Blame it on the Rain (from Saturn's Rings)
A study led by the University of Leicester finds that charged-water "rain"
from Saturn's rings falls across large swaths of the planet
Diagram shows path of water flowing along magnetic field lines from Saturn’s atmosphere,
and the resultant H3+ emission, with darker bands near the equator where water is removing H3+ from the atmosphere.
Credit to NASA/JPL/Space Science Institute.
11 April 2013
A new study tracks the "rain" of charged water particles into the atmosphere of Saturn and finds there is more of it and it falls across larger areas of the planet than previously thought.
The study, led by the University of Leicester with observations funded by NASA, reveals that the rain influences the composition and temperature structure of parts of Saturn's upper atmosphere.
The paper appears in this week's issue of the journal Nature.
“Saturn is the first planet to show significant interaction between its atmosphere and ring system," said James O’Donoghue, the paper's lead author and a postgraduate researcher at Leicester.
“The main effect of ring rain is that it acts to 'quench' the ionosphere of Saturn. In other words, this rain severely reduces the electron densities in regions in which it falls.”
O’Donoghue explains that the ring's effect on electron densities is important because it explains why, for many decades, observations have shown those densities to be unusually low at certain latitudes on Saturn.
The study also helps scientists better understand the origin and evolution of Saturn's ring system and changes in the planet's atmosphere.
“It turns out that a major driver of Saturn's ionospheric environment and climate across vast reaches of the planet are ring particles located some 36,000 miles [60,000 kilometers] overhead,” said Kevin Baines, a co-author on the paper, based at NASA's Jet Propulsion Laboratory, Pasadena, Calif.
“The ring particles affect both what species of particles are in this part of the atmosphere and where it is warm or cool.”
In the early 1980s, images from NASA's Voyager spacecraft showed two to three dark bands on Saturn, and scientists theorized that water could have been showering down into those bands from the rings.
Those bands were not seen again until 2011 when the team observed the planet with Keck Observatory’s NIRSPEC, a unique near-infrared spectrograph that combines broad wavelength coverage with high spectral resolution that allowed the observers to clearly see subtle emissions from the bright parts of Saturn.
The effect was difficult to discern because it involves looking for a subtle emission from bright parts of Saturn. It required an instrument like that on Keck, which can split up a large range of light.
The ring rain's effect occurs in Saturn's ionosphere, where charged particles are produced when the otherwise neutral atmosphere is exposed to a flow of energetic particles or solar radiation.
When the scientists tracked the pattern of emissions of a particular hydrogen ion with three protons (triatomic hydrogen), they expected to see a uniform planet-wide infrared glow.
What they observed instead was a series of light and dark bands – with areas of reduced emission corresponding to water-dense portions of Saturn’s rings and areas of high emission corresponding to gaps in the rings.
They surmised that charged water particles from the planet’s rings were being drawn towards the planet along Saturn's magnetic field lines and were neutralizing the glowing triatomic hydrogen ions. This leaves large “shadows” in what would otherwise be a planet-wide infrared glow.
These shadows cover some 30 to 43 percent of the planet's upper atmosphere surface from around 25 to 55 degrees latitude. This is a significantly larger area than suggested by the Voyager images.
Both Earth and Jupiter have an equatorial region that glows very uniformly. Scientists expected this pattern at Saturn, too, but they instead saw dramatic differences at different latitudes.
“Where Jupiter is glowing evenly across its equatorial regions, Saturn has dark bands where the water is falling in, darkening the ionosphere," said Tom Stallard, a paper co-author at Leicester.
“We're now also trying to investigate these features with an instrument on NASA's Cassini spacecraft. If we're successful, Cassini may allow us to view in more detail the way that water is removing ionized particles, such as any changes in the altitude or effects that come with the time of day.”
Keck Observatory observing time was funding by NASA, with a letter of support from the Cassini mission to Saturn.
The Cassini-Huygens mission is a cooperative project of NASA, the European Space Agency, and the Italian Space Agency.
The mission is managed by JPL for NASA's Science Mission Directorate, Washington. JPL is a division of the
California Institute of Technology in Pasadena, Calif.
The full paper can be found at:
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