Artist concept of lightning on Venus. Credit: NASAVenus has reentered our sky in its part-time job as the Evening Star, appearing as a uniquely brilliant white beacon over the western horizon after sunset.

With all the attention that the exploration of certain other planets has received lately, I feel that Venus exploration has fallen off our radar a bit, and that it is high time for an update.

There is no lack of exploration of Venus today: NASA’s MESSENGER spacecraft, bound for Mercury, flew by Venus twice (2006, 2007), making observations on the fly; Japan is currently planning to send a climate orbiter mission (“Planet C”) there in 2010; and the European BepiColombo will perform a couple of Venus flybys of its own, in 2013, on its way to Mercury.

Most notably, the European Venus Express orbiter is in the middle of a two-year mission of exploration, and has revealed new and fascinating things about Venus–a planet whose cloud-shrouded surface kept us mostly ignorant about it until recent decades. (Before the 1960’s it was even speculated that Venus might be a steamy swamp or rain forest world!)

Here’s a quick recap of some of the highlights of Venus Express’s findings:

“Hurricanes” at the poles: Venus Express’s VIRTIS instrument, which is able to probe several different layers of the atmosphere, has put together a detailed picture of wind behavior at different latitudes and different altitudes. What was discovered from these observations is that Venus has giant, hurricane-like vortexes capping its poles. Winds within these systems all flow in generally the same direction, as you’d expect with hurricanes, circling mostly windless “eyes” at their centers at the poles.

Lighting: Evidence of lightning on Venus was detected by earlier orbiter and lander missions, and Venus Express has confirmed it–maybe more lightning activity than on Earth. What makes Venus’s lightning unique among the planets with lightning (Earth, Jupiter, and Saturn, as far as we know) is that it’s the only case where lightning is formed by something other than clouds of water droplets–in Venus’s case, sulfuric acid droplets do the trick. Lightning can be an important factor in that it breaks up atmospheric molecules and allows them to recombine in different forms.

Active volcano search: It has long been suggested that there may be active volcanoes on Venus today, though no direct evidence (like images of erupting volcanoes, for example) have yet been obtained. Venus Express has measured large variations over time in the concentrations of sulfur dioxide in Venus’s atmosphere–a compound that on Earth comes from volcanic eruptions.

There’s a lot more to say about Venus, as it is a world as varied and fascinating as the Earth (minus the life forms, as far as we know). Though it may not be the hottest vacation spot in the solar system, with its pressure cooker of a toxic, acid-laced atmosphere, it is one of those great mysteries that we actually get to watch unfold before us as exploration of it moves forward.

NASA’s MESSENGER spacecraft at Mercury-artist concept.

Photo by: NASA

I’ve been waiting for the “whole story” on Martian ice at the Phoenix lander site to unfold more completely, but the chemical analyses have not yet run their full courses-so I’ve decided to widen the focus on this blog to give a status report on current active robotic exploration of planets going on around the Solar System.

Limiting my scope to only planetary spacecraft, the list is still respectable. In no particular order, here’s the round-up:

Spirit: Mars Exploration Rover Spirit’s activities on the Martian surface have been reduced to save on power, but the robot remains alive. With the arrival of Martian winter, Spirit spends more power running heaters to keep key electronic and power equipment healthy. Spirit remains in the giant Gusev Crater, where it will spend its entire life on Mars.

Opportunity: Exploring a much smaller crater of its own, Victoria Crater-Spirit’s twin, Opportunity, continues its investigation of the rock layers of Mars’ geological history. As of June 10, Opportunity has clocked in at 7.26 miles of total “roving” on Mars, since its landing back in 2004.

Phoenix: The brand-spankin’-new Mars Phoenix lander has been digging into one of Mars’ greatest scientific mysteries: water. Detailed chemical analysis of samples taken at Phoenix’s site near the northern polar ice cap is underway, but the big question– is Phoenix standing on frozen Martian water– has been answered: yes.

Mars Reconnaissance Orbiter: The newest orbiter in the Martian fleet continues to send back its extreme-high-resolution imagery and its revealing chemical measurements, as well as to serve as a high-speed data and communication relay for other Mars-exploring robots.

Mars 2001 Odyssey: Credited with detecting the massive amounts of frozen water in Mars’ northern hemisphere-the same ice that the Phoenix lander is now scraping at, Mars 2001 Odyssey continues its surveillance of Mars’ chemistry and atmosphere.

Mars Express: The European orbiter that launched the ill-fated Beagle II lander has continued on a respectable career of exploration in its own right. Mars Express also helped support the landing of the Phoenix.

Cassini: Saturn’s first robot-in-residence, Cassini, has concluded its initial 4-year mission and is now continuing on an extended mission. Cassini has given us unprecedented close-up images and measurements of many of Saturn’s stunning moons, its complicated ring system, and the swirling, aurora-touched cloud formations of Saturn itself.

MESSENGER: The first spacecraft to visit the little-understood Mercury since 1975 made its first flyby of that planet last January, and will settle into a permanent orbit in March 2011. Even the few pics it snapped as it hurled by gave us far more detailed images of Mercury than ever before.

New Horizons: Launched a couple years ago on its outward bound, meteoric flight to Pluto, New Horizons has already performed some exploration duty, capturing images and data of Jupiter, Jupiter’s volcanic moon Io, and Jupiter’s long magnetic “tail.” Now in “cruise mode,” this little robot will fly past Pluto (dwarf planet; king of the Plutoids) in July 2015.

Voyagers 1 and 2: Do you remember the remarkable voyages of discovery made by the Voyager spacecraft, both launched in 1977? Since completing their primary missions of flying by the Gas Giant planets (Voyager 1 at Jupiter and Saturn, Voyager 2 at all four), these two veterans have continued to operate and send information back to Earth, and are now about 3 times more distant from the Sun than Pluto.

That’s the wrap. If I missed anyone, my apologies!

A patch of what might be ice, exposed by Phoenix’s
landing rockets.So, did it land on ice? Huh? Did it?

Two blogs ago I wrote about the then upcoming landing of the Phoenix spacecraft on Mars, near the Northern polar ice cap (Probing the Martian Pole). The entire point of landing on Mars’ extreme northern plains was to find and examine ice-ice we know is up there in great abundance, as detected by orbiting spacecraft (Mars Odyssey 2001).

There, frozen under the surface dust layers, is a vast deposit of ice-”enough to fill Lake Michigan twice.” So Phoenix was sent to actually land there and scrape up surface samples of the soil, and hopefully ice. The question was, would the layer of dust covering the ice be thin enough for Phoenix to reach the ice with its robotic arm and shovel?

The landing occurred on May 25th-a successful landing. NASA broadcast the drama live on NASA TV, which we shared with several hundred Chabot visitors via planetarium, theater, and closed-circuit TV. There were no actual images coming from Phoenix during the landing-after all, it was cooped up in its protective shell for much of the descent-but the excitement of the real-time drama and the nervous faces of NASA/JPL were enough to enthrall our audience. Pictures wouldn’t come form Phoenix until later that night at the earliest.

But the pictures did come in over the days following. At first they looked much like images from other Mars landers (Viking, Pathfinder, Spirit, Opportunity), only flatter. Rusty red soil, low flat horizon, a scattering of pebbles and rocks. The landscape itself appeared less interesting to me than other landing sites-but if you measure Phoenix’s success by the beauty of the scenery, you’re missing the point.

Phoenix is pretty much all about the ice, and what chemicals are frozen and preserved in it. The questions asked by the Phoenix mission are: did life ever arise on Mars, is the current climate on Mars suitable to support life, and what is Mars’ geological makeup? If the vast ice deposits of the flat northern hemisphere lowlands are the frozen leftovers of what was once a liquid sea, then are there chemical clues of past conditions-even past life-locked up and preserved there?

So, do we have answers to these questions yet? Is there ice under Phoenix within reach of its scooper? At the time of my writing this the answer is: maybe. During the first week of testing Phoenix’s systems to get it ready for full-on prospecting, a picture of the ground underneath the lander was taken using the camera attached to the robotic arm. This picture revealed a patch of solid substance that seems to have been exposed by the blast of Phoenix’s landing rockets. It looks like it could be ice, but until a sample is analyzed we won’t know for sure (because, it could be solid rock, too).

The first sample scoop of soil dug up by Phoenix’s shovel was placed in a bucket on board the lander and examined by camera, before being carefully dumped into a designated sample waste location (Mars’ first land fill). The picture revealed some white substance in the reddish soil-which could be ice, or possible salt.…

Stay tuned in the coming days and weeks for hot news from the ice as Phoenix conducts its investigations in earnest.