Transcript Lecture19
The Gas Giants
The Gas Giants
Jupiter
Saturn
Uranus
Neptune
Mass (MEarth)
317.8
95.2
14.4
17.2
Distance from Sun (AU)
5.20
9.54
19.2
30.1
Equatorial Radius (REarth)
11.2
9.46
3.98
3.81
Average Density (kg/m3)
1330
710
1240
1670
Size-Mass Relationship
• As with terrestrials, composition can be guessed from mean
density. But the high compressibility of volatiles must be
accounted for
Initially, as they accrete mass they grow in radius
But at a mass of ~300 earth masses, further accretion causes the
radius to decrease.
Composition
• Jupiter and Saturn are
well matched by H+He
models
Require some ice/rock
as well
• Uranus and Neptune are
much better represented
by an icy composition.
T=0 K models
T>0K
Recall: Moment of Inertia
• The moment of inertia is a measure of degree of concentration
Related to the “inertia” (resistance) of a spinning body to external
torques
Shows giant planets are centrally concentrated: cores?
Body
I/MR2
Sun
0.06
Mercury
0.33
Venus
0.33
Earth
0.33
Moon
0.393
Mars
0.366
Jupiter
0.254
Saturn
0.210
Uranus
0.23
Neptune
0.23
0.4 for a homogeneou s sphere
I
0.67 for a hollow shell
2
MR
0 for a point mass
Shapes
• Rotation induces significant
flattening of compressible
material
Body
a/(a-b)
Rotation
Period (d)
Sun
10000
25.4
Earth
298
1.0
Jupiter
16
0.41
Saturn
10
0.426
Heat Balance
• The average temperature of Jupiter is 160 K. Is it in thermal
equilibrium? (Assume a visible albedo of 0.43, but a perfect
blackbody in the infrared).
• An infrared picture of Jupiter
Atmospheres
• Similar thermal structure
to terrestrial planets
• Temperature of Jupiter
and Saturn is never low
enough to form a methane
cloud deck – which
dominates Neptune and
Uranus
• Steep T gradient
(especially in Jupiter)
means interior is
convective
H at high temperatures and pressures
• Atmosphere of Jupiter and
Saturn is mostly “liquid” H2.
• At very high pressures, H atoms
dissociate from each other and
their electrons
Forms a metallic liquid
Good conductor
STP
Interiors
• Jupiter and Saturn are dominated by an
atmosphere of fluid, metallic hydrogen
• Neptune and Uranus are dominated by an
icy mantle, probably as a fluid,
conducting ocean, surrounded by a H and
He atmosphere
Cloud patterns
• Surface features
are due to forms
and colourations of
the highest cloud
layers
Magnetospheres
• The giant planets have strong magnetic fields
Likely due to the convective, metallic hydrogen interior
Interact with solar wind (and atmosphere of Io) to produce
spectacular aurorae
Summary: The Gas Giants
Jupiter
Saturn
Uranus
Neptune
Mass (MEarth)
317.8
95.2
14.4
17.2
Core (MEarth)
~15?
~15?
~13?
~13?
%Mass of Core
≤5%
≤15%
≤90%
≤76%
I/MR2
0.254
0.210
0.23
0.23
Heat Out/In
2.5
2.3
~1.1
2.7
Wind Max (km/s)
~100
≥400
≤200
≤200
Prot (hrs)
9.8
10.6
17.2
16.1
Magnetic Field (vs Earth)
20,000
6000
50
25
Convection?
Y
Y
Y?
Y
Break
Jupiter
• This shows Voyager
1's approach during a
period of over 60
Jupiter days.
• Notice the difference
in speed and direction
of the various zones
of the atmosphere.
• The interaction of the
atmospheric clouds
and storms shows how
dynamic the Jovian
atmosphere is.
Cloud motions in Jupiter’s atmosphere
The Coriolis force diverts N-S motion into E-W motion, in distinct
zonal bands.
Infared and Optical
• Regions of white in visible light are dark in infrared
internal heat is blocked by the clouds
• Darkest visible bands are brightest in the infrared
seeing deeper into the atmosphere where it is hotter
• Red spot also dark in IR: cool, high altitude storm
Jupiter’s atmosphere
• The combination of convection and rotation sets up strong zonal
patterns: 5 in each hemisphere
• Rising air from the deeper layers cools and forms clouds as it
rises; we see deeper where the high ammonia clouds have been
depleted by precipitation, much as on Earth rain will often mean
clearer skies.
Great Red Spot
•
•
Red colour probably from red phosphorous
A large eddy caused by rising hot gas and the Coriolis force
Oval BA
• A White oval storm, similar to
the Red Spot but smaller
Formed from colliding storms in
1988
• Recently turned Red
May be bringing material to the
upper atmosphere, where
reactions with UV solar rays
change the colour.
Feb 27, 2006
Saturn
He Diffusion
•
Saturn radiates more energy than it receives, by the same
amount as Jupiter does
But Saturn is smaller, and this cannot all be gravitational energy
It is thought that He forms droplets and sinks downward,
releasing gravitational energy
Thermal infrared
picture of Saturn
Storms on Saturn
• Like Jupiter, Saturn shows large storms
• These are usually harder to see, however
Uranus and Neptune
Uranus
• Bluish green colour, with far
fewer atmospheric features
than Jupiter and Saturn
Neptune
Colours of Uranus and Neptune
Uranus and Neptune: Interiors
• Likely have a rocky core, but are
dominated by a fluid, icy and ionic
ocean
• Surrounded by an atmosphere rich in
H and He
• Uranus is the only gas giant that does
not emit much more heat than it
receives from the Sun
Internal convection disrupted?
Consistent with lack of storms
Uranus’ tilt
• Uranus has an axis of rotation pointing almost directly toward the
Sun
Interestingly, prevailing winds are still E-W, so the Coriolis force
dominates the weather patterns.
Magnetic Fields
• Both Uranus and Neptune have magnetic field axes that are:
Not aligned with their rotation axis
Not centered at the geometric centre of the planet
• Probably due to complex fluid flow in the interiors
Magnetic axis
Rotation axis
Next lecture: Extrasolar planets