Lecture 9

Comets: As Primitive as you Can Get

Comets

Beyond Jupiter, icy bodies can survive in the vacuum of interplanetary space.
However, if icy bodies approach closer to the Sun than ~4 – 6 AU, they begin to sublimate.
- Sublimation: solid becomes a gas (snow on ski slope)
- This is why asteroids have no ice
- Such icy bodies are comets.

Historical Remarks

Originally thought to be one time visitors to the solar system
Edmund Halley used Newton’s laws (and Kepler) to show:
- orbits of comets seen in 1531, 1607, 1682 were the same
- predicted return in 1758-1759
Space craft now valuable tool

Comet P/Halley

Orbit of Comet P/Halley

A Typical Comet

Comet Structure

Close up view of Halley’s comet - first time nucleus imaged
The original icy body forms the "nucleus".
Darkest object in solar system
Sublimation of the nucleus forms the coma,, of the comet.
Gas escapes from regions on heated, sunlit side.
Gas drags dust with it forming dust tail - shines by reflected and scattered sunlight.

Comet Tails

"Gas" or "ion" tail:
- Straight and narrow
- Consists of ions swept up by solar wind
"Dust" tail:
- Wide and diffuse
- Solid particles pushed by radiation pressure
Comet tails always point away from the Sun
- gas tail in direction of Solar wind
- when comet leaves the inner Solar System, it goes tail first
Near the Sun, coma can expand to 100,000 km (but very low density).
Tail can be millions of kilometers long (up to 1 – 2 AU in extreme cases).

Comet Hale-Bopp:

Why Study Comets?

They are nice to look at
More importantly: Clues to formation and early evolution of solar system
- Vital role in allowing life on earth?
  - Atmosphere?
  - Oceans?

Origin of Comets

Need to explain: two classes of orbits
Long period comets
- Periods > 200 yrs, can be millions of years
- semi-major axes up to 10⁵ AU, e close to 1
- orbits randomly inclined to ecliptic
Shorter period comets
- Periods < 200yrs, usually 5-20 yrs
- Have been "captured" by planets, usually Jupiter
- small semi-major axes
- low inclination to ecliptic

Shorter period Comets

Oort Cloud - the Long Periods

Formation of Comets

Cometary bodies formed in pre-Solar nebula, about 20 – 30 AU from center
- distance of Uranus and Neptune
- temperature T ~ 100 K
  - At higher temperature, ices do not survive.
  - A lower temperatures, H₂O locked into solid hydrates of ammonia and methane.

Formation of Oort Cloud

Perturbations by Uranus and Neptune scatter the orbits of the icy bodies:
- smaller orbits: ice will sublimate quickly, don’t last.
- large orbits will form Oort Cloud
- very large orbits will escape from Solar System

Kuiper Belt - Short Period Comets

Ring of comets beyond orbit of Neptune
- Inner region: 34-45 AU, ~6x10⁹ objects
- Outer region: 45 -> 10³(?) AU with >10¹³ objects, total mass ~ 100 Earth masses
- Population of icy planetesimals that formed via accretion at their present location -
- different process from Oort cloud

Evidence for Kuiper Belt

IRAS discovery of "disks" around other stars that can be seen in the IR
Disks around 25-50% of proto stars
HST shows images of disks around stars that are just forming
Discovery of 21 trans-Neptunian objects in our Solar System
Orbital elements of Jupiter’s comets
Such disks are common and part of normal process of formation of planetary systems

Perturbations of cometary orbits probably alter their orbits so they can re-enter the inner Solar System.

Impacts by Comets on Planets

Comet SL/9

Captured by Jupiter in 1992
Collided with Jupiter after first orbit
First perijove fragmented the comet into several smaller pieces, all on the same orbit.
Fragmented comet struck Jupiter in the summer of 1994
Comet fragments hitting the upper cloud deck of Jupiter resulted in fireballs easily seen in the infrared.

What Would a Similar Collision on Earth Look Like?

Comets and the Earth: