Ruth Murray-Clay - University of Chicago Murray-Clay Harvard-Smithsonian Center for Astrophysics...
84
Origins of Gas Giant Planets Ruth Murray-Clay Harvard-Smithsonian Center for Astrophysics Image Credit: NASA
Transcript of Ruth Murray-Clay - University of Chicago Murray-Clay Harvard-Smithsonian Center for Astrophysics...
Origins of Gas Giant Planets
Ruth Murray-ClayHarvard-Smithsonian Center for Astrophysics
Image Credit: NASA
Graduate Students
Undergraduates
Piso Tripathi
Dawson
Wolff Lau Alpert Mukherjee Wolansky Jackson
Marois et al. 2010
Neptune’s orbital distance
HR 8799: A testbed for planet formation theories
NASA, ESA, M. Robberto, HST Orion Treasury Project, L. Ricci
Alves, Lada, & Lada 2001
Alves, Lada, & Lada 2001
Alves, Lada, & Lada 2001
gas + dust + ice
gas + dust
100 102 104
rp (AU)
10ï4
10ï3
10ï2
10ï1
100M
p/M*
Data: Zuckerman & Song 2009; exoplanet.eu
Kratter, Murray-Clay, & Youdin, ApJ (2010)
~planets
~brown dwarfs
~stars
Test case HR 8799: Brown Dwarfs or Planets?
Jupiter
Saturn
100 102 104
rp (AU)
10ï4
10ï3
10ï2
10ï1
100M
p/M*
Data: Zuckerman & Song 2009; exoplanet.eu
Kratter, Murray-Clay, & Youdin, ApJ (2010)
~planets
~brown dwarfs
~stars
Test case HR 8799: Brown Dwarfs or Planets?
Jupiter
SaturnPlanetary companions
100 102 104
rp (AU)
10ï4
10ï3
10ï2
10ï1
100M
p/M*
Data: Zuckerman & Song 2009; exoplanet.eu
Kratter, Murray-Clay, & Youdin, ApJ (2010)
~planets
~brown dwarfs
~stars
Test case HR 8799: Brown Dwarfs or Planets?Brown dwarf companions
Jupiter
SaturnPlanetary companions
100 102 104
rp (AU)
10ï4
10ï3
10ï2
10ï1
100M
p/M*
Data: Zuckerman & Song 2009; exoplanet.eu
Kratter, Murray-Clay, & Youdin, ApJ (2010) Larger than most
protoplanetary disks
~planets
~brown dwarfs
~stars
Test case HR 8799: Brown Dwarfs or Planets?Brown dwarf companions
Jupiter
SaturnPlanetary companions
100 102 104
rp (AU)
10ï4
10ï3
10ï2
10ï1
100M
p/M*
Data: Zuckerman & Song 2009; exoplanet.eu
Kratter, Murray-Clay, & Youdin, ApJ (2010) Larger than most
protoplanetary disks
~planets
~brown dwarfs
~stars
Planetary companions
Brown dwarf companions
HR 8799Jupiter
Saturn
Test case HR 8799: Brown Dwarfs or Planets?
Three ways to form companions
turbulent fragmentation
core accretion
gravitational instability
Three ways to form companions
turbulent fragmentation
core accretion
gravitational instability
HR 8799
Today’s Goal:A framework for identifying giant planet
formation processes.
Marois et al. 2010
using HR 8799 as a test case
Outline:Origin Stories
~70 AU
More complicated hybrid scenariose.g., form a core close to the star, scatter outward, then accrete gas
Formation closer to star + scattering outward
~ in situ formation by gravitational instability
~ in situ formation by core accretion
Outline:Origin Stories
~70 AU
More complicated hybrid scenariose.g., form a core close to the star, scatter outward, then accrete gas
Formation closer to star + scattering outward
~ in situ formation by gravitational instability
~ in situ formation by core accretion
Gravitational instability
L
most unstable scale:
self-gravity overcomes pressure and Keplerian shear
L ⇠ H
Mfrag ⇠ ⌃(2⇡H)2 ⇠ 4⇡
✓H
a
◆3
M⇤
Gravitational Instability?Planets cannot grow after fragmentation and they must migrate in
Kratter, Murray-Clay, & Youdin, ApJ 2010
e10
Mas
s (M
Jup)
100
20 1401
Radius (AU)60 100
minimumfragment mass
minimumfragment distance
Gravitational Instability?Planets cannot grow after fragmentation and they must migrate in
Kratter, Murray-Clay, & Youdin, ApJ 2010
e10
Mas
s (M
Jup)
100
20 1401
Radius (AU)60 100
minimumfragment mass
minimumfragment distance
Stability requires resonance, suggesting migration
Fabrycky & Murray-Clay 2010
Collapse must occur at the end of infallor the fragment will grow into a binary star
M
Mdisk
Collapse must occur at the end of infallor the fragment will grow into a binary star
M
Mdisk
Collapse must occur at the end of infallor the fragment will grow into a binary star
M
Mdisk
Collapse must occur at the end of infallor the fragment will grow into a binary star
M
isolation mass is stellar!
Mdisk
100 102 104
rp (AU)
10ï4
10ï3
10ï2
10ï1
100M
p/M*
Data: Zuckerman & Song 2009; exoplanet.eu
Kratter, Murray-Clay, & Youdin, ApJ (2010) Larger than most
protoplanetary disks
~planets
~brown dwarfs
~stars
HR 8799expect higher
mass companions from disk collapse
Gravitational instability planets can only be failed binary stars
Outline:Origin Stories
~70 AU
More complicated hybrid scenariose.g., form a core close to the star, scatter outward, then accrete gas
Formation closer to star + scattering outward
~ in situ formation by gravitational instability
~ in situ formation by core accretion
Core accretion: Need to grow a solid core through collisions
v t
v
Volume = Avt
# collisions in time t ~ n Avt ~ (nH) A (t/torb)
number density = n
A
H ~ v torb
Sun
Growth timescale is set by:A: cross-section for collisionsv: relative velocities of colliding bodiesn: density of bodies available to accrete
mass of object trying to grow
orbital time: longer farther from the star
cross-sectionfor collisions
disk surface density in solids
tgrow
=M
M⇠ M
⌃Atorb
mass of object trying to grow
orbital time: longer farther from the star
cross-sectionfor collisions
disk surface density in solids
tgrow
=M
M⇠ M
⌃Atorb
Cross-section regimes:
physical cross-sectiongravitational focusing
capture by gas drag intoplanetary atmosphere ?
Sun
Let’s make gas useful
planetesimal
larger planetesimal or core
Gas Alters the Orbits of Single Planetesimals
planetesimal wants to orbitstar at
radial pressuregradient
but gas orbits more slowly
small
The resulting drag acceleration
large
isvKep
vorb
< vKep
v2orb
r=
GM⇤r2
+1
⇢
dP
dr
FD
m
In the absence of gas, satellites can orbit within the Hill radius
Sun
RHill
In the absence of gas, satellites can orbit within the Hill radius
Sun
RHill
planetarygravity
In the absence of gas, satellites can orbit within the Hill radius
Sun
RHill
planetarygravity
In the absence of gas, satellites can orbit within the Hill radius
Sun
RHill
planetarygravity
In the absence of gas, satellites can orbit within the Hill radius
Sun
RHill
tidalacceleration
planetarygravity
In the absence of gas, satellites can orbit within the Hill radius
Sun
RHill
tidalacceleration
planetarygravity
RHill
RWISH
RHill
No gas: Gas:
core
planetesimal
Wind Shearing (WISH)
Perets & Murray-Clay (2011)
A core + planetesimal in gas can:shear apart
or inspiral and merge
orbit around starmutualorbit
A core + planetesimal in gas can:shear apart
or inspiral and merge
orbit around starmutualorbit
FD
m
FD
m
10−4 10−2 100 102 104 106 108
rs (cm)
10−1
100
101
102
103
104
105
R sta
b/rb
rs ≤ rb
rb/rb
RH/rb
RWS/rb
Epstein
Stokes
1 < Re < 800Ram
1 AU rb = 10kmRam Pressure Drag
binarystability
10−4 10−2 100 102 104 106 10810−1
100
101
102
103
104
105
Wind-Shearing Limits Orbital Stability
WISH radiuslarge body radius
small body radius (cm)
Hill radius
core radius
10km= core radius
Perets & Murray-Clay (2011)
A core + planetesimal in gas can:shear apart
or inspiral and merge
orbit around starmutualorbit
FD
m
FD
m
100
102
104
106
108
1010
τm
erge
(yr)
Porb
1 AU
Stokes
Ram: τmerge ∝ rs
100
102
104
106
108
1010
τm
erge
(yr)
Porb
5 AU
Epstein
Stokes
Ram
10−4 10−2 100 102 104 106 108
rs (cm)
100
102
104
106
108
1010
τm
erge
(yr)
Porb
40 AU
Epstein: τmerge ∝ rs
Stokes: τmerge ∝ rs
2
100
102
104
106
108
1010
τm
erge
(yr)
Porb
1 AU
Stokes
Ram: τmerge ∝ rs
100
102
104
106
108
1010
τm
erge
(yr)
Porb
5 AU
Epstein
Stokes
Ram
10−4 10−2 100 102 104 106 108
rs (cm)
100
102
104
106
108
1010
τm
erge
(yr)
Porb
40 AU
Epstein: τmerge ∝ rs
Stokes: τmerge ∝ rs
2
100
102
104
106
108
1010
τm
erge
(yr)
Porb
1 AU
Stokes
Ram: τmerge ∝ rs
100
102
104
106
108
1010
τm
erge
(yr)
Porb
5 AU
Epstein
Stokes
Ram
10−4 10−2 100 102 104 106 108
rs (cm)
100
102
104
106
108
1010
τm
erge
(yr)
Porb
40 AU
Epstein: τmerge ∝ rs
Stokes: τmerge ∝ rs
2
small body radius (cm)
For Small Planetesimals,Merger Times < Disk Lifetimes
time
to m
erge
(yr
)
typical disk lifetime
~Pluto radius ~km
Perets & Murray-Clay (2011)
“Binary Capture”
RHill
RWISH
dissipation due to interaction
with gas
Murray-Clay & Perets (in prep)(see also Ormel & Klahr 2010)
ï0.02ï0.01 0.00 0.01 0.02x (AU)
ï0.02
ï0.01
0.00
0.01
0.02
y (A
U)
ï0.02ï0.01 0.00 0.01 0.02x (AU)
ï0.02
ï0.01
0.00
0.01
0.02
y (A
U)
ï0.02ï0.01 0.00 0.01 0.02x (AU)
ï0.02
ï0.01
0.00
0.01
0.02y
(AU
)
RHill
Ratm
Integration of forces confirms that capture can happen with a cross-section as large as the Hill radius
RHill
RWISH
Ratm Capture by the atmosphere is only possible if
the small particle can decouple
from the exterior gas.
ï0.02ï0.01 0.00 0.01 0.02x (AU)
ï0.02
ï0.01
0.00
0.01
0.02y
(AU
)
ï0.02ï0.01 0.00 0.01 0.02x (AU)
ï0.02
ï0.01
0.00
0.01
0.02
y (A
U)
ï0.02ï0.01 0.00 0.01 0.02x (AU)
ï0.02
ï0.01
0.00
0.01
0.02
y (A
U)
RHill
Ratm
RWISH
Integrations confirm that well-entrained particles can be swept around the core, preventing accretion
Growth times at 70 AU can be short enough to nucleate an atmosphere
104 105 106
time (yr)
10ï410ï310ï210ï1100101102103
Mco
re (M
Earth
) Mcrit(Rafikov
2006,2010)
50% of MMSN solids in equal mass per log bin from mm
to 10cm
Murray-Clay et al. (in prep.)
Growth times at 70 AU can be short enough to nucleate an atmosphere
104 105 106
time (yr)
10ï410ï310ï210ï1100101102103
Mco
re (M
Earth
) Mcrit(Rafikov
2006,2010)
50% of MMSN solids in equal mass per log bin from mm
to 10cm
Murray-Clay et al. (in prep.)
ï0.02ï0.01 0.00 0.01 0.02x (AU)
ï0.02
ï0.01
0.00
0.01
0.02
y (A
U)
ï0.02ï0.01 0.00 0.01 0.02x (AU)
ï0.02
ï0.01
0.00
0.01
0.02
y (A
U)
ï0.02ï0.01 0.00 0.01 0.02x (AU)
ï0.02
ï0.01
0.00
0.01
0.02y
(AU
)
� = 0.01
RHill
Ratm
Turbulence doesn’t prevent the final stage of core growth by capture of planetesimals
100 102 104
rp (AU)
10ï4
10ï3
10ï2
10ï1
100M
p/M*
Data: Zuckerman & Song 2009; exoplanet.eu
Kratter, Murray-Clay, & Youdin, ApJ (2010) Larger than most
protoplanetary disks
~planets
~brown dwarfs
~stars
HR 8799: Brown Dwarfs or Planets?
HR 8799
100 102 104
rp (AU)
10ï4
10ï3
10ï2
10ï1
100M
p/M*
Data: Zuckerman & Song 2009; exoplanet.eu
Kratter, Murray-Clay, & Youdin, ApJ (2010) Larger than most
protoplanetary disks
~planets
~brown dwarfs
~stars
HR 8799: Brown Dwarfs or Planets?
HR 8799
100 102 104
rp (AU)
10ï4
10ï3
10ï2
10ï1
100M
p/M*
Data: Zuckerman & Song 2009; exoplanet.eu
Kratter, Murray-Clay, & Youdin, ApJ (2010) Larger than most
protoplanetary disks
~planets
~brown dwarfs
~stars
HR 8799: Brown Dwarfs or Planets?
HR 8799
100 102 104
rp (AU)
10ï4
10ï3
10ï2
10ï1
100M
p/M*
Data: Zuckerman & Song 2009; exoplanet.eu
Kratter, Murray-Clay, & Youdin, ApJ (2010) Larger than most
protoplanetary disks
~planets
~brown dwarfs
~stars
HR 8799
Gemini Planet Imager (PI: Bruce Macintosh)
will have different mass distributionsOverlapping populations
100 102 104
rp (AU)
10ï4
10ï3
10ï2
10ï1
100
Mp/M
*
will have different mass distributionsOverlapping populations
100 102 104
rp (AU)
10ï4
10ï3
10ï2
10ï1
100
Mp/M
*
will have different mass distributionsOverlapping populations
100 102 104
rp (AU)
10ï4
10ï3
10ï2
10ï1
100
Mp/M
*
will have different mass distributionsOverlapping populations
100 102 104
rp (AU)
10ï4
10ï3
10ï2
10ï1
100
Mp/M
*
Num
ber
Mass
Num
ber
Mass
Excluding radial orbits:
Stellar metallicity and planetary atmospheric composition provide additional discriminants
H2O snowline ~2 AU
CO snowline ~40 AU C and O
frozen outtogether
C rich gasO rich solids
Oberg, Murray-Clay, & Bergin, ApJL
(2011)
O
C
Outline:Origin Stories
~70 AU
More complicated hybrid scenariose.g., form a core close to the star, scatter outward, then accrete gas
Formation closer to star + scattering outward
~ in situ formation by gravitational instability
~ in situ formation by core accretion
Dawson & Murray-Clay 2013
~ in situ formation?hot Jupiters
highly eccentric planets
Metal-rich stars host more “moved” planets: A signature of planet-planet interactions
“moved” planets{
100 102 104
rp (AU)
10ï4
10ï3
10ï2
10ï1
100M
p/M*
Data: Zuckerman & Song 2009; exoplanet.eu
Kratter, Murray-Clay, & Youdin, ApJ (2010) Larger than most
protoplanetary disks
~planets
~brown dwarfs
~stars
HR 8799
GPI
Jupiter
Saturn
Test case HR 8799: Brown Dwarfs or Planets?
100 102 104
rp (AU)
10ï4
10ï3
10ï2
10ï1
100M
p/M*
Data: Zuckerman & Song 2009; exoplanet.eu
Kratter, Murray-Clay, & Youdin, ApJ (2010) Larger than most
protoplanetary disks
~planets
~brown dwarfs
~stars
HR 8799
GPI
Jupiter
Saturngravitational instability
Test case HR 8799: Brown Dwarfs or Planets?
100 102 104
rp (AU)
10ï4
10ï3
10ï2
10ï1
100M
p/M*
Data: Zuckerman & Song 2009; exoplanet.eu
Kratter, Murray-Clay, & Youdin, ApJ (2010) Larger than most
protoplanetary disks
~planets
~brown dwarfs
~stars
HR 8799
GPI
Jupiter
Saturncore
accretion
Test case HR 8799: Brown Dwarfs or Planets?
100 102 104
rp (AU)
10ï4
10ï3
10ï2
10ï1
100M
p/M*
Data: Zuckerman & Song 2009; exoplanet.eu
Kratter, Murray-Clay, & Youdin, ApJ (2010) Larger than most
protoplanetary disks
~planets
~brown dwarfs
~stars
core accretion
disk gravitational instability?
HR 8799: signpostJupiter
Saturn
How do giant planets and brown dwarfs form?turbulent fragmentation
Formation and evolution of planetary systems
Infall and disk accretion sets the
initial conditions for
and then evolve dynamically over long
timescales
which then migrate as they interact with other planets,
residual gas and planetesimals
around stars with different masses, at different stages of evolution, and in
different environments.
growth of planetesimals and
planets
all the while developing
atmospheres that depend on this
history.
Tripathi
Wolff, Dawson, & Murray-Clay (2012)
Piso, Youdin, & Murray-Clay (final stages)
Dawson & Murray-Clay (2013)
Lau & Murray-Clay (final stages)
Dawson & Murray-Clay (2012)
Alpert
Mukherjee Dawson, Murray-Clay, & Johnson (submitted)
Dawson et al. (2012)
Dawson, Murray-Clay, & Fabrycky (2011)Graduate StudentsUndergraduates
Wolansky (senior thesis)
Jackson (junior project)
100 102 104
rp (AU)
10ï4
10ï3
10ï2
10ï1
100M
p/M*
Data: Zuckerman & Song 2009; exoplanet.eu
Kratter, Murray-Clay, & Youdin, ApJ (2010) Larger than most
protoplanetary disks
~planets
~brown dwarfs
~stars
core accretion
disk gravitational instability?
HR 8799: signpostJupiter
Saturn
How do giant planets and brown dwarfs form?turbulent fragmentation
