[meteorite-list] Remnants of 1994 Comet Impact Leave Puzzle at Jupiter

From: Ron Baalke <baalke_at_meteoritecentral.com>
Date: Mon Aug 23 13:22:24 2004
Message-ID: <200408231722.KAA14462_at_zagami.jpl.nasa.gov>

http://space.com/scienceastronomy/mystery_monday_040823.html

Remnants of 1994 Comet Impact Leave Puzzle at Jupiter
By Robert Roy Britt
space.com
23 August 2004

Jupiter's atmosphere still contains remnants of a comet impact from a
decade ago, but scientists said last week they are puzzled by how two
substances have spread into different locations.

The new study also discovered two previously undetected chemicals in
Jupiter's air.

Grasping what chemical compounds are in and above the Jovian clouds and
how they move about could help scientists understand planets outside our
solar system, too, said the researchers who produced the work.

>From July 16 through July 22, 1994, more than 20 fragments of Comet
P/Shoemaker-Levy 9 collided with the gaseous planet, all coming in at
about the same latitude, 45 degrees south. Fragments up to 1.2 miles (2
kilometers) sent plumes of hot gas into the
Jovian atmosphere. Dark scars lasted for weeks.

Shocks created by the impacts led to high-temperature chemical reactions
that produced hydrogen cyanide, which remains in the air but has been
spread around a bit in the years since. The comet also delivered carbon
monoxide and water, which through an interaction with sunlight,
scientists suspect, was converted to carbon dioxide.

The Cassini spacecraft, now at Saturn, examined Jupiter as it swung by.
The new study draws on infrared data from Cassini collected in 2000 and
2001.

The hydrogen cyanide has diffused some both north and south, mixed by
wave activity, explained Michael Flasar of NASA's Goddard Space Flight
Center. Jupiter's cloud bands carry material around the planet swiftly,
but the bands do not mix easily. Not surprisingly, hydrogen cyanide is
most abundant in a belt at the latitude where the comet was absorbed. At
five degrees of latitude change in both directions, its presence drops
off sharply.

The highest concentration of carbon dioxide, however, has shifted away
from the latitude of the impact. It is most prevalent poleward of 60
degrees south and decreases abruptly, toward the equator, north of 50
degrees south. Another smaller spike in its presence occurs at high
northern latitudes, around 70 to 90 degrees north.

Perhaps the two chemicals got distributed at different altitudes, and
are being moved around by different currents, Flasar told SPACE.com. Or
maybe the formation of the carbon dioxide was more complex than thought.
He said it might have involved carbon monoxide first moving away from
the impact area and then interacting with other substances at higher
latitudes before being converted to carbon dioxide.

"At high latitudes, precipitation of energetic oxygen ions probably
occurs, associated with Jupiter's magnetically induced lights, known as
aurora," Flasar explained. "These energetic ions could react with
Jupiter's atmosphere to produce hydroxyl, which can oxidize carbon
monoxide to produce carbon dioxide."

If all that sounds complicated, you're not alone in wondering what's
going on.

"We're scratching our heads, and we need to work through these, and
perhaps other, scenarios," said Flasar, who is principal investigator
for Cassini's Composite Infrared Spectrometer.

The study, led by Virgil G. Kunde of the University of Maryland, was
published Thursday in the online version of the journal Science.

The work also uncovered two new compounds, diacetylene and a so-called
methyl radical, which are products of the breakup of methane by
ultraviolet radiation from the Sun. These were expected but had not been
observed at Jupiter before.

So far as astronomers know, the more than 100 giant planets found
outside our solar system might be something like Jupiter. Only one has
had its atmosphere probed. Better knowledge of the substances in Jupiter,
and how things move around, should help set the stage for grasping the
formation and evolution of gaseous extrasolar planets, the researchers say.

"An understanding of the processes governing the composition and
distribution of chemical species in Jupiter's atmosphere is required to
successfully understand the chemical composition of extrasolar planets,"
they write in the journal.
Received on Mon 23 Aug 2004 01:22:20 PM PDT