Lin, M.-K. 2017, MNRAS, 466, 3533
Planets must grow to Jupiter size in <200 orbits
to trigger a concentrated vortex.
Concentrated(< 120°)
Elongated (> 240°)
180 degrees
![Page 18: Generating Vortices with Slowly-growing Gas Giant Planets(2) Then, add a giant planet at r = 1 and run the simulation. Gap Two -Fluid (Gas + Dust) Simulations Zhu, Z. et al. 2012 (1b)](https://reader033.vdocument.in/reader033/viewer/2022060514/5f82ae4b9ce2596f2c3d7803/html5/thumbnails/18.jpg)
Vortex Extents with Slower Planet Growth
MH, Kratter, K., Lin, M.-K. 2017, MNRAS, 466, 3533
No Vortex
Planets must grow to Jupiter size in <200 orbits
to trigger a concentrated vortex.
Typical Jupiter analogsdo not trigger vortices!
(e.g. Lissauer et al. 2009)
Concentrated(< 120°)
Elongated (> 240°)
180 degrees
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Dust Trapping in Vortices?
Gas Dust
Tgrowth = 10 orbits(Concentrated Vortex)
Simulated with Two-Fluid FARGO [Gas + Dust] (Zhu, Z. et al. 2012)MH, Pinilla, P., Kratter, K., Lin, M.-K. 2018, in prep.
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?
Do elongated vortices trap dust the same way?Tgrowth = 1000 orbits
(Elongated Vortex)
Gas DustMH, Pinilla, P., Kratter, K., Lin, M.-K. 2018, in prep.
Simulated with Two-Fluid FARGO [Gas + Dust] (Zhu, Z. et al. 2012)
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Do elongated vortices trap dust the same way?
Concentrated Vortex Elongated Vortex
Contour Levels: 1.10,
Gas1.20, 1.30, 1.40, …, 2.70 [Σ / Σ0]
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Concentrated Vortex
Azimuthal Density Profiles: 1 mm-size grains
MH, Pinilla, P., Kratter, K., Lin, M.-K. 2018, in prep.
Dust
Elongated Vortex
Gaussian (as expected)
Mostly Flat!(not expected!)
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Azimuthal Density Profiles: 1 cm-size grains
MH, Pinilla, P., Kratter, K., Lin, M.-K. 2018, in prep.
Dust
Concentrated Vortex Elongated Vortex
Gaussian (as expected)
Peak is off-center!(not expected!)
![Page 24: Generating Vortices with Slowly-growing Gas Giant Planets(2) Then, add a giant planet at r = 1 and run the simulation. Gap Two -Fluid (Gas + Dust) Simulations Zhu, Z. et al. 2012 (1b)](https://reader033.vdocument.in/reader033/viewer/2022060514/5f82ae4b9ce2596f2c3d7803/html5/thumbnails/24.jpg)
Tgrowth = 1000 orbits(Elongated Vortex)
Why are the elongated vortex peaks off-center?
Planet
The elongated vortex interacts with the
planet’s spiral arms!
MH, Pinilla, P., Kratter, K., Lin, M.-K. 2018, in prep.
![Page 25: Generating Vortices with Slowly-growing Gas Giant Planets(2) Then, add a giant planet at r = 1 and run the simulation. Gap Two -Fluid (Gas + Dust) Simulations Zhu, Z. et al. 2012 (1b)](https://reader033.vdocument.in/reader033/viewer/2022060514/5f82ae4b9ce2596f2c3d7803/html5/thumbnails/25.jpg)
Synthetic Images of Elongated Vortices
Mp = 1 MJupRp = 20 AUTgrowth = 1000 orbits
αdisk = 3 ×10-5
smin = 1 μmsmax = 1 cmn ~ s-3.0
λ = 0.87 mm (Band 7)d = 140 pcBeam: 0.07ʺ × 0.07ʺ
MH, Pinilla, P., Kratter, K., Lin, M.-K. 2018, in prep.
Signature: Peak is off-center in images!
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Resolving the Extent of an Elongated Vortex
Concentrated Vortex Elongated Vortex
A beam diameter of 0.5 rp (0.07ʺ × 0.07ʺ)can resolve the extent and off-center peak of an elongated vortex.
MH, Pinilla, P., Kratter, K., Lin, M.-K. 2018, in prep.
![Page 27: Generating Vortices with Slowly-growing Gas Giant Planets(2) Then, add a giant planet at r = 1 and run the simulation. Gap Two -Fluid (Gas + Dust) Simulations Zhu, Z. et al. 2012 (1b)](https://reader033.vdocument.in/reader033/viewer/2022060514/5f82ae4b9ce2596f2c3d7803/html5/thumbnails/27.jpg)
Resolving the Extent of an Elongated Vortex
Concentrated Vortex Elongated Vortex
A beam diameter of 1.0 rp (0.14ʺ × 0.14ʺ)can resolve the extent and off-center peak of an elongated vortex.
MH, Pinilla, P., Kratter, K., Lin, M.-K. 2018, in prep.
![Page 28: Generating Vortices with Slowly-growing Gas Giant Planets(2) Then, add a giant planet at r = 1 and run the simulation. Gap Two -Fluid (Gas + Dust) Simulations Zhu, Z. et al. 2012 (1b)](https://reader033.vdocument.in/reader033/viewer/2022060514/5f82ae4b9ce2596f2c3d7803/html5/thumbnails/28.jpg)
Resolving the Extent of an Elongated Vortex
Concentrated Vortex Elongated Vortex
A beam diameter of 1.5 rp (0.21ʺ) cannot resolve an elongated vortex.
MH, Pinilla, P., Kratter, K., Lin, M.-K. 2018, in prep.
When observing vortex candiates, request beam sizes of at most the semimajor axis of the planet (not the asymmetry) in your ALMA proposal!
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SummaryJupiter analogs will not trigger vortices unless they
can grow faster than the viscous accretion rate.
If giant planets can still trigger vortices, they would(1) have shorter lifetimes, (2) be less dense,
and (3) be more elongated, making them less likely to observable.
Beam diameters of at most the planet’s semimajor axis are needed to show that a vortex is elongated.
Elongated planet-induced vortices are characterized by (1) wider azimuthal extents and (2) off-center peaks.
![Page 30: Generating Vortices with Slowly-growing Gas Giant Planets(2) Then, add a giant planet at r = 1 and run the simulation. Gap Two -Fluid (Gas + Dust) Simulations Zhu, Z. et al. 2012 (1b)](https://reader033.vdocument.in/reader033/viewer/2022060514/5f82ae4b9ce2596f2c3d7803/html5/thumbnails/30.jpg)
(1) Interpolate from 6 grain sizes to 100 grain sizes from 1 μm to 1 cm.
Generating Synthetic Images
(2) Combine all grain sizes into a single surface density map.
[Grain Size Distribution: n = n0 s-3.0 ]
(4) Convolve simulated images with a beam size.
(3) Run radiative transfer calculations to convertthe density map into a simulated intensity map.
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Do larger grains in elongated vortices still have narrower concentrations? (Yes.)
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Resolving the Extent of an Elongated Vortex
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(1a) Start with a gas disk with the left radial density profile.To simulate this with Two-Fluid FARGO ( ):
(2) Then, add a giant planet at r = 1 and run the simulation.
Gap
Two-Fluid (Gas + Dust) SimulationsZhu, Z. et al. 2012
(1b) Start with a dust disk with same profile, but 100x lower density.
Gap
Particle Sizes: 1 μm, 100 μm, 0.3 mm, 1 mm, 0.3 cm, 1 cm
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Parameter Study
Mass ViscosityPlanet Growth Times
10
(in orbits)
10
10
10
1000
2000
2000
4000
(“Instant”) (Slowest)
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Vortex Lifetimes with Slower Planet Growth
MH, Kratter, K., Lin, M.-K. 2017, MNRAS, 466, 3533
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When are gap edges unstable?
High-Viscosity disks (α >= 3 ×10-3)
will smooth out these peaks.
Low-Viscosity disks (α < 3 ×10-3)
are needed to form vortices.
Not Sharp Enough! Unstable!