Category Archives: planetary science

exoplanets, extrasolar planets, planetary science

They’re Having the Vapors!!

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Some Protoplanetary Disks have Water Vapor

Image:M42proplyds.jpgSo, not only have astronomers found methane in the atmosphere of a planet circling another star, but now CalTech astronomers have found water vapor in the spinning disks of gas and dust surrounding other stars. These disks, called protoplanetary disks, or “proplyds” for short, are where planets are born.

The Earth and other planets of the solar system formed in a proplyd beginning more than 4.5 billion years ago, and so we look to other systems to understand how planets are born, and how ours looked at that time. The image here is a protoplanetary disk in the Orion Nebula studied by Hubble Space Telescope.

The astronomers used NASA’s Spitzer Space Telescope and the Keck II telescope on Mauna Kea in Hawai’i to study the infrared wavelengths of light emitted by from these disks. The chemical fingerprints of water vapor showed up in disks around the stars DR Tau and AS 205A. The next step was to figure out where the vapor exists in the disk around each star. So, the science team (consisting of astronomers from CalTech, the Leiden Observatory in the Netherlands, SRON, and the University of Texas at Austin) made high-resolution measurements at shorter wavelengths of infrared light. The data showed the clumps of material where the water resides were moving at fast speeds, meaning that the clumps are closer to their stars, possibly in regions where Earth-like planets might be forming.

Now, you might think, “Okay, so they’ve found water vapor at a couple of stars. So what?” Astronomers expect to make more observations of dozens of similar-type stars, and the two instruments they’ve used should turn up more water vapor in more proplyds (if it exists). The bigger implications lie with figuring out how water concentrations evolve and survive in protoplanetary disks and eventually create oceans (or ice-covered planets). Who knows? What scientists find may help us understand how Earth got its oceans. Stay tuned!

cassini, moons, planetary science

Ah Enceladus

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I Remember You Well

The first time I “met” the Saturnian moon Enceladus was during the Voyager 2 flyby in August, 1981. I was a wet-behind-the-ears science writer/editorial assistant at The Denver Post, and somehow I got the managing editor to send me out to JPL to cover the mission. I had an idea there was a “local angle” and that I’d pursue it. Turns out there was–a guy named Jim Warwick at the University of Colorado had a planetary radio astronomy team hooked up to the Voyager mission, and so I hooked on to him as a sort of science guide. It was fateful.

The first closeups of Enceladus came a day or so into the flyby, and when they appeared on the TV screen in the Von Karman auditorium at JPL, we were all entranced by the details. This was quite a moon! Cratered, cracked, covered with strange grooved areas. I was hooked on planetary science for life!

Last week, the Cassini Mission at Saturn flew REALLY close to Enceladus, looking to study the polar regions. It flew through some icy water plumes jetting out from fractured, geyser-like openings in the south polar region, and took some time to look around the north pole area, which has also been modified by geysers and cratering in the past.

This image shows this icy moon’s north polar region, and a LOT of evidence for internal activity (driven by heat). The surface is cratered, sure, but those craters have disrupted regions that were resurfaced sometime in the distant past. And, some flow-like formations seem to have gone right through some craters. What would be resurfacing Enceladus? One explanation is tectonism, surface activity driven by heating from within.

Since Enceladus is largely ice with a rocky core, heating from below the surface could easily melt the interior ices. Eventually that melt is forced out through cracks in the surface–where it acts as a kind of repaving material. Incoming impactors AND pressure from below continue to disrupt the surface, and you get these terrains where craters are interrupted by flow features and smooth plains are torn up by craters. It’s quite an interplay of planetary activity and surface modification out there. The next step is to figure out the timeline for these activities. Obviously Enceladus is undergoing resurfacing pretty often, given that there are geysers shooting out material around its south pole. But, the big question now is, “How long ago was the north polar region active?” Stay tuned!