Small Solar System Bodies Lecture 18.  Homework 10 is Due Monday, April 16 Announcements.

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Presentation transcript:

Small Solar System Bodies Lecture 18

 Homework 10 is Due Monday, April 16 Announcements

Meteorites Distinguish between: Meteoroid = small body in space Meteor = meteoroid colliding with Earth and producing a visible light trace in the sky Meteorite = meteor that survives the plunge through the atmosphere to strike the ground.... Sizes from microscopic dust to a few centimeters. About 2 meteorites large enough to produce visible impacts strike the Earth every day. Statistically, one meteorite is expected to strike a building somewhere on Earth every 16 months. Typically impact onto the atmosphere with 10 – 30 km/s (≈ 30 times faster than a rifle bullet).

Meteor Showers Most meteors appear in showers, peaking periodically at specific dates of the year.

Radiants of Meteor Showers Tracing the tracks of meteors in a shower backwards, they appear to come from a common origin, the radiant.  Common direction of motion through space.

Meteoroid Orbits Meteoroids contributing to a meteor shower are debris particles, orbiting in the path of a comet. Spread out all along the orbit of the comet. Comet may still exist or have been destroyed. Only a few sporadic meteors are not associated with comet orbits.

Meteorite Impacts on Earth Over 150 impact craters found on Earth. Famous example: Barringer Crater near Flagstaff, AZ: Formed ~ 50,000 years ago by a meteorite of ~ 80 – 100 m diameter

Impact Craters on Earth Barringer Crater: ~ 1.2 km diameter; 200 m deep Impact of a large body formed a crater ~ 180 – 300 km in diameter in the Yucatán peninsula, ~ 65 million years ago. Drastic influence on climate on Earth; possibly responsible for extinction of dinosaurs. Much larger impact features exist on Earth:

Finding Meteorites Most meteorites are small and do not produce significant craters. Good place to find meteorites: Antarctica! Distinguish between: Falls = meteorites which have been observed to fall (fall time known). Finds = meteorites with unknown fall time.

Analysis of Meteorites 3 broad categories: Iron meteorites Iron meteorites Stony meteorites Stony meteorites Stony-Iron meteorites Stony-Iron meteorites

What Does a “Meteorite” Look Like? Selection bias: Iron meteorites are easy to recognize as meteorites (heavy, dense lumps of iron-nickel steel) – thus, more likely to be found and collected.

Daily Quiz If most falls are stony meteorites, why are most finds iron meteorites? a. Stony meteorites are less weather-resistant. b. Stony meteorites look more like Earth rocks. c. Stony meteorites penetrate the ground more deeply. d. Both a and b above. e. All of the above.

The Allende Meteorite Carbonaceous chondrite, fell in 1969 near Pueblito de Allende, Mexico Showered an area about 50 km x 10 km with over 4 tons of fragments. Fragments containing calcium-aluminum- rich inclusions (CAIs) Extremely temperature- resistant materials. Allende meteorite is a very old sample of solar-nebula material!

The Origins of Meteorites Probably formed in the solar nebula, ~ 4.6 billion years ago. Almost certainly not from comets (in contrast to meteors in meteor showers!). Probably fragments of stony-iron planetesimals Some melted by heat produced by 26 Al decay (half-life ~ 715,000 yr). 26 Al possibly provided by a nearby supernova, just a few 100,000 years before formation of the solar system (triggering formation of our sun?)

The Origins of Meteorites Planetesimals cool and differentiate Collisions eject material from different depths with different compositions and temperatures. Meteorites can not have been broken up from planetesimals very long ago  so remains of planetesimals should still exist.  Asteroids

Asteroids Last remains of planetesimals that built the planets 4.6 billion years ago!

The Asteroid Belt Sizes and shapes of the largest asteroids, compared to the moon Small, irregular objects, mostly in the apparent gap between the orbits of Mars and Jupiter. Thousands of asteroids with accurately determined orbits known today.

Kirkwood’s Gaps The asteroid orbits are not evenly distributed throughout the asteroid belt between Mars and Jupiter. There are several gaps where no asteroids are found: Kirkwood’s gaps (purple bars below) These correspond to resonances of the orbits with the orbit of Jupiter. Example: 2:3 resonance

Non-Belt Asteroids Apollo-Amor Objects: Not all asteroids orbit within the asteroid belt. Asteroids with elliptical orbits, reaching into the inner solar system. Some potentially colliding with Mars or Earth. Trojans: Sharing stable orbits along the orbit of Jupiter: Trapped in the Lagrangian points of Jupiter.

Daily Quiz What causes the Kirkwood gaps of the asteroid belt? a. Orbital resonances with Earth. b. Orbital resonances with Mars. c. Orbital resonances with Jupiter. d. Orbital resonances with Saturn. e. Both a and b above.

Comets Comet Ikeya-Seki in the dawn sky in 1965

Comet Structure Nucleus Coma Tail

Comet Nucleus Small, fragile lump of porous rock Ice of water, carbon dioxide, and ammonia 10 to 100 kilometers across When comet nucleus approaches Sun, evaporation forms coma and tail

Two Types of Tails Ion tail: Ionized gas pushed away from the comet by the solar wind. Pointing straight away from the sun. Dust tail: Dust set free from vaporizing ice in the comet; carried away from the comet by the sun’s radiation pressure. Lagging behind the comet along its trajectory

Gas and Dust Tails of Comet Mrkos in 1957

Comet Hale Bopp (1997)

Dust Jets from Comet Nuclei Jets of dust are ejected radially from the nuclei of comets. Comet Hale-Bopp, with uniform corona digitally removed from the image. Comet dust material can be collected by spacecraft above Earth’s atmosphere.

Fragmenting Comets Comet Linear apparently completely vaporized during its sun passage in Only small rocky fragments remained.

The Geology of Comet Nuclei Comet nuclei contain ices of water, carbon dioxide, methane, ammonia, etc.: Materials that should have condensed from the outer solar nebula. Those compounds sublime (transition from solid directly to gas phase) as comets approach the sun. Densities of comet nuclei: ~ 0.1 – 0.25 g/cm 3 Not solid ice balls, but fluffy material with significant amounts of empty space.

Fragmentation of Comet Nuclei Comet nuclei are very fragile and are easily fragmented. Comet Shoemaker-Levy was disrupted by tidal forces of Jupiter Two chains of impact craters on Earth’s moon and on Jupiter’s moon Callisto may have been caused by fragments of a comet.

The Origin of Comets Comets are believed to originate in the Oort cloud: Spherical cloud of several trillion icy bodies, ~ 10,000 – 100,000 AU from the sun. 10,000 – 100,000 AU Oort Cloud Gravitational influence of occasional passing stars may perturb some orbits and draw them towards the inner solar system. Interactions with planets may perturb orbits further, capturing comets in short-period orbits.

The Kuiper Belt Second source of small, icy bodies in the outer solar system: Kuiper belt, at ~ 30 – 100 AU from the sun. Few Kuiper belt objects could be observed directly by Hubble Space Telescope. Pluto and Charon are Kuiper belt objects.

Impacts on Earth Comet nucleus impact producing the Chicxulub crater ~ 65 million years ago may have caused major climate change, leading to the extinction of many species, including dinosaurs. Gravity map shows the extent of the crater hidden below limestone deposited since the impact.

The Tunguska Event The Tunguska event in Siberia in 1908 destroyed an area the size of a large city! Explosion of a large object, probably an Apollo asteroid of 90 – 190 m in diameter, a few km above the ground. Energy release comparable to a 12- megaton nuclear weapon! Area of destruction from the Tunguska event superimposed on a map of Washington, D.C. and surrounding beltway.

Daily Quiz Of the following, which is a major flaw with the comet impact hypothesis for the Tunguska Event of 1908? a. A comet would have been easily seen in the predawn skies the morning of the impact. b. A small comet body would vaporize much higher in Earth’s dense atmosphere. c. The impact crater was too large for a comet body impact. d. No known comets went missing in e. No ice was found at the impact site.

Pluto Discovered 1930 by C. Tombaugh. Existence predicted from orbital disturbances of Neptune, but Pluto is actually too small to cause those disturbances.

Pluto as a (Dwarf) Planet Virtually no surface features visible from Earth. ~ 65 % of size of Earth’s Moon. Highly elliptical orbit; coming occasionally closer to the sun than Neptune. Orbit highly inclined (17 o ) against other planets’ orbits  Neptune and Pluto will never collide. Surface covered with nitrogen ice; traces of frozen methane and carbon monoxide. Daytime temperature (50 K) enough to vaporize some N and CO to form a very tenuous atmosphere.

Pluto’s Moon Charon Hubble Space Telescope image Discovered in 1978; about half the size and 1/12 the mass of Pluto itself. Tidally locked to each other.

Pluto and Charon Orbit highly inclined against orbital plane. From separation and orbital period: M pluto ~ 0.2 Earth masses. Density ≈ 2 g/cm 3 (both Pluto and Charon)  ~ 35 % ice and 65 % rock. Large orbital inclinations  Large seasonal changes on Pluto and Charon.

The Origin of Pluto and Charon Probably very different history than neighboring Jovian planets. Older theory: Modern theory: Pluto and Charon members of the Kuiper belt. Collision between Pluto and Charon may have caused the peculiar orbital patterns and large inclination of Pluto’s rotation axis. Mostly abandoned today since such interactions are unlikely. Pluto and Charon formed as moons of Neptune, ejected by interaction with massive planetesimal.

Daily Quiz If you visited Pluto and found Charon a full moon directly overhead, where would Charon be in the sky when it was at First Quarter phase? a. At the west point on the horizon. b. At the east point on the horizon. c. It depends on the time of day. d. Directly overhead. e. Either a or b above.

 Read Units 60 and 72  We will now return to talking about stars and galaxies etc. For Next Time