What’s Up this Week: May 28 – June 3, 2007

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Monday, May 28 – On this day in 1959, the first primates made it to space. Abel (a rhesus monkey) and Baker (a squirrel monkey) lifted off in the nose cone of an Army Jupiter missile and were carried to sub-orbital flight. Recovered unharmed, Abel died just three days later from anesthesia during an electrode removal, but Baker lived on to a ripe old age of 27.

Tonight let’s monkey around the stars as we head towards the Moon and see Spica, just a little more than a degree to the north. Although at first glance tonight crater Copernicus will try to steal the scene, head further south to capture another lunar club challenge – Bullialdus. Even binoculars can make out this crater with ease near the center of Mare Nubium. If you’re scoping – power up – this one is fun! Very similar to Copernicus, note Bullialdus’ thick, terraced walls and central peak. If you examine the area around it carefully, you can note it is a much newer crater than shallow Lubiniezsky to its north and almost non-existent Kies to the south. On Bullialdus’ southern flank, it’s easy to make out its A and B craters, as well as the interesting little Koenig to the southwest.

Now let’s head about four fingerwidths northwest of Beta Virginis for another unusual star – Omega. Classed as an M-type red giant, this 480 light-year distant beauty is also an irregular variable which fluxes by about half a magnitude. Although you won’t notice much change in this 5th magnitude star, it has a very pretty red coloration and is worth the time to view.

Tuesday, May 29 – Today in 1919, a total eclipse of the Sun occurred and stellar measurements taken along the limb agreed with predictions based on Einstein’s General Relativity theory – the first such confirmation. Although we call it gravity, spacetime curvature deflects the light of stars near the limb, causing their apparent positions to differ slightly. Unlike today’s astronomy, at that time you could only observe stars near the Sun’s limb (within less than an arc second) during an eclipse. It’s interesting to note that even Newton had his own theories on light and gravitation which predicted some deflection!

Tonight would be a wonderful opportunity for Moongazers to return to the surface and have a look at the peaceful Sinus Iridum area. If you’ve been clouded out before, be sure to have a look for telescopic lunar club challenges – Promontoriums Heraclides and LaPlace.

If you’re up for a bit more of a challenge, then let’s head about 59 light-years away in Virgo for star 70. You’ll find it located about 6 degrees northeast of Eta and right in the corner of the Coma, Boötes, and Virgo border. So what’s so special about this G-type, very normal-looking 5th magnitude star?

It’s a star that has a planet.

Long believed to be a spectroscopic binary because of its 117 day shifts in color, closer inspection has revealed that 70 Virginis actually has a companion planet. Roughly 7 times larger than Jupiter and orbiting no further away than Mercury from its cooler-than-Sol parent star, 70 Virginis B just might well be a planet cool enough to support water in its liquid form.

How “cool” is that? Try about 85 degrees Celsius…

Wednesday, May 30 – Tonight let’s have a look at a very bright and changeable lunar feature that is often over-looked. Starting with the great grey oval of Grimaldi, let your eyes slide along the terminator towards the south until you encounter the bright crater Byrgius.

Named for Joost Burgi, who made a sextant for Tycho Brahe, this “seen on the curve” crater is really quite large with a diameter of 87 kilometers. Perhaps one of the most interesting features of all is high albedo Byrgius A, which sits along its east wall line and produces a wonderfully bright ray system. While it is not noted as a lunar club challenge, it’s a great crater to help add to your knowledge of selenography!

Now let’s add to our double star list as we hunt down Zeta Boötes located about 7 degrees southeast of Arcturus. This is a delightful multiple star system for even small telescopes.

Thursday, May 31 – While tonight the Moon will appear about as full as it gets to some observers, the date won’t be “official” until tomorrow. While the glare will make it difficult to do many things, we can still have a look at other bright objects! Let’s start tonight by going just north of Zeta Boötes for Pi. With a wider separation, this pair of whites will easily resolve to the smaller telescope.

Now skip up northeast about a degree for Omicron Boötes. While this is not a multiple system, it makes for a nice visual pairing for a binocular challenge. For telescopes, the southeastern star holds interest as a small asterism.

Continue northeast another two degrees to discover Xi Boötes. This one is a genuine multiple star system with magnitude 5 and 7 companions. Not only will you enjoy this G-type sun for its duplicity, but for the fine field of stars in which it resides!

Friday, June 1 – Tonight the Moon is full. Often referred to as the Full Strawberry Moon, this name was a constant to every Algonquin tribe in North America. But, our friends in Europe referred to it as the Rose Moon. The North American version came about because the short season for harvesting strawberries comes each year during the month of June – so the full Moon that occurs during that month was named for this tasty red fruit!

Tonight before it rises and the light commands the sky, let’s have a look at a tasty red star – R Hydrae. You’ll find it about a fistwidth south of Spica or about a fingerwidth west of Gamma Hydrae.

R was the third long term variable star to be discovered and it is credited to Maraldi in 1704. While it had been observed by Hevelius some 42 years earlier, it was not recognized immediately because its changes happen over more than a year. At maximum, R reaches near 4th magnitude – but drops well below human eye perception to magnitude 10. During Maraldi’s and Hevelius’ time, this incredible star took over 500 days to change, but it has speeded up to around 390 days in the present century.

Why such a wide range? Science isn’t really sure. R Hydrae is a pulsing M-type giant whose evolution may be progressing more rapidly than expected due to changes in structure. What we do know is that it is around 325 light-years away and is approaching us at around 10 kilometers per second.

In the telescope, R will have a pronounced red coloration which deepens near minima. Nearby is 12th magnitude visual companion star Ho 381, which was first measured for position angle and distance in 1891. Since that time no changes in separation have been noted, which leads us to believe that the pair may be a true binary.

Saturday, June 2 – Before the Moon rises tonight, let’s return again to R Hydrae. While observing a variable star with either the unaided eye, binoculars, or a telescope can be very rewarding, it’s often quite difficult to catch changes in long-term variables, because there are times when the constellation is not visible. While R Hydrae is unique in color, let’s drop about half a degree to the southeast to visit another variable star – SS Hydrae.

SS is a quick change artist – the Algol-type. While you will need binoculars or a telescope to see this normally 7.7 magnitude star, at least its fluctuations are far more rapid, with a period of only 8.2 days. With R Hydrae we have a star that expands and contracts causing the changes in brightness – but SS is an eclipsing binary. While less than a half magnitude is not a noteworthy amount, you will notice a difference if you view it over a period of time. Be sure to note that this is actually a triple star system, for there is also a 13th magnitude companion star located 13″ from the primary. Watch if as often as possible and see if you can detect changes in the next few weeks!

When the Moon rises tonight, take a look at the northwestern limb about half the distance between Grimaldi and Sinus Iridum. Our search is for an “on the edge” crater known as Einstein. Use the prominent crater Kraft to help guide you to this extreme edge feature!

Sunday, June 3 – If you’re up early, why not keep a watch out for the peak of the Tau Herculids meteor shower? These are the offspring of comet Schwassman-Wachmann 3, which broke up in 2006. The radiant is near Corona Borealis and we’ll be in this stream for about a month. At best when the parent comet has passed perihelion, you’ll catch about 15 per hour maximum. Most are quite faint and the westering Moon will interfere, but sharp-eyed observers will enjoy it.

While we have a bit of time tonight to spare before the Moon rises, let’s try a visual double for the unaided eye – Eta Virginis. Can you distinguish between a 4th and 6th magnitude pair?

The brighter of the two is Zaniah (Eta), which through occultation had been discovered to be a triple star. In 2002, Zaniah became the first star imaged by combining multiple telescopes with the Navy Prototype Optical Interferometer. This was the first time the three were split. Two of them are so close that they orbit in less than half the distance between the Earth and Sun!

Binocular users should take a look at visual double Rho Virginis about a fistwidth west-southwest of Epsilon. This pair is far closer and will require an optical aid to separate. The brighter of this pair – Rho – is a white, main sequence dwarf with a secret… It’s a variable! Known as a Delta Scuti type, this odd star can vary slightly in magnitude in anywhere from 30 minutes to two and a half hours as it pulsates.

For mid-to-large telescopes, Rho offers just a little bit more. The visual companion star has a visual companion as well! Less than a half degree southwest of Rho is a small, faint spiral galaxy – NGC 4608 – at 12th magnitude, it’s hard to see because of Rho’s brightness…but it’s not alone. Look for a small, but curiously shaped galaxy labeled NGC 4596. Its resemblance to the planet Saturn makes it well worthwhile!

Podcast: Neutron Stars and their Exotic Cousins

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Astronomers are always trying to get their hands on bigger and more powerful telescopes. But the most powerful telescopes in the Huge stars become black holes, and small stars become white dwarfs. But medium-sized stars can become neutron stars; exotic objects that overcome the nuclear force holding protons and electrons apart. What was once the size of a star is compressed down to only a few dozen kilometres across.

Click here to download the episode

Neutron Stars and their Exotic Cousins – Show notes and transcript

Or subscribe to: astronomycast.com/podcast.xml with your podcatching software.

Astronauts Will Get Some Warning When the Space Storm’s Coming

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One of the great risks of space travel is the threat from solar radiation storms. An unlucky group of astronauts traveling to the Moon could get caught unprotected as a hail of charged particles and radiation blast through the spacecraft. But now NASA researchers think the Solar and Heliospheric Observatory (SOHO) will be able to give astronauts some warning before the big storm hits.

SOHO is normally used for scientific observations of the Sun. But it’s equipped with an instrument called the Comprehensive Suprathermal and Energetic Particle Analyzer (COSTEP), which counts particles coming from the Sun, and measures their energies.

One of the main predictors are electrons, which aren’t dangerous in themselves, but are the first wave of a coming storm. The electrons are lighter than the other particles, so they’re carried out ahead of the heavier, and more dangerous particles. By analyzing hundreds of solar storms, the researchers were able to match electrons with a predicted density of ions.

When SOHO is experiencing one of these electron storms, astronauts traveling to the Moon will be experiencing it as well. And the more dangerous ions and heavier particles are about to arrive. This advance notice will allow the astronauts to retreat to a safer location in the spacecraft and ride out the storm, suffering the minimum radiation damage.

This technique was able to predict all 4 major storms in 2003, providing advance warnings from 7 to 74 minutes.

Original Source: NASA News Release

Merging Stars Create a New Class of Explosion

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Astronomers know of several kinds of explosions in space. Supernovae occur when massive stars detonate or become black holes. Gamma ray bursts occur for certain kinds of supernovae, or the collision between compact objects, like neutron stars. And novae happen when stellar material piles up on the surface of a star or white dwarf, and then detonates. But now it looks like a new class of explosions have been identified: a red luminous nova.

The explosive event was discovered in a nearby galaxy in the Virgo cluster called Messier 85. Astronomers watched a star flare up, not as bright as a supernova, but much brighter than a nova. Instead of a quick flash, it brightened up much more slowly, with a distinctive red colour.

Astronomers speculate that the explosion occurred when two ordinary stars in a binary system finally came together, undergoing a process called “common envelope evolution”.

The cooling afterglow of the explosion was too dim to see in Hubble, but it was still bright enough in the infrared spectrum to see with the Spitzer Space Telescope. There’s little doubt that it’s a new class of object, and now astronomers will be fine tuning their searches to turn up more objects like this.

Original Source: Caltech News Release

Dark Caverns Discovered on Mars

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When I first saw this image, I thought it was some kind of joke, or Photoshop trick. But nope, this is real. NASA’s Mars Reconnaissance orbiter has returned images of strange cavern entrances on Mars.

See that dark spot in the middle of the picture? It seems to be a hole, in an otherwise smooth landscape of lava. It isn’t an impact crater because it lacks a raised rim or ejecta. Light from the Sun must be getting down there, but it’s so deep that none of it is bouncing back out. It’s just a dark hole.

So what is it? Scientists think it’s some kind of chamber with a collapsed roof, or pit with extremely vertical sides. Whatever the case, it’s quite surprising to see.

And just in case you think this is an anomaly, there are actually 7 of these features discovered on Mars so far.

The Planetary Society’s Emily Lakdawalla has more details.

Astrosphere for May 25, 2007

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In case you missed it, I hosted the 4th Carnival of Space yesterday here at Universe Today, so no astrosphere. But today is a new day, and there’s an astrosphere:

First, Skymania News takes us on a tour of the new planetarium which is part of the restoration of the Royal Observatory in London.

Really Rocket Science considers the Planetary Society’s challenge of tagging an asteroid. How hard would it really be?

Space Prizes has a quick note about some new scholarships announced by the American Astronomical Society. $10,000 would go a long way to paying off tuition fees.

Alan Boyle joins other space bloggers in Houston for the International Space Development Conference.

A telescope made from rotating liquid is an old idea, but now people want to put one on the Moon.

The Astroprof gives you a detailed explanation of nebulae.

Coastal Scene on Titan

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Take a look at the image attached to this story. If you didn’t know any better, you’d think you were looking at a rugged coastline somewhere on Earth. Maybe some island in the Mediterranean, or Norwegian fjord. Nope, you’re looking at a completely alien world: Titan.

NASA’s Cassini spacecraft took this image on May 12, 2007 during its most recent flyby of Saturn’s largest moon. During the flyby, its radar instrument captured this image using its radar instrument. Smooth surfaces, like liquid are seen as black, while the textured regions are land.

While other bodies of liquid such as lakes have been seen on Titan before, nothing has had these kinds of features: channels, islands, bays, and other terrain you’d see on Earth. But instead of water, this liquid is probably a mixture of ethane and methane. Since there are no brighter regions in the liquid regions of the image, scientists are assuming the ocean exceeds tens of metres deep.

The image is about 160 kilometers (100 miles) by 270 kilometers (170 miles) across.

Original Source: NASA/JPL/SSI/ESA News Release

Telescope Under the Ice in Antarctica

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If you think you need to install a telescope on a mountaintop, or even above the surface of the Earth, think again. A new telescope currently being installed near the South Pole has detectors more than 2 kilometres under the surface of the Antarctic ice cap. For the neutrinos it’s searching for, that much ice is the same as nothing at all.

Neutrinos are illusive particles generated by the fusion reactions in the Sun and other cosmic events. They barely interact with normally matter, passing right through like it’s complete vacuum. Only in the rarest occasions will a neutrino collide directly normal matter, releasing a torrent of subparticles and radiation.

Once completed, the IceCube observatory will consist of detectors arranged in a 1 kilometre cubic array frozen underneath the surface of the Antarctic ice cap. Construction is currently into its 3rd year, with more than 20 institutions participating. The final instrument will consist of more than 70 strings, each containing more than 60 optical detectors frozen into the ice.

When operational, IceCube will be able to detect neutrinos from the Sun, as well as some of the most catastrophic events in the Universe, such as a supernova or black hole. The neutrinos will interact with particles of ice within the array, and produce a cascade of particles that will produce a flash of light captured by the optical detectors.

The full construction is going to take another 3-4 years, but the array is already operational, and gathering scientific results.

Original Source: University of Delaware News Release

Metal Poor Star Found With Planets

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When you look at the ground beneath your feet, you’re looking at matter created in the heart of stars at the end of their lives. Some of the heavier elements were fashioned in the supernovae explosions of massive stars. And in many cases, these elements went through several generations of stars. So it was a tremendous surprise this week when astronomers discovered planets orbiting a metal poor star.

The discovery was made by a team of researchers from the University of Texas using the 9.2-metre Hobby-Eberly Telescope at McDonald Observatory. They found a system of two Jupiter-like planets orbiting a star that’s so low in metals that it shouldn’t have planets at all.

But there they are.

The star is known as HD 155358, and the planets were discovered using the radial velocity method, where the gravity from the planets pull the star back and forth with a velocity we can detect here on Earth. This allows astronomers to calculate their mass and the length of their orbit.

One planet has an orbital period of 195 days and has 90% the mass of Jupiter. The other takes 530 days and has 50% the mass of Jupiter. They actually orbit so close to one another, that they must gravitationally interact. They push each other around.

A commonly-held model of planetary formation requires that there are large quantities of heavy metals present in the protoplanetary disk. Finding such a low metal star, but still with two planets around it, is an impressive find, and will give astronomers reason to reconsider their theories.

Original Source: UT Austin News Release

Carnival of Space #4

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Universe Today is hosting the Carnival of Space for a second week. This time, it’s the mighty carnival #4. Once again, we’ve got a round-up of cool space-related articles from writers and bloggers. If you want to get involved, and maybe even host the carnival in a future week, you can find out more at the Carnival of Space website. Thanks for dropping by, I hope you enjoy the stories.

First up, Chris Lintott takes us into the submillimetre spectrum. And it’s looking good.

At Cumbrian Sky, Stuart Atkinson is dreads the day when one of the Mars rovers dies. Not tonight…

The Astronomy Picture of the Day submits a dark night over Death Valley, and highlights the dangers of encroaching light pollution.

Deborah Byrd from the EarthSky Blogs is wondering is the line between science and science fiction is beginning to blur with the search for Spock’s homeworld.

From hi-tech to low-tech. Do modern assumptions about astronomical observation work when looking at astronomy in ancient societies? Alun Salt from Clioaudio ponders that question.

Alan Boyle from MSNBC’s Cosmic Log reports that James “Scotty” Doohan’s ashes have been found.

Centauri Dreams considers our future, when the Milky Way and Andromeda galaxy crash into one another. Who keeps the Sun?

Amanda Bauer is a fan of robots for space exploration, especially those hardworking Mars rovers. But is it time to enact the three laws of robotics?

A Babe in the Universe blog reports on the new dedication for the SOFIA airborne observatory.

Getting to space isn’t easy. Staying fit in space is hard too. Read this post from James Watt.

Pamela Gay explains the wonders of jets. No, not airplanes; the torrents of particles blasting away from black holes, new stars, and now, a brown dwarf.

Robert Pearlman at collectSPACE has been following the launch of the Shuttle Launch Experience, a new $60 million simulator designed to deliver to tourists at the Kennedy Space Center Visitor Complex the feelings and emotions during a ride to orbit. collectSPACE will be covering the public opening on Friday, but before then, they got an early look inside.

Ian Musgrave from Astroblog has news on an exotic Neptune-sized world covered in hot ice.

Terraforming Mars. Is that a good idea, or a bad idea? Colony Worlds weighs in with an opinion.

When he’s not furious, the Angry Astronomer calmly explains stellar evolution in a four part series (1 2 3 4).

Would you rather see a hundred thousand acres of restored prairie or the same space covered by solar collection arrays? Thought so. But only 62 miles away is nearly limitless room and sunshine undiluted by an inconvenient atmosphere. Brian Dunbar has his opinion.

And finally, I look forward 3 trillion years into our lonely future.

Thanks to everyone who participated, and thanks for letting me be the host. I had a blast. I’ll see you next week at the next stop in the Carnival of Space.