ASTR100 (Spring 2008) Introduction to Astronomy Asteroids, Comets, and Dwarf Planets
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Transcript of ASTR100 (Spring 2008) Introduction to Astronomy Asteroids, Comets, and Dwarf Planets
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ASTR100 (Spring 2008) Introduction to AstronomyAsteroids, Comets, and Dwarf Planets
Prof. D.C. Richardson
Sections 0101-0106
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Why is there an asteroid belt?
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Asteroid Facts
Asteroids are rocky leftovers of planet formation.
Largest is Ceres, diameter ~1,000 km. 150,000 in catalogs, and probably over a million with diameter >1 km.
Small asteroids are more common than large asteroids.
All the asteroids in the solar system wouldn’t add up to even a small terrestrial planet.
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12566 Derichardson
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Asteroids are cratered and not round.
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Eros
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Asteroids with Moons
Some large asteroids have their own moon(s).
Asteroid Ida has a tiny moon named Dactyl.
Ida (approx. 30 km long)
Dactyl!
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Binary 90 Antiope
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Triple 87 Sylvia
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Bonus Topic: Origin of Binary Asteroids
If a fragile asteroid passes too close to a terrestrial planet, tides may pull it apart!
Impacts and spin-up can also make binaries…
QuickTime™ and aYUV420 codec decompressor
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Asteroid Orbits
Most asteroids orbit in a belt between Mars and Jupiter.
Trojan asteroids follow Jupiter’s path.
Orbits of near-Earth asteroids approach or cross Earth’s orbit.
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Thought Question
Why are there very few asteroids beyond Jupiter’s orbit?
A. There was no rocky material beyond Jupiter’s orbit.
B. The heaviest rocks sank toward the center of the solar system.
C. Ice could form in the outer solar system.
D. A passing star probably stripped away all of those asteroids, even if they were there at one time.
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Thought Question
Why are there very few asteroids beyond Jupiter’s orbit?
A. There was no rocky material beyond Jupiter’s orbit.
B. The heaviest rocks sank toward the center of the solar system.
C. Ice formed in the outer solar system.
D. A passing star probably stripped away all of those asteroids, even if they were there at one time.
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Thought Question
Which explanation for the asteroid belt seems the most plausible?
A. The belt is where all the asteroids happened to form.
B. The belt is the remnant of a large terrestrial planet that used to be between Mars and Jupiter.
C. The belt is where all the asteroids happened to survive.
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Thought Question
Which explanation for the asteroid belt seems the most plausible?
A. The belt is where all the asteroids happened to form.
B. The belt is the remnant of a large terrestrial planet that used to be between Mars and Jupiter.
C. The belt is where all the asteroids happened to survive.
But WHY didn’t they form a little planet?
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Orbital Resonances
Asteroids in orbital resonance with Jupiter experience periodic nudges.
Eventually those nudges moves asteroids out of resonant orbits, leaving gaps in the belt.
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Origin of the Asteroid Belt
Rocky planetesimals between Mars and Jupiter did not accrete into a planet.
Orbital resonances stirred up asteroids, scattering most away and preventing the rest from forming a planet.
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How are meteorites related to asteroids?
Most meteorites are pieces of asteroids.
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Meteorite: A rock from space that reaches Earth’s surface.Meteor: The bright tail of hot debris from the rock as it plunges
through Earth’s atmosphere.
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Peekskill, NY:
October 9, 1992
QuickTime™ and aYUV420 codec decompressor
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Meteorite Types
1. Primitive: Unchanged in composition since they first formed 4.6 billion years ago.
2. Processed: Younger, have experienced processes like volcanism or differentiation.
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Primitive meteorites: simple, all ingredients mixed together
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Processed meteorites: shattered fragments of larger
objects
Iron from a core.
Volcanic rock from a crust or mantle.
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What do we learn from meteorites?
Primitive meteorites reveal the age of the solar system.
Processed meteorites show that differentiation and volcanism happened on asteroids.
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Meteorites from the Moon and Mars
A few meteorites arrive from the Moon and Mars.
Composition differs from asteroid fragments, matches planet samples.
A cheap (but slow) way to acquire Moon and Mars rocks!
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How do comets get their tails?
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Comet Facts
Formed beyond the frostline, comets are icy counterparts to asteroids.
The nucleus of a comet is like a “dirty snowball.”
Most comets do not have tails. Most remain forever frozen in the outer solar system.
Only comets that enter the inner solar system grow tails.
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Nucleus of a Comet
A “dirty snowball.”
Source of material for comet’s tail.
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Anatomy of a Comet
Coma is atmosphere that comes from heated nucleus.
Plasma tail is gas escaping from coma, pushed by solar wind.
Dust tail is pushed by photons.
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Deep Impact
Mission to study nucleus of Comet Tempel 1.
Projectile hit surface on July 4, 2005.
Many telescopes studied aftermath of impact.
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Comets eject small particles that follow the comet around in its orbit and cause meteor showers when Earth crosses the comet’s orbit.
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Meteor showers appear to emanate from the same area of sky because of Earth’s motion through space.
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Where do comets come from?
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Kuiper belt:Orderly orbits from 30–100 AU in disk of solar system.
Oort cloud:Random orbits extending to about 50,000 AU.
Only a tiny number of comets enter the inner solar system —most stay far from the Sun.
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How did they get there?
Kuiper belt comets: disk leftovers that share the orderly motions of planets.
Oort cloud comets: disk leftovers kicked far from the Sun by the jovian planets to form giant spherical cloud of comets.
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How big can a comet be?
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Is Pluto a planet?
Much smaller than the 8 major planets.
Not a gas giant like the outer planets.
Has an icy composition like a comet. Has a very elliptical, inclined orbit.
Pluto has more in common with comets than with the 8 major planets.
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Pluto’s Orbit
Pluto’s orbit is tilted and significantly elliptical.
Neptune orbits 3 times during the time Pluto orbits twice—resonance prevents a collision.
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Discovering Large Iceballs
In summer 2005, astronomers discovered Eris, an iceball even larger than Pluto.
Eris even has a moon: Dysnomia.
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Other Icy Bodies
There are many icy objects like Pluto on elliptical, inclined orbits beyond Neptune.
The largest ones are comparable in size to Earth’s Moon.
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Kuiper Belt Objects
These large, icy bodies have orbits similar to the smaller objects in the Kuiper Belt that become short-period comets.
So are they very large comets or very small planets?
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Is Pluto a Planet?
In 2006, the International Astronomical Union decided to call Pluto and objects like it “dwarf planets.”
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What are Pluto and other large objects of the Kuiper Belt
like?
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What is Pluto like?
Its largest moon Charon is nearly as large as Pluto itself (probably made by a major impact).
Pluto is very cold (40 K). Pluto has a thin nitrogen atmosphere that refreezes onto the surface as Pluto’s orbit takes it farther from the Sun.
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HST’s View of Pluto and its Moons
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Other Kuiper Belt Objects
Most have been discovered very recently so little is known about them.
NASA’s New Horizons mission will study Pluto and a few other Kuiper Belt objects in a planned flyby.
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ASTR100 (Spring 2008) Introduction to AstronomyThe Impact Hazard
Prof. D.C. Richardson
Sections 0101-0106
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Have we ever witnessed a major impact?
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Comet SL9 caused a string of violent impacts on Jupiter in 1994, reminding us that catastrophic collisions still happen.
Tidal forces tore it apart during a previous encounter with Jupiter.
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This crater chain on Callisto probably came from another comet that tidal forces tore to pieces.
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Impact plume from a fragment of comet SL9 rises high above Jupiter’s surface.
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Dusty debris at an impact site.
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Artist’s conception of SL9 impact.
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Several impact sites.
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Impact sites in infrared light.
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Did an impact kill the dinosaurs?
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Mass Extinctions
Fossil record shows occasional large dips in the diversity of species: mass extinctions.
The most recent was 65 million years ago, ending the reign of the dinosaurs.
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Iridium—evidence of an impact
Iridium is very rare in Earth surface rocks but often found in meteorites.
Luis and Walter Alvarez found a worldwide layer containing iridium, laid down 65 million years ago, probably by a meteorite impact.
Dinosaur fossils all lie below this layer.
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Dinosaur fossils in lower rock layers.
No dinosaur fossils in upper rock layers.
Thin layer containing rare element iridium.
Iridium Layer
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Consequences of an Impact
A meteorite 10 km in size would send large amounts of debris into the atmosphere.
Debris would reduce the amount of sunlight reaching Earth’s surface.
The resulting climate change may have caused mass extinction.
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Likely Impact Site
Scientists found a large subsurface crater about 65 million years old in Mexico.
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Comet or asteroid about 10 km in diameter approaches Earth…
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Is the impact threat a real danger or just media hype?
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Facts About Impacts
Asteroids and comets have hit Earth.
A major impact is only a matter of time: not IF but WHEN.
Major impacts are very rare. Extinction-level events: ~ millions of years.
Major damage: ~ tens–hundreds of years.
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x
Tunguska, Siberia: June 30, 1908.A ~40 meter object disintegrated and exploded in the atmosphere.
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Meteor Crater, Arizona: 50,000 years ago (50 meter object).
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Frequency of Impacts
Small impacts happen almost daily.
Impacts large enough to cause mass extinctions are many millions of years apart.
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Impacts in the Media…
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Near miss!
On April 13, 2029, NEA 2004 MN4 is predicted to pass within 5.7 ± 1.4 Earth radii of our planet!
Asteroid now called 99942 Apophis…
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The asteroid with our name on it
We haven’t seen it yet. Deflection is more probable with years of advance warning.
Control is critical: breaking a big asteroid into a bunch of little asteroids is unlikely to help.
We get less advance warning of a killer comet…
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What are we doing about it?
Stay tuned to:http://impact.arc.nasa.gov/
Deflection techniques include… Pushing asteroid using spacecraft. Erecting solar sail on asteroid. Installing mass driver on asteroid. Changing surface reflectivity. Nuclear weapons (last resort).
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How do other planets affect impact rates and life on
Earth?
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The gravity of a jovian planet (especially Jupiter) can redirect a comet.
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Jupiter has directed some comets toward Earth but has ejected many more into the Oort cloud.
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Was Jupiter necessary for life on Earth?
Impacts can extinguish life.
But were they necessary for “life as we know it”?