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Lecture 12:Lecture 12:Giant Planet Moons and RingsGiant Planet Moons and Rings
Claire MaxNovember 4th, 2010
Astro 18: Planets and Planetary SystemsUC Santa Cruz
Please remind me to take a break at 12:45 pm
Saturn’s moon Enceladus
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Halliday Lecture Wed Nov 17thHalliday Lecture Wed Nov 17th
http://community.ucsc.edu/hallidaylecture2010
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How to use the web for researchHow to use the web for research
• The good, the bad, and the ugly
• Internet Research Methods
• A few of the reputable sites in planetary A few of the reputable sites in planetary sciences:sciences:– NASANASA– European Space Agency (ESA)European Space Agency (ESA)– The Planetary SocietyThe Planetary Society
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Main points: Giant Planet MoonsMain points: Giant Planet Moons
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Medium and Medium and Large MoonsLarge Moons
• Enough self-gravity to Enough self-gravity to be sphericalbe spherical
• Have substantial Have substantial amounts of iceamounts of ice
• Formed in orbit around Formed in orbit around jovian planetsjovian planets
• Circular orbits in same Circular orbits in same direction as planet direction as planet rotationrotation
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Small Small MoonsMoons
• These are far more These are far more numerous than the numerous than the medium and large moons.medium and large moons.
• They do not have enough They do not have enough gravity to be spherical: gravity to be spherical: Most are “potato-shaped.”Most are “potato-shaped.”
• Captured asteroids or Captured asteroids or comets, so their orbits do comets, so their orbits do not follow usual patterns.not follow usual patterns.
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Small Small MoonsMoons
• They are captured asteroids or comets, so They are captured asteroids or comets, so their orbits do not follow usual patterns.their orbits do not follow usual patterns.
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You might think these moons are too small for You might think these moons are too small for active geology to occuractive geology to occur
• You would be wrong!You would be wrong!
• Terrestrial planets are made mostly of rockTerrestrial planets are made mostly of rock
• Jovian moons are made mostly of iceJovian moons are made mostly of ice
• Ices melt at lower temperatures than rock.Ices melt at lower temperatures than rock.• Less heating is required to have molten coresLess heating is required to have molten cores• Volcanism and tectonics can occur Volcanism and tectonics can occur
• There is another heat source besides Sun.There is another heat source besides Sun.• Tidal heating of the interior plays a more important role; Tidal heating of the interior plays a more important role;
radioactivity contributes tooradioactivity contributes too
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The Large Jovian Moons are very activeThe Large Jovian Moons are very active
• JupiterJupiter• IoIo• EuropaEuropa• GanymedeGanymede• CallistoCallisto
• (Jupiter has > 60 known moons!)(Jupiter has > 60 known moons!)
• SaturnSaturn• TitanTitan• EnceladusEnceladus
• NeptuneNeptune• TritonTriton
sulfur volcanoessulfur volcanoes
active ice worldactive ice world
thick atmosphere (Nthick atmosphere (N22 & CH & CH44))
world of water ice, subsurface liquidworld of water ice, subsurface liquid
dead & dirty ice worlddead & dirty ice world
nitrogen volcanoes, retrograde orbitnitrogen volcanoes, retrograde orbit
warm-water volcanoeswarm-water volcanoes
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Large Moons of JupiterLarge Moons of Jupiter
• ““Galilean” moons: the four biggest onesGalilean” moons: the four biggest ones• Discovered by GalileoDiscovered by Galileo• Closest to JupiterClosest to Jupiter
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Orbital Resonances play a role tooOrbital Resonances play a role too
• Every 7 days, Every 7 days, these 3 these 3 moons line moons line up.up.
• The tugs add The tugs add up over time, up over time, making all 3 making all 3 orbits orbits elliptical.elliptical.
Animation of Io's tidal heating
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Io: Jupiter’s closest moonIo: Jupiter’s closest moon• Jupiter’s tidal forces flex Io Jupiter’s tidal forces flex Io
like a ball of silly putty.like a ball of silly putty.• Friction generates heatFriction generates heat• Interior of Io is moltenInterior of Io is molten
• Volcanoes erupt frequently.Volcanoes erupt frequently.• Sulfur in the lava accounts Sulfur in the lava accounts
for yellow colorfor yellow color• Surface ice vaporizes and Surface ice vaporizes and
jets awayjets away• Lava is hotter than on EarthLava is hotter than on Earth
• Evidence of tectonics & Evidence of tectonics & impact cratering is covered impact cratering is covered over by the lava flows.over by the lava flows.
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Three views of Io, from Galileo Three views of Io, from Galileo spacecraft at Jupiterspacecraft at Jupiter
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Io Volcanoes: Two KindsIo Volcanoes: Two Kinds
EruptiveEruptive Effusive (lava flows)Effusive (lava flows)
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Can see heat from Io's volcanoes in Can see heat from Io's volcanoes in infrared adaptive optics images infrared adaptive optics images
• F. Marchis, UC Berkeley and Team KeckF. Marchis, UC Berkeley and Team Keck
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What makes red rings around Io’s What makes red rings around Io’s volcanoes??volcanoes??
• Sulfur ejected from ventsSulfur ejected from vents
• Makes red / orange colored rings where it landsMakes red / orange colored rings where it lands
• Gradually diffuses, fades into yellowGradually diffuses, fades into yellow
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Europa
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EuropaEuropa
• Metallic core, rocky Metallic core, rocky mantle, and a crust mantle, and a crust made of Hmade of H22O iceO ice
• Its fractured surface Its fractured surface tells us that Europa has tells us that Europa has active tectonicsactive tectonics• few impact cratersfew impact craters• double-ridged cracks double-ridged cracks • jumbled icebergsjumbled icebergs
• Photographic evidence Photographic evidence of a subsurface ocean.of a subsurface ocean.
• Europa has a magnetic field. Implies liquid salt water beneath Europa has a magnetic field. Implies liquid salt water beneath icy crust.icy crust.
• Where liquid water exists, there could be life!Where liquid water exists, there could be life!
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Ice Rafts on Europa (ice floating on Ice Rafts on Europa (ice floating on liquid water?)liquid water?)
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Double ridges on EuropaDouble ridges on Europa
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Tidal stresses crack Europa’s Tidal stresses crack Europa’s surface ice.surface ice.
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Why double ridges?Why double ridges?
• ““Rafts” develop high edges by banging into Rafts” develop high edges by banging into each other repeatedlyeach other repeatedly
• ““Rafts” drift apartRafts” drift apart
• Fresh water flows up into the crackFresh water flows up into the crack
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Europa’s interior also warmed by tidal Europa’s interior also warmed by tidal heating.heating.
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GanymedeGanymede
• Largest moon in Largest moon in the solar systemthe solar system
• Clear evidence of Clear evidence of geological activity geological activity
• Tidal heating plus Tidal heating plus heat from radio-heat from radio-active decay?active decay?
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Ganymede geological features: Ganymede geological features: grooved terraingrooved terrain
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CallistoCallisto
• It has an old surface.It has an old surface.• heavily cratered, dirty iceheavily cratered, dirty ice• cratering reveals clean, white cratering reveals clean, white
ice underneathice underneath• no evidence of tectonicsno evidence of tectonics
• Its interior did not differentiate.Its interior did not differentiate.• rock mixed with icerock mixed with ice
• It does not experience tidal It does not experience tidal heating.heating.
• Yet it has a magnetic field.Yet it has a magnetic field.
• Could it have a subsurface Could it have a subsurface ocean anyway?ocean anyway?
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CallistoCallisto
• ““Classic” Classic” cratered iceball.cratered iceball.
• No tidal heating, No tidal heating, no orbital no orbital resonances. resonances.
• But it has But it has magnetic field !?magnetic field !?
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Galilean moons: Interior structureGalilean moons: Interior structure
Io
Callisto
Europa
Ganymede
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Moons of SaturnMoons of Saturn
TitanTitan EnceladusEnceladus
I’ll discuss only two of them....I’ll discuss only two of them....
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Titan, Saturn's largest moonTitan, Saturn's largest moon
• Has a thick atmosphere.Has a thick atmosphere.• Nitrogen (90%), Argon, methane, Nitrogen (90%), Argon, methane,
ethaneethane• N comes from dissociated NHN comes from dissociated NH33
• methane, ethane are greenhouse methane, ethane are greenhouse gases: surface is warmer than it gases: surface is warmer than it should beshould be
• ethane may condense to form ethane may condense to form clouds and rainclouds and rain
• The atmosphere blocks our view The atmosphere blocks our view of Titan’s surface.of Titan’s surface.• Hazy!Hazy!
• it has large lakes of liquid it has large lakes of liquid hydrocarbons!hydrocarbons!
• Erosion may be importantErosion may be important
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Titan’s AtmosphereTitan’s Atmosphere
• Titan is the only Titan is the only moon in the solar moon in the solar system to have a system to have a thick atmospherethick atmosphere
• It consists mostly of It consists mostly of nitrogen with some nitrogen with some argon, methane, and argon, methane, and ethaneethane
• Surface atmospheric Surface atmospheric pressure similar to pressure similar to ours on Earthours on Earth
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But you can see to the surface at a few But you can see to the surface at a few wavelengths where methane absorption is lowwavelengths where methane absorption is low
• Cassini spacecraft sent Cassini spacecraft sent Huygens landing probe to Huygens landing probe to surface of Titansurface of Titan
• Landing site for Huygens Landing site for Huygens probeprobe
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Titan’s SurfaceTitan’s Surface
• HuygensHuygens probe provided first look at Titan’s surface probe provided first look at Titan’s surface in early 2005in early 2005
• Liquid methane, “rocks” made of iceLiquid methane, “rocks” made of ice
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Huygens probe landing on TitanHuygens probe landing on Titan
• Titan Landing Movie
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Radar images of Titan lakes (!)Radar images of Titan lakes (!)
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Dry riverbeds on TitanDry riverbeds on Titan
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Titan’s “hydrological” cycleTitan’s “hydrological” cycle
• Unmistakable river channels cut into Titan's Unmistakable river channels cut into Titan's terrain. So there must be some kind of rainfall, terrain. So there must be some kind of rainfall, almost certainly drops of liquid methane.almost certainly drops of liquid methane.
• Raindrops would condense around the aerosol Raindrops would condense around the aerosol particles that Huygens lander detected.particles that Huygens lander detected.
• ““Methane rain” and lakes of liquid Methane rain” and lakes of liquid hydrocarbons play the role of water on Earth.hydrocarbons play the role of water on Earth.
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Enceladus: one of Saturn’s Enceladus: one of Saturn’s “medium moons”“medium moons”
• What are the blue What are the blue linear features?linear features?
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Enceladus: one of Saturn’s Enceladus: one of Saturn’s “medium moons”“medium moons”
• What are the blue What are the blue linear features?linear features?
• Warm cracks!Warm cracks!
Temperature scaleTemperature scale
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Plumes from the blue cracksPlumes from the blue cracks
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Models for Enceladus plumesModels for Enceladus plumes
• Southern “hot Southern “hot spot” ?spot” ?
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Rocky Planets vs. Icy MoonsRocky Planets vs. Icy Moons
• Rock melts at higher Rock melts at higher temperaturestemperatures
• Only large rocky Only large rocky planets have enough planets have enough heat for activityheat for activity
• Ice melts at lower Ice melts at lower temperaturestemperatures
• Tidal heating can Tidal heating can melt internal ice, melt internal ice, driving activitydriving activity
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What have we learned?What have we learned?
• What kinds of moons orbit jovian What kinds of moons orbit jovian planets?planets?– Moons of many sizesMoons of many sizes– Level of geological activity depends on sizeLevel of geological activity depends on size
• Why are Jupiter’s Galilean moons so Why are Jupiter’s Galilean moons so geologically active?geologically active?– Tidal heating drives activity, leading to Io’s Tidal heating drives activity, leading to Io’s
volcanoes and ice geology on other moonsvolcanoes and ice geology on other moons
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What have we learned?What have we learned?
• What is special about Titan and other major What is special about Titan and other major moons of the solar system?moons of the solar system?– Titan is only moon with thick atmosphereTitan is only moon with thick atmosphere– Many other major moons show signs of geological Many other major moons show signs of geological
activityactivity
• Why are small icy moons more geologically Why are small icy moons more geologically active than small rocky planets?active than small rocky planets?– Ice melts and deforms at lower temperatures enabling Ice melts and deforms at lower temperatures enabling
tidal heating to drive activitytidal heating to drive activity
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Jovian Planet RingsJovian Planet Rings
• Topics:Topics:
• What are Saturn’s rings like?What are Saturn’s rings like?
• How do other Jovian ring systems compare to How do other Jovian ring systems compare to Saturn’s?Saturn’s?
• Why do the Jovian planets have rings?Why do the Jovian planets have rings?
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The Main Points: RingsThe Main Points: Rings
• All four Giant Planets have ringsAll four Giant Planets have rings– Chunks of rock, ice, dust in orbit around planetChunks of rock, ice, dust in orbit around planet
• Saturn’s rings are the most massive and spectacularSaturn’s rings are the most massive and spectacular
• Formation: a moon can’t survive intact within the Formation: a moon can’t survive intact within the “Roche tidal zone”“Roche tidal zone”
• Ring systems may be short-lived, always changingRing systems may be short-lived, always changing– Each chunk in Saturn’s rings has a collision with another chunk Each chunk in Saturn’s rings has a collision with another chunk
every few hours!every few hours!– Implies that rings are always being replenishedImplies that rings are always being replenished
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Jovian Planets: Ring SystemsJovian Planets: Ring Systems
• All four jovian planets have ring systemsAll four jovian planets have ring systems
• Others have smaller, darker ring particles than SaturnOthers have smaller, darker ring particles than Saturn
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What are Saturn’s rings like?What are Saturn’s rings like?
• They are made up of numerous, tiny individual They are made up of numerous, tiny individual particlesparticles
• They orbit over Saturn’s equatorThey orbit over Saturn’s equator
• They are very thinThey are very thin
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Earth-based viewEarth-based view
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Spacecraft view of ring gapsSpacecraft view of ring gaps
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Not much mass in Saturn’s ringsNot much mass in Saturn’s rings
• If gathered If gathered together, together, material in material in rings would rings would make a make a sphere 500 sphere 500 km acrosskm across
• Smaller Smaller than our than our Moon!Moon!
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Saturn's rings are very thinSaturn's rings are very thin
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Saturn's rings are very thinSaturn's rings are very thin
• Movies from the Movies from the Cassini Cassini spacecraftspacecraft
• http://photojournal.jpl.nasa.gov/archive/PIA12795.mov
Saturn's rings are 270,000 km in Saturn's rings are 270,000 km in diameter, but only about 30 meters diameter, but only about 30 meters thick!thick!
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Saturn's rings are very thinSaturn's rings are very thin
• A star is seen A star is seen clearly on clearly on opposite side opposite side of Saturn’s of Saturn’s rings (Cassini rings (Cassini image)image)
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Artist’s conception of close-upArtist’s conception of close-up
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Saturn’s rings are probably a Saturn’s rings are probably a transient phenomenontransient phenomenon
• Each chunk of rock and ice in Each chunk of rock and ice in Saturn’s rings collides with another Saturn’s rings collides with another one every few hoursone every few hours
• Must grind up smaller chunks into Must grind up smaller chunks into tiny piecestiny pieces
• Needs mechanism for regeneration: Needs mechanism for regeneration: collisions of some of Saturn’s small collisions of some of Saturn’s small moons? moons?
– Not well understood yet.Not well understood yet.
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A collision caught in the act (?)A collision caught in the act (?)
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Shepherd MoonsShepherd Moons
• Pair of small moons can force particles into a narrow ringPair of small moons can force particles into a narrow ring
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Shepherd moons in actionShepherd moons in action
• Prometheus and Prometheus and Pandora shepherd Pandora shepherd Saturn’s F RingSaturn’s F Ring– From Cassini From Cassini
spacecraftspacecraft
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Jupiter’s ringJupiter’s ring
• Not much stuffNot much stuff
• If you gathered all If you gathered all the material in the material in Jupiter’s ring Jupiter’s ring together into a ball, together into a ball, it would be only 30 it would be only 30 meters in diameter!meters in diameter!
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Jupiter’s ring: other viewsJupiter’s ring: other views
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Rings of Uranus in infrared lightRings of Uranus in infrared light
Voyager: 4 groups of rings
ε
δγη
4 5 6
αβ
Keck Adaptive Optics, 2004(de Pater)
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Uranus rings, another viewUranus rings, another view
• Credit: L. SromovskyCredit: L. Sromovsky Keck adaptive opticsKeck adaptive optics
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Uranus: new outer ring just Uranus: new outer ring just discovereddiscovered
• Imke de Pater, UC BerkeleyImke de Pater, UC Berkeley
• Cartoon of Uranus vs. Cartoon of Uranus vs. Saturn ring configurationSaturn ring configuration
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Rings of NeptuneRings of Neptune
• Neptune's rings from VoyagerNeptune's rings from Voyager
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Roche’s limit for tidal breakup Roche’s limit for tidal breakup of a moon, making ringsof a moon, making rings
Roche’s limitRoche’s limit: :
rrRocheRoche such that disruptive tidal force between the two small such that disruptive tidal force between the two small masses is just barely balanced by the gravitational masses is just barely balanced by the gravitational
attraction between themattraction between them
Mass M, radius R two small masses m
in orbit around planet, barely touching each other
x2 - x1
rrRocheRoche
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Roche’s limit, continuedRoche’s limit, continued
• All Jovian planet rings exist within their All Jovian planet rings exist within their respective Roche radiirespective Roche radii
• So if a moon entered this zone, it would break So if a moon entered this zone, it would break up due to tidal stressesup due to tidal stresses
rRoche =2RρM
ρm
⎛⎝⎜
⎞⎠⎟1/3
wηερερM αnδρm αρεδεnsitiεsofplαnεtαnδm oon.
Exαm plε-ifm oonηαssαm εδεnsityαsplαnεt:ρRocηε=2R
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Theories for how rings formedTheories for how rings formed
• Theory 1:Theory 1:
• A satellite got A satellite got disrupted when it got disrupted when it got too close to Saturn too close to Saturn and was ripped apart and was ripped apart by strong tidal forcesby strong tidal forces
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Ring theory 2Ring theory 2
• A moon of Saturn A moon of Saturn was broken apart was broken apart in a collision, and in a collision, and the remnants the remnants stayed in orbit as stayed in orbit as ringsrings
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Ring theory 3Ring theory 3
• Ring developed during Ring developed during initial formation of initial formation of Saturnian systemSaturnian system
• Gravitational tugs from Gravitational tugs from Saturn and other moons Saturn and other moons prevented material from prevented material from gathering together to gathering together to form a moonform a moon
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But rings aren’t left over from But rings aren’t left over from planet formationplanet formation
• Rings aren’t leftover from planet formation Rings aren’t leftover from planet formation because the particles are too small to have because the particles are too small to have survived this long.survived this long.
• There must be a continuous replacement of There must be a continuous replacement of tiny particles.tiny particles.
• The most likely source is impacts with moons.The most likely source is impacts with moons.
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Ring Formation and ReplenishmentRing Formation and Replenishment
• Jovian planets all have rings because they have Jovian planets all have rings because they have many small moons close-inmany small moons close-in
• Impacts on these moons are randomImpacts on these moons are random
• Saturn’s lovely rings may be an “accident” of our Saturn’s lovely rings may be an “accident” of our timetime
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The Main Points: RingsThe Main Points: Rings
• All four Giant Planets have ringsAll four Giant Planets have rings– Chunks of rock and ice, dust in orbit around planetChunks of rock and ice, dust in orbit around planet
• Saturn’s rings are the most massive and spectacularSaturn’s rings are the most massive and spectacular
• Formation: a moon can’t survive intact within the “Roche Formation: a moon can’t survive intact within the “Roche tidal zone”tidal zone”
• Ring systems may be short-lived, always changingRing systems may be short-lived, always changing– Each chunk in Saturn’s rings has a collision with another chunk Each chunk in Saturn’s rings has a collision with another chunk
every few hours!every few hours!
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Main points: Giant Planet MoonsMain points: Giant Planet Moons
• What makes Io so volcanically active?What makes Io so volcanically active?• Tidal heating, caused by the title force of Jupiter as Io moves through Tidal heating, caused by the title force of Jupiter as Io moves through
its elliptical orbit, which in turn is caused by orbital resonances with its elliptical orbit, which in turn is caused by orbital resonances with Europa & Ganymede. Europa & Ganymede.
• Why can active geology occur on much smaller worlds when they Why can active geology occur on much smaller worlds when they are made of ice rather than rock?are made of ice rather than rock?
• Ices soften and melt at much lower temperatures than rock, allowing Ices soften and melt at much lower temperatures than rock, allowing icy volcanism and tectonics at surprisingly low temperatures.icy volcanism and tectonics at surprisingly low temperatures.
• Why do we suspect a subsurface ocean on Europa?Why do we suspect a subsurface ocean on Europa?• Photos show evidence of water flows on the surface, magnetic field Photos show evidence of water flows on the surface, magnetic field
measurements support the presence of a salty ocean, and there is measurements support the presence of a salty ocean, and there is enough tidal heating to melt a thick layer of ice beneath the surface.enough tidal heating to melt a thick layer of ice beneath the surface.