Weekend SkyWatcher’s Forecast – September 5 – 7, 2008

Greetings, fellow Skywatchers! The weekend has arrived at last and with it… more lunar challenge studies. Are you ready to dance with the pie-eyed piper as we seek out Piccolomini? You’ll find it to the southwest of the shallow ring of Fracastorius on Mare Nectaris’ southern shore. How about seeing double as we take on a few binary stars? It’s time to get out your binoculars and telescopes as we head to the Moon because… Here’s what’s up!

Friday, September 5, 2008 – Tonight let’s discover beauty on our own Moon as we have a look at one of the last lunar challenges of the year which occurs during the first few days of the Moon’s appearance – Piccolomini. You’ll find it to the southwest of the shallow ring of Fracastorius on Mare Nectaris’ southern shore. Piccolomini is a standout lunar feature – mainly because it is a fairly fresh impact crater. Its walls have not yet been destroyed by later impacts, and the interior is nicely terraced. Power up and look carefully at the northern interior wall where a rock slide may have rumbled toward the crater floor. While the floor itself is fairly featureless, the central peak is awesome. Rising a minimum of two kilometers above the floor, it is even higher than the White Mountains in New Hampshire!

Beta LyraeWhen you’ve caught up on your studies, let’s have a look at Beta and Gamma Lyrae, the lower two stars in the “Harp.” Beta is actually a quickly changing variable which drops to less than half the brightness of Gamma in around 12 days. For a few days the pair will seem of almost equal brightness; then you will notice the star closest to Vega begins to fade away. Beta is one of the most unusual spectroscopic stars in the sky, and it is possible that its eclipsing binary companion may be a prototypical “collapsar” (Yep – a black hole!) rather than an actual luminous body.

Double DoubleNow use the telescope for a pair of stars which are very close – Epsilon Lyrae (RA 18 44 20 Dec +39 40 12). Known to most of us as the “Double Double,” look about a fingerwidth northeast of Vega. Even the slightest optical aid will reveal this tiny star as a pair, but the real treat is with a telescope – because each component is a double star! Both sets of stars appear as primarily white, and each pair is very close in magnitude. What is the lowest power that you can use to split them?

Stargazer JackSaturday, September 6, 2008 – Today celebrates the founding of the Astronomical and Astrophysical Society of America. Started in 1899, it is now known as the American Astronomical Society. Also on this date, in 2006, the milestone 1500th episode of Jack Horkheimer’s Star Gazer series aired. The long-running short program on public television has led thousands of people, young and old, to “keep on looking up!” For a lifetime of achievement in public outreach, we salute you, Mr. Horkheimer!

Tonight when you have had a look at the Serpentine Ridge, drop south along the terminator and see if you can identify the very old crater Abulfeda, west of Theophilus.

Abulfeda - W. HigginsThis charming crater was named for Prince Ismail Abu’l Feda, who was a Syrian geographer and astronomer born in the late thirteenth century. Spanning 62 kilometers, its rocky walls show what once was a great depth, but the crater is now filled-in by lava, and drops to a mere 3110 meters below the surface. While it doesn’t appear very large to the telescope, that’s quite big enough to entirely hide Mt. Siple – one of the highest peaks in Antarctica! If conditions are steady, power up and take a look at Albulfeda’s smooth-appearing floor. Can you see many smaller strikes? If the lighting is correct, you might even spot one far younger than the others!

Ranger 9 CamerasSunday, September 7 – For binoculars and telescopes, tonight’s Moon will provide a piece of scenic history as we take an in-depth look at crater Albategnius. This huge, hexagonal, mountain-walled plain will appear near the terminator about one-third the way up from the south limb. This 136 kilometer wide crater is approximately 4390 meters deep, and its west wall will cast a black shadow on the dark floor. Albategnius is a very ancient formation, which partially filled with lava at one point in its development. It is home to several wall craters like Klein (which will appear telescopically on its southwest wall). Albategnius holds more than just the distinction of being a prominent crater – it holds a place in history. On May 9, 1962 Louis Smullin and Giorgio Fiocco of the Massachusetts Institute of technology aimed a red laser toward the lunar surface and Albategnius became the first lunar object to be illuminated by a laser and then detected from Earth!

Ranger 9 ImageOn March 24, 1965 Ranger 9 took this “snapshot” of Albategnius (in the lower right of the lunar image) from an altitude of approximately 2500 kilometers. Companion craters in the image are Ptolemaeus and Alphonsus, which will be revealed for us tomorrow night. Ranger 9 was designed by NASA for one purpose – to achieve a lunar impact trajectory and send back high-resolution photographs and high-quality video images of the lunar surface. It carried no other scientific experiments, and its only destiny was to take pictures right up to the moment of final impact. It is interesting to note that Ranger 9 slammed into Alphonsus approximately 18.5 minutes after the lunar photo was taken. They called that…a “hard landing.”

As the week progresses, watch as the Moon draws closer for a near event with Jupiter by Wednesday. While the pair will still be separated by around two degrees it will still be an awesome sight that doesn’t require a telescope to enjoy!

Wishing you clear skies…

This week’s awesome images are Crater Piccolomini – Credit: Oliver Pettenpaul (LPOD), Beta Lyrae – Credit: Palomar Observatory, courtesy of Caltech, Beta Lyrae – Credit: Palomar Observatory, courtesy of Caltech, Crater Abulfeda – Credit: Wes Higgins, Ranger 9 Image of Lunar Surface and Image of Lunar Surface – Credit: NASA. We thank you!!

Observing Alert: Possible New Dwarf Nova In Andromeda

NvAnd08

[/caption]According to AAVSO Special Notice #122 prepared by M. Templeton, there’s a possible new WZ Sge-type dwarf nova located in Andromeda. The alert was posted yesterday and intial observations were sent in within the last 48 hours. For more information, read on…

AAVSO Special Notice #122

Multiple observers have confirmed the detection of an optical transient in Andromeda whose photometric behavior is thus far consistent with its classification as a WZ Sge-type dwarf nova system. The object was submitted to the CBAT unconfirmed objects list (D. Green, editor) by an unidentified observer on 2008 September 01.6.

A comprehensive list of the numerous follow-up observations made in Russia was published and an announcement of apparent very short period superhumps (P ~ 0.055 days) was made in vsnet-alert 10478. A comparison of the field with archival POSSII plates by D. Denisenko et al suggests the progenitor is very faint, with a blue magnitude of 21 or fainter. The reported outburst magnitudes of approximately V=12.5 then suggest an amplitude of at least 8 magnitudes.

M. Andreev (Terskol, Russia) obtained the following coordinates for the object using a 28-cm telescope:

RA: 02h 00m 25.42s , Dec: +44d 10m 18.4s (J2000)

Finder Chart
Finder Chart

Several other sets of coordinates have been published by Russian observers on the page noted above, and most are within a few tenths of an arcsecond.

Observations of this new object, including time-series photometry, are encouraged. The object has not been formally named, and the WZ Sge classification has not been definitively confirmed. Observers are asked to follow the object during the next several weeks. The object may fade and rebrighten, so please submit all observations including “fainter-than” estimates. Instrumental time-series observations are also encouraged to confirm the presence of superhumps and (if possible) define the period.

Please submit all data to the AAVSO using the name and/or AUID pair VSX J020025.4+441018 , AUID 000-BFT-799.

Nova Andromeda Photo courtesy of AstroAlert.

Weekend SkyWatcher’s Forecast – August 22-24, 2008

Bug Nebula

[/caption]Greetings, fellow SkyWatchers! Are you ready for a relatively Moon-less weekend? For telescope observers, we’ll travel south and capture the cosmic firefly – the “Bug Nebula”. If you have binoculars, take them out as we journey back 2000 years in time to look at the magnificent M25. For those who like a challenge? Try your luck at being a “Snake” charmer. Even if you just relax in a lawn chair and stare at the stars, you’re in luck because the Northern Iota Aquarid meteor shower is in town for a visit, too! Step out the back door, face south, and let’s journey into the night…

Friday, August 22, 2008 – With the Moon long gone from early evening skies, let’s have a look tonight at NGC 6302, a very curious planetary nebula located around three fingerwidths west of Lambda Scorpii: it is better known as the “Bug” nebula (RA 17 13 44 Dec -37 06 16).

With a rough visual magnitude of 9.5, the Bug belongs to the telescope – but it’s history as a very extreme planetary nebula belongs to us all. At its center is a 10th magnitude star, one of the hottest known. Appearing in the telescope as a small bowtie, or figure 8 shape, huge amounts of dust lie within it – very special dust. Early studies showed it to be composed of hydrocarbons, carbonates and iron. At one time, carbonates were believed associated with liquid water, and NGC 6302 is one of only two regions known to contain carbonates – perhaps in a crystalline form.

Ejected at a high speed in a bi-polar outflow, further research on the dust has shown the presence of calcite and dolomite, making scientists reconsider the kind of places where carbonates might form. The processes that formed the Bug may have begun 10,000 years ago – meaning it may now have stopped losing material. Hanging out about 4000 light-years from our own solar system, we’ll never see NGC 6302 as well as the Hubble Telescope presents its beauty, but that won’t stop you from enjoying one of the most fascinating of planetary nebulae!

Saturday, August 23, 2008 – Do you remember August 10, 1966 when Lunar Orbiter 1 was launched? Well, on this day in history it made headlines as it sent back the very first photo of Earth as seen from space! While the photographic quality is pretty poor by today’s standards, can you imagine the media stir it caused at the time? Never before had humankind witnessed our own planet. Just think of the advances we’ve in just 42 years!

M25
M25
Tonight let’s venture about three fingerwidths northeast of Lambda Sagittarii to visit a well-known but little-visited galactic cluster – M25 (RA 18 31 42 Dec -19 07 00). Discovered by de Chéseaux and then cataloged by Messier, it was also observed and recorded by William Herschel, Elert Bode, Admiral Smythe and T. W. Webb…but was never added to the catalog of John Herschel. Thanks to J.L.E. Dreyer, it did make the second Index Catalog as IC 4725. Seen with even the slightest optical aid, this 5th magnitude cluster contains two G-type giants and well as a Cepheid variable with the designation of U. This star varies by about one magnitude in a period of less than a week. M25 is a very old cluster, perhaps 90 million years old, and the light you see tonight left the cluster over 2000 years ago. While binoculars will see a double handful of bright stars overlaying fainter members, telescopes will reveal more and more as aperture increases. At one time it was believed to have only around 30 members, later thought to have 86… But recent studies by Archinal and Hynes indicate it may have as many as 601 member stars!

Sunday, August 24, 2008 – Today in 1966 from an Earth-orbiting platform, the Luna 11 mission launched on a three day trip. After successfully achieving orbit, the mission went on to study lunar composition and nearby meteoroid streams. Also on this date in 2006, 424 members of the International Astronomical Union shocked the world as they officially declared Pluto “to no longer be a planet.” Discovered in 1930, Pluto enjoyed its planetary status for 76 years before being retired. While text books will have to be re-written and the amateur science community will continue to recognize it as a solar system body, it is now considered to be a “dwarf planet.” At least temporarily…

So far in our southern expedition we’ve mined for globular gems, had our heads in the clouds and squashed a bug. What’s left? Let’s head over to the dark side as we take a look at the “Snake”…

Snake Nebula
Snake Nebula
Barnard Dark Nebula 72 is located about a fingerwidth north of Theta Ophiuchi (RA 17 23 02 Dec -23 33 48). While sometimes dark nebulae are hard to visualize because they are simply an absence of stars, patient observers will soon learn to “see in the dark.” The trained eye often realizes the presence of unresolved stars as a type of background “noise” that most of us simply take for granted – but not E. E. Barnard. He was sharp enough to realize there were at least 182 areas of the sky where these particular areas of nothingness existed, and he correctly assumed they were nebulae which were obscuring the stars behind them.

Unlike bright emission and reflection nebulae, these dark clouds are interstellar masses of dust and gas which remain unilluminated. We would probably not even know they were there except for the fact they eradicate star fields we know to be present! It is possible one day they may form stars of their own, but until that time we can enjoy these objects as splendid mysteries – and one of the most fascinating of all is the “Snake.” Put in a widefield eyepiece and relax… It will come to you. Barnard 72 is only a few light-years in expanse and a relatively short 650 light-years away. If at first you don’t see it, don’t worry. Like many kinds of objects, spotting dark nebulae takes some practice.

While you’re out, watch for the peak of the Northern Iota Aquarid meteor shower. Even though the official peak isn’t until tomorrow night, with no Moon to interfere and deep sky to enjoy, you might catch a bright streak! Wishing you clear skies and good luck…

This week’s awesome image are: NGC 6302: The Bug Nebula – Credit: Don Goldman, Lunar Orbiter’s first photo – Credit: NASA, M25 – Hillary Mathis, Vanessa Harvey, REU program/NOAO/AURA/NSF and B 72: The Snake Nebula – Credit: Tom McQuillan/Adam Block/NOAO/AURA/NSF. Thank you!!

Weekend SkyWatcher’s Forecast – August 8-10, 2008

Shevill Mathers

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Greetings, fellow SkyWatchers! Are you ready for another weekend? As the seasons slowly begin to change for both hemispheres and the Moon grows more full, look for an optical phenomena known as a “nimbus” – or halo around the Moon. While it’s nothing more than a thin layer of ice crystals in the upper troposphere, it is a wonderfully inspiring sight and was once used as a means of weather forecasting. If you see a nimbus, try counting the number of stars visible inside the halo and see if it matches the number of days before bad weather arrives! In the meantime, follow me as we head out on our next weekend journey into the night…

Hipparchus
Hipparchus
Friday, August 8, 2008 – Our first order of business for the weekend will be to pick up a Lunar Club challenge we haven’t noted so far this year – Hipparchus. Located just slightly south of the central point of the Moon and very near the terminator, this is not truly a crater – but a hexagonal mountain-walled plain. Spanning about 150 kilometers in diameter with walls around 3320 meters high, it is bordered just inside its northern wall by crater Horrocks. This deep appearing “well” is 30 kilometers in diameter, and its rugged interior drops down an additional 2980 meters below the floor. To the south and just outside the edge of the plain is crater Halley. Slightly larger at 36 kilometers in diameter, this crater named for Sir Edmund Halley is a little shallower at 2510 meters – but it has a very smooth floor. To the east you’ll see a series of three small craters – the largest of which is Hind.

On this date in 2001, the Genesis Solar Particle Sample Return mission was launched on its way toward the Sun. On September 8, 2004, it returned with its sample of solar wind particles – unfortunately a parachute failed to deploy, causing the sample capsule to plunge unchecked into the Utah soil. Although some of the specimens were contaminated, many did survive the mishap. So what is “star stuff?” Mostly highly charged particles generated from a star’s upper atmosphere flowing out in a state of matter known as plasma.

Despite tonight’s Moon, let’s study one of the grandest of all solar winds as we seek out an area about three fingerwidths above the Sagittarius teapot’s spout as we have a look at the magnificent M8.

Visible to the unaided eye as a hazy spot in the Milky Way, fantastic in binoculars, and an area truly worth study in any size scope, this 5200 light-year diameter area of emission, reflection, and dark nebulae has a rich history. Its involved star cluster – NGC 6530 – was discovered by Flamsteed around 1680, and the nebula by Le Gentil in 1747. Cataloged by Lacaille as III.14 about 12 years before Messier listed it as number 8, its brightest region was recorded by John Herschel, and dark nebulae were discovered within it by Barnard.

Tremendous areas of starbirth are taking place in this region, while young, hot stars excite the gas in a region known as the “Hourglass” around the stars Herschel 36 and 9 Sagittarii. Look closely around cluster NGC 6530 for Barnard Dark Nebulae B 89 and B 296 at the nebula’s southern edge…and try again on a darker night. No matter how long you choose to swim in the “Lagoon” you will surely find more and more things to delight both the mind and the eye!

Archimedes
Archimedes
Saturday, August 9, 2008 – Today in 1976, the Luna 24 mission was launched on a return mission of its own – not to retrieve solar wind samples, but lunar soil! When we begin our observations tonight, we’ll start by having a look at another great study crater – Archimedes. You’ll find it located in the Imbrium plain north of the Apennine Mountains and west of Autolycus.

Under this lighting, the bright ring of this class V walled plain extends 83 kilometers in diameter. Even though it looks to be quite shallow, it still has impressive 2150 meter high walls. To its south is a feature not often recognized – the Montes Archimedes. Though this relatively short range is heavily eroded, it still shows across 140 kilometers of lunar topography. Look for a shallow rima that extends southeast across Palus Putredinus toward the Apennines. Mark your challenge notes!

Now let’s go have a look at a star buried in one of the spiral arms of our own galaxy – W Sagittarii…

Located less than a fingerwidth north of the tip of the teapot spout (Gamma), W Sagittarii (RA 18 05 01 Dec -29 34 48) is a Cepheid variable that’s worth keeping an eye on. While its brightness only varies by less than a magnitude, it does so in less than eight days! Normally holding close to magnitude 4, nearby field stars will help you correctly assess when minimum and maximum occur. While it’s difficult for a beginner to see such changes, watch it over a period of time. At maximum, it will be only slightly fainter than Gamma to the south. At minimum, it will be only slightly brighter than the stars to its northeast and southwest.

While you watch W go through its changes – think on this. Not only is W a Cepheid variable (a standard for the cosmic distance scale), but it is also one that periodically changes its shape. Not enough? Then think twice… Because W is also a Cepheid binary. Still not enough? Then you might like to know that recent research points toward the W Sagittarii system having a third member as well!

Sunday, August 10, 2008 – Today in 1966 Lunar Orbiter 1 was successfully launched on its mission to survey the Moon. In the days ahead, we’ll take a look at what this mission sent back! Tonight keep a very close watch on Selene as Antares is less than a degree away. Check for an occultation event!

Walter
Walter
Our lunar mission for tonight is to move south, past the crater rings of Ptolemaeus, Alphonsus, Arzachel and Purbach, until we end up at the spectacular crater Walter. Named for Dutch astronomer Bernhard Walter, this 132 by 140 kilometer wide lunar feature offers up amazing details at high power. It is perhaps most fascinating to take the time to study the differing levels, which drop to a maximum of 4130 meters below the surface. Multiple interior strikes abound, but the most fascinating of all is the wall crater Nonius. Spanning 70 kilometers, Nonius would also appear to have a double strike of its own – one that’s 2990 meters deep!

Eta Sgr
Eta Sgr
Although it will be tough to locate with the unaided eye thanks to the Moon, let’s take a closer look at one of the most unsung stars in this region of sky – Eta Sagittarii (RA 18 17 37 Dec -36 45 42). This M-class giant star will display a wonderful color contrast in binoculars or scopes, showing up as slightly more orange than stars in the surrounding field. Located 149 light-years away, this irregular variable is a source of infrared radiation and is a little larger than our own Sun – yet is 585 times brighter. At around three billion years old, Eta has either expended its helium core or just began to use it to fuse carbon and oxygen – creating an unstable star capable of changing its luminosity by about 4%. But have a closer look…for Eta is also a binary system with an 8th magnitude companion.

Keep an eye out for the beginnings of the Perseid meteor shower and a futher report! Wishing you clear skies and a great weekend…

This week’s awesome images are: Nimbus – Credit: Shevill Mathers, Hipparchus: Credit: Tammy, M8 – Credit: NOAO/AURA/NSF, Archimedes – Credit: Wes Higgins, Walter – Credit: West Higgins and Eta Sagittarii – Credit: Palomar Observatory courtesy of Caltech. Thank you for sharing!

StarGazer’s Telescope: Jumpin’ Jupiter!

Greetings, Fellow Stratos Dwellers! Have you had more than your fair share of clouds lately and are hankering for a few photons? Skies haven’t been spectacular in this part of the world either and when it is clear, the heat is sure making it difficult to get a nice steady view. But, it’s a nice night out. Wanna’ take out the StarGazer’s telescope and have a look at Jupiter? I’ll see you in the back yard…

Yes. The skies are still hazy, but it’s a warm night. Isn’t it something to see Jupiter up there riding along on the Milky Way? Makes me think of that crazy song… “Now that’s she’s back in the atmosphere, with drops of Jupiter in her hair..” Ok! Ok! I know we have to keep it quiet or we’ll wake the neighbors. Careful walking around the edge of the pool while you’re looking up. I don’t want to have to fish you out! You’ll see the telescope set up right over there. Go ahead. The eyepiece is waiting on you.

What’s that? Oh, yeah. It is awesome! Did you know that it has two and a half times more mass than all of the other planets put together? In fact, if it had much more mass Jupiter would shrink. Don’t laugh! I’m not kidding. If Jupiter gained more weight it could have even conceivably been a star. Can you imagine that? Then we’d never have a dark night.

Hmmm? Yes. You’re right. There are very noticeable markings when it steadies down a bit. Those are the cloud zones. The white one in the center is the EZ. Now quit that laughing! It stands for equatorial zone. The dark one underneath the EZ is the north equatorial belt and the one on top of it is the south. Yes. There’s lots of other fine lines, too. Below the north equatorial belt is the tropical and temperate zones. Same goes for the south up above. Just a bunch of fast moving ammonia crystals with maybe a little ammonium hydrosulfide thrown in for good measure. As phosphorus, sulfur or maybe even hydrocarbons swirl up from below, the ultraviolet light from Sol gives ’em a little suntan.

Hey! You saw it? Good for you! Yep. Just a little right of center in the southern tropical zone. That’s why I called you out here tonight. The Great Red Spot isn’t all that red, is it? Just a strange, salmon colored oval that shows up every now and again when things steady off. Yes, it sure is a storm. An anticyclonic storm that we know started at least as early as 1831 and maybe even as early as 1665. Sometimes it rotates fast and sometimes it rotates slow, but it always rotates counterclockwise to Jupiter. No one really knows why it is the color it is, but we do know its cooler than the other cloudtops and big enough at times to swallow three planet Earths. Now, move over…

It’s my turn.

IBEX Mission Will View the Final Frontier of the Solar System

The heliopause is the frontier between the Solar System and the interstellar medium. Credit: NASA/JPL

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Space is far from empty. The Solar System can be viewed as a “bubble” of solar matter – filled with particles emitted by the Sun as the solar wind – extending well beyond the orbit of Pluto. The solar wind velocity is supersonic for most of this distance (exceeding a million miles per hour), but the point at which it begins to interact with the interstellar medium (ISM), the solar wind drops to subsonic velocities, creating a region of compression known as the termination shock. After 26 years of flight, the Voyager 1 deep space probe entered this bizarre, turbulent region of space, where solar particles build up and magnetic fields become twisted. Now a new mission has been designed to watch this region of space from afar to begin to understand the boundary of our solar system, where violent turbulence rules and high-energy atoms are generated…

In 2004, Voyager 1 hit it and in 2006, Voyager 2 hit it. The first probe flew through the termination shock at around 94 AU (8 billion miles away); the second measured it at only 76 AU (7 billion miles). This result alone suggests that the termination shock may be irregularly shaped and/or variable depending on solar activity. Before the Voyager missions, the termination shock was theorized, but there was little observational evidence until the two veteran probes traversed the region. The termination shock is of paramount importance to understanding the nature of the outer reaches of the solar system as, counter-intuitively, the Sun’s activity increases, the region beyond the termination shock (the heliosheath) becomes more efficient at blocking deadly cosmic rays. During solar minimum, it becomes less efficient at blocking cosmic rays.

Artist impression of Voyager 1, the first probe to traverse the heliosheath (NASA)
Artist impression of Voyager 1, the first probe to traverse the heliosheath (NASA)

In an effort to map the location and characteristics of the termination shock and heliosheath beyond, NASA scientists are preparing the Interstellar Boundary Explorer (IBEX) for launch in October. IBEX is part of NASA’s Small Explorer program (SMEX), where inexpensive, small probes are used to efficiently observe particular cosmic phenomena. IBEX will be orbiting beyond the influence of the Earth’s magnetic field (the magnetosphere) at a 200,000 mile distance from the Earth. This is because the phenomenon IBEX will be observing can be generated by our own magnetic field. So what will IBEX be measuring? To understand the interaction between solar wind ions and the interstellar medium, IBEX will use two sensors to detect energetic neutral atoms (ENAs) being blasted from the outermost reaches of the solar system.

How are ENAs generated and how are they a measurement of the interaction between the heliosphere and the ISM? Out there in the ISM exists neutral atoms and ions. As the solar system passes through interstellar space, the strong magnetic field generated around the heliosphere deflects the charged ions, pushing them out of the way. However, slow-moving neutral atoms are not affected by the magnetic field and penetrate deep into the heliosheath. When this happens, these neutral atoms from the ISM interact with energetic protons (which do have charge) rapidly spiralling along the magnetic field embedded in the solar wind. When this interaction occurs (known as charge exchange), an electron is stripped from the ISM atom and attracted to the energetic solar wind proton, thus making it neutral. When this exchange occurs, an energetic hydrogen atom (electron and proton) is ejected. An ENA is born.

Artist impression of IBEX (NASA)
Artist impression of IBEX (NASA)

Now, this is where the clever bit comes in. As mentioned before, neutral atoms do not “feel” magnetic fields, so when ENAs are created they are ejected in a straight line. Some of these atoms will be directed toward the Earth. IBEX will then measure these ENAs and work out where they came from. As they will have travelled directly to IBEX, the location of the termination shock may be deduced. Over a period of time, IBEX will be able to build up a picture of the locations of these atomic interactions and relate them the characteristics of the boundary of our Solar System.

But the best thing is, we won’t need to send a probe into deep space and wait for decades before it traverses the boundary layer, we will be able to make these measurements from Earth orbit. Such an exciting mission. Roll on the Pegasus rocket launch October 5th, 2008!

Source: Physorg.com

Astronomers Discover a Supernova/Gamma Ray Burst Hybrid

Spiral galaxy NGC 2770 with two supernovae SN 2007uy and SN 2008D. Credit: NASA

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Just when we thought we were beginning to understand what supernovae and gamma ray bursts were all about. Astronomers have just uncovered the true nature of what they thought was a regular supernova observed in January. At the time, it looked like a supernova emitting a 5-minute long burst of X-rays. But these X-rays were of a lower energy (known as “soft” X-rays) than expected leading some to believe this was a normal emission from a supernova explosion that was being observed during detonation (astronomers don’t usually get the chance to observe a star as it explodes and usually have to make do with analysing the supernova remnant). However, it is now believed this strange supernova event may have been emissions from a dying star at an intermediate mass, neither producing a supernova nor a gamma ray burst, but a combination of both…

Orbiting above Earth on January 9th 2008, the NASA/STFC/ASI Swift telescope caught a rare glimpse of what seemed to be a “normal” supernova at the precise moment of detonation. This observation was completely by luck, as Swift was already observing a supernova remnant (SN 2007uy) in spiral galaxy NGC 2770 that had exploded the previous year (90 million light-years away near the Lynx constellation). Then, as Swift was retrieving data from the SN 2007uy remnant, SN 2008D blasted a 5-minute long burst of X-rays in the same galaxy making this the first supernova to be directly observed.

However, looks can be deceiving. Researchers from a host of institutions including Italian National Institute for Astrophysics (INAF), the Max-Planck Institute for Astrophysics (MPA) and the European Southern Observatory (ESO) have analysed the supernova data thoroughly and at first agreed with the original assessment that it was indeed “normal.”

What made this event very interesting is that the X-ray signal was very weak and ‘soft’, very different from a gamma-ray burst and more in line with what is expected from a normal supernova.” – Paolo Mazzali, INAF’s Padova Observatory/MPA, research leader.

Dana Berry/SkyWorks Digital
Artist impression of the twin jets from a GRB. Credit: Dana Berry/SkyWorks Digital

However, astronomers at the Asiago Observatory in Northern Italy had designated the event as a Type 1c supernova, more commonly associated with long-period gamma-ray bursts. Type 1c supernovae are generated by hydrogen-poor progenitor stars with helium-rich outer layers prior to exploding at the end of their lives. But SN 2008D generated soft X-rays more associated with smaller stellar explosions. Therefore SN 2008D was probably produced by a star that was massive at birth (approximately 30 solar masses), rapidly using up its hydrogen fuel in its short life until it was only 8-10 solar masses. At this point it exploded, probably creating a remnant black hole. This chain of thought has led Paolo Mazzali and his team to think SN 2008D was produced by an object of a mass at the boundary of a normal supernova and gamma-ray burst.

Since the masses and energies involved are smaller than in every known gamma-ray burst related supernova, we think that the collapse of the star gave rise to a weak jet, and that the presence of the Helium layer made it even more difficult for the jet to remain collimated, so that when it emerged from the stellar surface the [X-ray] signal was weak.” – Massimo Della Valle, co-investigator.

Researcher and co-author Stefano Valenti points out that this discovery indicates that all black hole-producing supernovae have the potential to be gamma-ray burst progenitors. “The scenario we propose implies that gamma-ray burst-like inner engine activity exists in all supernovae that form a black hole,” he added.

Source: ESO

Polaris Brightness Variations are Revived, Astronomers Mystified

Polaris A (Pole Star) with its two stellar companions, Polaris Ab and Polaris B. Polaris itself is a Cepheid type variable star. Artists impression. Credit: NASA
Polaris A (Pole Star) with its two stellar companions, Polaris Ab and Polaris B. Polaris itself is a Cepheid type variable star. Artists impression. Credit: NASA

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Polaris is a well known Cepheid variable, but its periodic brightness variations have been steadily decreasing in amplitude for the last hundred years. Around the beginning of the 20th Century, Polaris’ brightness fluctuated every four days by 10%. Only ten years ago this variation had dropped to 2%, leading astronomers to believe this steady decline in the variability of the star was about to end. That was until recent observations uncovered an increase in variability to 4%. Polaris is an odd star in that it is a Cephid variable with a declining variability, and now astronomers are baffled as to why the brightness fluctuation has been revived…

Polaris (a.k.a. the North Star or Pole Star) has helped mankind navigate the globe since ancient times. Always positioned around the North Polar axis of the Earth, Polaris has also provided material for literature, poetry and religion. In astronomical terms it is also significant as it is a Cepheid variable with a regular variation in brightness, although it is the only Cepheid variable known that has been decreasing in brightness for the last several decades. But to complicate matters even further, this Type 1a supergiant (approximately 4-5 solar masses and 30 solar radii) appears to have been rejuvenated, and the vibrations have increased, varying in brightness by 4 %.

This discovery comes after observations made by Hans Bruntt from the University of Sydney and his international collaboration. Dr Alan Penny, co-investigator from the University of St. Andrews, UK, will present the team’s findings at his university’s “Cool Stars 15” conference this week.

In reality, the astronomers had focused their attention on Polaris in the hope to catch the point at which its variations ceased completely, only to find they had increased. “It was only through an innovative use of two small relatively unknown telescopes in space and a telescope in Arizona that we were able to discover and follow this star’s recovery so accurately,” Penny said. He was using the SMEI space camera, usually applied for solar-terrestrial observations of the solar wind, but he used it to accurately survey the night sky for Cepheid variables. At the same time, Bruntt was using a small telescope attached to NASA’s retired infra-red space telescope (WIRE) set up to study Polaris for a short period. When Penny noticed the strange recovery of Polaris in his SMIE data, it was compared with Bruntt’s WIRE data. It was therefore confirmed that Polaris’ vibrations had been revived.

H. Bruntt et al. 2008
Decrease over 100 years of amplitude of 4-day light variation of Polaris and of the increase since 2000. Credit: H. Bruntt et al. 2008

Backing up Penny and Bruntt, Professor Joel Eaton (Tennessee State University), who was using the AST automated spectroscopic telescope located in Arizona, noticed variations in the plasma velocity on the surface of Polaris. These measurements showed the brightness variations were correlated with expansion and contraction effects through the body of the star.

These observations are both exciting and perplexing. Although the variations observed in Cepheid variables are poorly understood, the vast majority of these “standard candles” do not change in brightness, let alone revive themselves. It would appear Polaris is undergoing a change that isn’t predicted by the standard model for stellar evolution, so the team of astronomers will be quick to follow up these observations with some theory as to what is causing the changes inside Polaris…

Sources: Physorg, arXiv

Observing Alert: Dwarf Nova VY Aquari Re-Brightens

VY Aquari (35" field)

[/caption]According to AAVSO Special Notice #114 prepared by Matthew Templeton and released just a few minutes ago, dwarf nova VY Aquari is now rebrightening and observers are asked to contribute their data. VY Aquari has been fairly quiet since its last superoutburst of 10.2 magnitude on June 30, 2008 and is on the rise again…

“Several observers have reported that the dwarf nova VY Aqr (RA 21 12 09.20 Dec 08 49 36.5) has rebrightened since fading from its initial superoutburst. Although VY Aqr has been classified as a WZ Sge-type dwarf nova, previous superoutburst rebrightenings have not been well-observed. Continued monitoring of VY Aqr for the next several weeks is strongly encouraged. Both visual and CCD time-series observations are needed, the former to track the overall light curve, and the latter to study superhumps and short-term variability. Both positive and fainter-than estimates are valuable, so please continue to monitor VY Aqr if and when it becomes faint again — it may undergo further rebrightenings during this outburst.”

AAVSO Locator Chart
AAVSO Locator Chart
According to Sky & Telescope, a dwarf nova is a type of cataclysmic variable, consisting of a close binary star system in which one of the components is a white dwarf, which accretes matter from its companion. They are similar to classical novae in that the white dwarf is involved in periodic outbursts, but the mechanisms are different: classical novae result from the fusion and detonation of accreted hydrogen, while current theory suggests that dwarf novae result from instability in the accretion disk, when gas in the disk reaches a critical temperature that causes a change in viscosity, resulting in a collapse onto the white dwarf that releases large amounts of gravitational potential energy.

Dwarf novae are distinct from classical novae in other ways; their luminosity is lower, and they are typically recurrent on a scale from days to decades. The luminosity of the outburst increases with the recurrence interval as well as the orbital period; recent research with the Hubble space telescope suggests that the latter relationship could make dwarf novae useful standard candles for measuring cosmic distances.

Thanks to recent studies by R. E. Mennickent (et al): “The tomograms reveal complex emission structures that can be identified with the accretion disc, the bright spot and, in the case of VY Aqr, the secondary star. For the first time, the white dwarf is detected unambiguously in the spectrum of VY Aqr.”

Why not check it out yourself? If you have a GoTo telescope, set it on the coordinates listed above and compare what you see with the wide angle chart (courtesy of AAVSO), then up the magnification and compare the field with the Palomar Sky Survey plate image during minima. We’d love to hear about your experience!

Large Chunk of ISS Space Junk Becomes Easy to Observe (Video)

The Easy Ammonia Servicer (EAS) photographed on July 23rd, 2007, by ISS astronauts. Watch your heads, it's re-entering tomorrow! (NASA)

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A huge piece of space debris, weighing 1400 lb (635 kg) and the size of two refrigerators, is gradually falling to Earth, giving observers on the ground a great opportunity to see it. The junk was jettisoned from the International Space Station (ISS) in 2007 and it is expected to re-enter the atmosphere later this year or early 2009. The Early Ammonia Servicer (EAS) was dropped from the ISS after a seven hour spacewalk and pushed in the opposite direction of the space station’s orbit shortly before a re-boost by a Soyuz resupply vehicle. This ensured the EAS would pose no danger to the ISS or crew on future orbits. Now the container is beginning its final few months in space and the bets are on as to where it will crash to Earth…

When the EAS, filled with ammonia coolant, had served its purpose the ISS crew had little choice but to throw it overboard. Astronaut Clay Anderson led the July 23rd 2007 operation with the assistance of cosmonauts Fyodor Yurchikhin and robotic arm operator Oleg Kotov as they shoved the EAS Earth-ward along with a 212 lb (96 kg) stanchion used to attach a camera to the station. The whole EVA lasted 7 hours and 41 minutes and the EAS was noted as the largest single piece of junk dropped from the ISS. At the time, mission control estimated that the EAS would orbit the Earth for 300 days; obviously this was a huge underestimate as it continues to spiral closer to the atmosphere one year after the mission.

Observing the EAS (Marco Langbroek)
Observing the EAS (Marco Langbroek)

The EAS is a huge piece of debris and easily tracked from the ground and poses no threat to missions, but it may be a hazard if, as expected, a large portion of the equipment survives re-entry. Dangers aside for now, the EAS is providing amateur astronomers with a new target to point their telescopes at. When the EAS was jettisoned, it was barely visible to the naked eye as it sped overhead with a magnitude of +4 to +4.5. Two days ago on July 20th, veteran satellite observer Marco Langbroek of Leiden, the Netherlands reported observing the EAS at an observable magnitude of +2.0. But it is moving very fast due to its decreased altitude.

Watch the EAS pass Altair in this high quality piece of video astronomy by Kevin Fetter (July 15th, 2008) »

Currently, the EAS can be seen over Europe, and next week North America will be able to spot it. For information on where and when to look for a chance to observe this huge lump of waste from the ISS, check out SpaceWeather.com’s Simple Satellite Tracker before it starts to flirt with our upper atmosphere in the next few months.

Sources: Space Weather, NASA, Collect Space.