Sunday, March 27, 2016

ROSE GALAXY

ROSE GALAXY

ROSE GALAXY
ROSE GALAXY

Saturday, March 26, 2016

Close Comet and the Milky Way

Close Comet and the Milky Way: APOD: 2016 March 25 - Close Comet and the Milky Way



Discover the cosmos! Each day a different image or photograph of our fascinating universe is featured, along with a brief explanation written by a professional astronomer.


2016 March 25


See Explanation. Moving the cursor over the image will bring up an annotated version. Clicking on the image will bring up the highest resolution version available.



Close Comet and the Milky Way
Image Credit & Copyright: Alex Cherney (Terrastro, TWAN)
Explanation: Comet 252P/Linear's lovely greenish coma is easy to spot in this expansive southern skyscape. Visible to the naked eye from the dark site near Flinders, Victoria, Australia, the comet appears tailless. Still, its surprisingly bright coma spans about 1 degree, posed here below the nebulae, stars, and dark rifts of the Milky Way. The five panels used in the wide-field mosaic were captured after moonset and before morning twilight on March 21. That was less than 24 hours from the comet's closest approach, a mere 5.3 million kilometers from our fair planet. Sweeping quickly across the sky because it is so close to Earth, the comet should be spotted in the coming days by northern hemisphere comet watchers. In predawn but moonlit skies it will move through Sagittarius and Scorpius seen toward the southern horizon. That's near the triangle formed by bright, yellowish, Mars, Saturn, and Antares at the upper left of this frame.

Tomorrow's picture: equinox^3

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Authors & editors: Robert Nemiroff (MTU) & Jerry Bonnell (UMCP)
NASA Official: Phillip Newman Specific rights apply.
NASA Web Privacy Policy and Important Notices
A service of: ASD at NASA / GSFC
& Michigan Tech. U.


Friday, March 25, 2016

Best NASA Images Yet Of Ceres’ Brightest Spot

Best NASA Images Yet Of Ceres’ Brightest Spot:



Ceres Occator color tight_FEA


Ah, dome sweet dome. Scientists from NASA's Dawn mission unveiled new images from the spacecraft's lowest orbit at Ceres, including highly anticipated views of Occator Crater, at the 47th annual Lunar and Planetary Science Conference in The Woodlands, Texas, on Tuesday. The new images, taken from Dawn's low-altitude mapping orbit (LAMO) of 240 miles (385 kilometers) above Ceres, reveal a dome in a smooth-walled pit in the bright center of the crater. Linear fractures crisscross the top and flanks of the dome with still more fractures slicing across the nearby plains."Before Dawn began its intensive observations of Ceres last year, Occator Crater looked to be one large bright area. Now, with the latest close views, we can see complex features that provide new mysteries to investigate," said Ralf Jaumann, planetary scientist and Dawn co-investigator at the German Aerospace Center (DLR) in Berlin. "The intricate geometry of the crater interior suggests geologic activity in the recent past, but we will need to complete detailed geologic mapping of the crater in order to test hypotheses for its formation."Like me, you've probably been anticipating LAMO for months, when we'd finally get our clearest view of the famous "bright spots". Spectral observations have shown that the patches are consistent with a magnesium sulfate called hexahydrite that resembles the more familiar Epsom salts here on Earth. Scientists think these salt-rich areas were residue left behind when water-ice sublimated in the past. Impacts from asteroids could have broken into Ceres' crust and possibly unearthed salt-rich ices. Exposed to the vacuum of space, the ice would have sublimated (vaporized), leaving the salt behind.The team also released an enhanced color map of the surface of Ceres that reveals a diversity of surface materials and how they relate to Ceres' landforms. The dwarf planet doesn't have as many large impact basins as scientists expected, but the number of smaller craters generally matches their predictions. The blue material highlighted in the color map is related to flows, smooth plains and mountains, which appear to be very young surface features."Although impact processes dominate the surface geology on Ceres, we have identified specific color variations on the surface indicating material alterations that are due to a complex interaction of the impact process and the subsurface composition," Jaumann said. "Additionally, this gives evidence for a subsurface layer enriched in ice and volatiles."We're learning more about that subsurface ice thanks to Dawn's Gamma Ray and Neutron Detector (GRaND). Neutrons and gamma rays produced by cosmic rays interacting with the topmost yard (meter) of the loose rock and dust called regolith provide a fingerprint of Ceres' chemical makeup. Lower counts indicate the presence of hydrogen, and since water's rich in hydrogen (H2o), the results from GRanD suggest concentrations of water ice in the near-surface at high latitudes."Our analyses will test a longstanding prediction that water ice can survive just beneath Ceres' cold, high-latitude surface for billions of years," said Tom Prettyman, the lead for GRaND and Dawn co-investigator at the Planetary Science Institute, Tucson, Arizona.Dawn scientists also reported that the Visual and Infrared Mapping Spectrometer (VIR) has detected water at Oxo Crater, a young, 6-mile-wide (9-kilometer-wide) feature in Ceres' northern hemisphere. This water could either be bound up in minerals or exist as ice and may have been exposed during a landslide or impact or a combination of the two events.  Oxo is the only place on Ceres where water has been detected at the surface so far.Not only have scientists found evidence of possible extensive subsurface ice, but the composition of the surface is variable. Using VIR, which measures mineral composition by how those minerals reflect sunlight, they found that Haulani Crater shows a different proportion of surface materials than its surroundings. While the surface of Ceres is mostly made of a mixture of materials containing carbonates and phyllosilicates (clays), their relative proportion varies across the surface."False-color images of Haulani show that material excavated by an impact is different than the general surface composition of Ceres. The diversity of materials implies either that there is a mixed layer underneath, or that the impact itself changed the properties of the materials," said Maria Cristina de Sanctis, the VIR instrument lead scientist.All these cool stuff we're finding out about this small body makes it nearly as exciting as Pluto. Taking a closer look is the best form of education.

The post Best NASA Images Yet Of Ceres’ Brightest Spot appeared first on Universe Today.

Solar Storms Ignite Aurora On Jupiter

Solar Storms Ignite Aurora On Jupiter:



Composite images from the Chandra X-Ray Observatory and the Hubble Space Telescope show the hyper-energetic x-ray auroras at Jupiter. The image on the left is of the auroras when the coronal mass ejection reached Jupiter, the image on the right is when the auroras subsided. The auroras were triggered by a coronal mass ejection from the Sun that reached the planet in 2011. Image: X-ray: NASA/CXC/UCL/W.Dunn et al, Optical: NASA/STScI


The Earthly Northern Lights are beautiful and astounding, but when it comes to planetary light shows, what happened at Jupiter in 2011 might take the cake. In 2011, a coronal mass ejection (CME) struck Jupiter, producing x-ray auroras 8 times brighter than normal, and hundreds of times more energetic than Earth's auroras. A paper in the March 22nd, 2016 issue of the Journal of Geophysical Research gave the details.The Sun emits a ceaseless stream of energetic particles called the solar wind. Sometimes, the Sun ramps up its output, and what is called a coronal mass ejection occurs. A coronal mass ejection is a massive burst of matter and electromagnetic radiation. Though they're slow compared to other phenomena arising from the Sun, such as solar flares, CMEs are extremely powerful.When the CME in 2011 reached Jupiter, NASA's Chandra X-Ray Observatory was watching, the first time that Jupiter's X-ray auroras were monitored at the same time that a CME arrived. Along with some very interesting images of the event, the team behind the study learned other things. The CME that struck Jupiter actually compressed that planet's magnetosphere. It forced the boundary between the solar wind and Jupiter's magnetic field in towards the planet by more than 1.6 million kilometers (1 million miles.)The scientists behind this study used the data from this event to not only pinpoint the source of the x-rays, but also to identify areas for follow-up investigation. They'll be using not only Chandra, but also the European Space Agency's XMM Newton observatory to collect data on Jupiter's magnetic field, magnetosphere, and aurora.NASA's Juno spacecraft will reach Jupiter this summer. One of its primary missions is to map Jupiter's magnetic fields, and to study the magnetosphere and auroras. Juno's results will be fascinating to anyone interested in Jupiter's auroras.Here at Universe Today we've written about Jupiter's aurora's here, coronal mass ejections here, and the Juno mission here.

The post Solar Storms Ignite Aurora On Jupiter appeared first on Universe Today.

Most ‘Outrageous’ Luminous Galaxies Ever Observed

Most ‘Outrageous’ Luminous Galaxies Ever Observed:



An artist's conception of an extremely luminous infrared galaxy similar to the ones reported in this paper. Image credit: NASA/JPL-Caltech.


Astronomers might be running out of words when it comes to describing the brightness of objects in the Universe.Luminous, Super-Luminous, Ultra-Luminous, Hyper-Luminous. Those words have been used to describe the brightest objects we've found in the cosmos. But now astronomers at the University of Massachusetts Amherst have found galaxies so bright that new adjectives are needed. Kevin Harrington, student and lead author of the study describing these galaxies, says, "We’ve taken to calling them ‘outrageously luminous’ among ourselves, because there is no scientific term to apply.”The terms "ultra-luminous" and "hyper-luminous" have specific meanings in astronomy. An infrared galaxy is called “ultra-luminous” when it has a rating of about 1 trillion solar luminosities. At 10 trillion solar luminosities, the term "hyper-luminous" is used. For objects greater than that, at around 100 trillion solar luminosities, "we don't even have a name," says Harrington.The size and brightness of these 8 galaxies is astonishing, and their existence comes as a surprise. Professor Min Yun, who leads the team, says, "The galaxies we found were not predicted by theory to exist; they’re too big and too bright, so no one really looked for them before.” These newly discovered galaxies are thought to be about 10 billion years old, meaning they were formed about 4 billion years after the Big Bang. Their discovery will help astronomers understand the early Universe better.“Knowing that they really do exist and how much they have grown in the first 4 billion years since the Big Bang helps us estimate how much material was there for them to work with. Their existence teaches us about the process of collecting matter and of galaxy formation. They suggest that this process is more complex than many people thought,” said Yun.Gravitational lensing plays a role in all this though. The galaxies are not as large as they appear from Earth. As their light passes by massive objects on its way to Earth, their light is magnified. This makes them look 10 times brighter than they really are. But event taking gravitational lensing into account, these are still impressive objects.But it's not just the brightness of these objects that are significant. Gravitational lensing of a galaxy by another galaxy is rare. Finding 8 of them is unheard of, and could be "another potentially important discovery," says Yun. The paper highlights these galaxies as being among the most interesting objects for further study "because the magnifying property of lensing allows us to probe physical details of the intense star formation activities at sub-kpc scale..."The team's analysis also shows that the extreme brightness of these galaxies is caused solely by star formation.“The Milky Way produces a few solar masses of stars per year, and these objects look like they forming one star every hour,” Yun says. Harrington adds, “We still don’t know how many tens to hundreds of solar masses of gas can be converted into stars so efficiently in these objects, and studying these objects might help us to find out.”It took a tag team of telescopes to discover and confirm these outrageously luminous galaxies. The team of astronomers, led by Professor Min Yun, used the 50 meter diameter Large Millimeter Telescope for this work. It sits atop an extinct volcano in Mexico, the 15,000 foot Sierra Negra. They also relied on the Herschel Observatory, and the Planck Surveyor.

The post Most ‘Outrageous’ Luminous Galaxies Ever Observed appeared first on Universe Today.

The Moon’s Other Axis

The Moon’s Other Axis:



A six degree True Polar Wander occurred on the Moon due to ancient volcanic activity. Image: University of Arizona/James Tuttle Keane


It's tempting to think that the Moon never changes. You can spend your whole life looking at it, and see no evidence of change whatsoever. In fact, the ancients thought the whole Universe was unchanging.You may have heard of a man named Aristotle. He thought the Universe was eternal and unchanging. Obviously, with our knowledge of the Big Bang, stellar evolution, and planetary formation, we know better. Still, the placid and unchanging face of the Moon can tempt us into thinking astronomers are making up all this evolving universe stuff.But now, according to a new paper in Nature, the Moon's axis of rotation is different now than it was billions of years ago. Not only that, but volcanoes may been responsible for it. Volcanoes! On our placid little Moon.The clue to this lunar True Polar Wander (TPW) is in the water ice locked in the shadows of craters on the Moon. When hydrogen was discovered on the surface of the Moon in the 1990s by the Lunar Prospector probe, scientists suspected that they would eventually find water ice. Subsequent missions proved the presence of water ice, especially in craters near the polar regions. But the distribution of that water-ice wasn't uniform.You would expect to see ice uniformly distributed in the shadows of craters in the polar regions, but that's not what scientists have found. Instead, some craters had no evidence of ice at all, which led the team behind this paper to conclude that these ice-free craters must have been exposed to the Sun at some point. What else would explain it?The way that the ice in these craters is distributed forms two trails that lead away from each pole. They're mirror images of each other, but they don't conform with the Moon's current axis of rotation, which is what led the team to conclude that the Moon underwent a 6 degree TPW billions of years ago.The paper also highlights the age of the water on the Moon. Since the TPW, and the melting of some of the ice as a result of it, occurred some billions of years ago, then the water ice that is still frozen in the shadows of some of the Moon's craters must be ancient. According to the paper, its existence records the "early delivery of water to the inner Solar System." Hopefully, a future mission will return a sample of this ancient water for detailed study.But even more interesting than the age of the ice in the craters and the TPW, to me anyways, is what is purported to have caused it. The team behind the paper reports that volcanic activity on the Moon in the Procellarum region, which was most active in the early history of the Moon, moved a substantial amount of material and "altered the density structure of the Moon." This alteration would have changed the moments of inertia on the Moon, resulting in a TPW.It's strange to think of the Moon with volcanic activity viewable from Earth. I wonder what effect visible lunar volcanoes would have had on thinkers like Aristotle, if lunar volcanic activity had occurred during recorded history, rather than ending one billion years ago or so.We know that events like eclipses and comets caused great confusion and sometimes upheaval in ancient civilizations. Would lunar volcanoes have had the same effect?

The post The Moon’s Other Axis appeared first on Universe Today.

ExoMars Mission Narrowly Avoids Exploding Booster

ExoMars Mission Narrowly Avoids Exploding Booster:



The ExoMars craft releases the Schiaparelli lander in October in this artist's view. Credit: ESA


On March 14, the ExoMars mission successfully lifted off on a 7-month journey to the planet Mars but not without a little surprise. The Breeze-M upper booster stage, designed to give the craft its final kick toward Mars, exploded shortly after parting from the probe. Thankfully, it wasn't close enough to damage the spacecraft.Michel Denis, ExoMars flight director at the European Space Operations, Center in Darmstadt, Germany, said that the two craft were many kilometers apart at the time of the breakup, so the explosion wouldn't have posed a risk. Still, the mission team won't be 100% certain until all the science instruments are completely checked over in the coming weeks.All went well during the takeoff and final separation of the probe, but then something odd happened. Breeze-M was supposed to separate cleanly into two pieces — the main body and a detachable fuel tank — and maneuver itself to a graveyard or "junk" orbit, where rockets and spacecraft are placed at the end of their useful lives, so they don't cause trouble with operational satellites.But instead of two pieces, tracking photos taken at the OASI Observatory in Brazil not long after the stage and probe separated show  a cloud of debris, suggesting an explosion occurred that shattered the booster to pieces.It wouldn't be the first time a Russian Breeze-M blew up.According to Russian space observer Anatoly Zak in a recent article in Popular Mechanics, a Breeze-M that delivered a Russian spy satellite into orbit last December exploded on January 16. Propellant in one of its fuel tanks may not have been properly vented into space; heated by the sun, the tank's contents likely combusted and ripped the stage apart. A similar incident occurred in October 2012.For now, we'll embrace the good news that the spacecraft, which houses the Trace Gas Orbiter (TGO) and the Schiaparelli lander, are underway to Mars and in good health.ExoMars is a joint venture between the European Space Agency (ESA) and the Russian Federal Space Agency (Roscosmos). One of the mission’s key goals is to follow up on the methane detection made by ESA’s Mars Express probe in 2004 to understand where the gas comes from. Mars' atmosphere is 95% carbon dioxide with the remaining 5% divided among nitrogen, argon, oxygen and others including small amounts of methane, a gas that on Earth is produced largely by living creatures.Scientists want to know how martian methane got into the atmosphere. Was it produced by biology or geology? Methane, unless it is continuously produced by a source, only survives in the Martian atmosphere for a few hundreds of years because it quickly breaks down to form water and carbon dioxide. Something is refilling the atmosphere with methane but what?TGO will also look at potential sources of other trace gases such as volcanoes and map the planet's surface. It can also detect buried water-ice deposits, which, along with locations identified as sources of the trace gases, could influence the choice of landing sites of future missions.The orbiter will also act as a data relay for the second ExoMars mission — a rover and stationary surface science platform scheduled for launch in May 2018 and arriving in early 2019.On October 16, when the spacecraft is still 559,000 miles (900,000 kilometers) from the Red Planet, the Schiaparelli lander will separate from the orbiter and three days later parachute down to the Martian surface. The orbiter will take measurements of the planet's atmosphere (including methane) as well as any atmospheric electrical fields.Mars is a popular place. There are currently five active orbiters there: two European (Mars Express and Mars Odyssey), two American (Mars Reconnaissance Orbiter and MAVEN), one Indian (Mars Orbiter Mission) and two rovers (Opportunity and Curiosity) with another lander and orbiter en route!

The post ExoMars Mission Narrowly Avoids Exploding Booster appeared first on Universe Today.

A Picturesque Equinox Sunset

A Picturesque Equinox Sunset: APOD: 2016 March 20 - A Picturesque Equinox Sunset



Discover the cosmos! Each day a different image or photograph of our fascinating universe is featured, along with a brief explanation written by a professional astronomer.


2016 March 20


See Explanation. Clicking on the picture will download the highest resolution version available.



A Picturesque Equinox Sunset
Image Credit & Copyright: Roland Christen
Explanation: What's that at the end of the road? The Sun. Many towns have roads that run east - west, and on two days each year, the Sun rises and sets right down the middle. Today is one of those days: an equinox. Not only is today a day of equal night ("aequus"-"nox") and day time, but also a day when the sun rises precisely to the east and sets due west. Featured here is a picturesque road in northwest Illinois, USA that runs approximately east -west. The image was taken one year ago today, during the March Equinox of 2015, and shows the Sun down the road at sunset. In many cultures, this March equinox is taken to be the first day of a season, typically spring in Earth's northern hemisphere, and autumn in the south. Does your favorite street run east - west? Tonight at sunset, with a quick glance, you can actually find out.

Quiz (really hard): What road is pictured?
Tomorrow's picture: alaskan sundogs

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Authors & editors: Robert Nemiroff (MTU) & Jerry Bonnell (UMCP)
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Alaskan Moondogs

Alaskan Moondogs: APOD: 2016 March 21 - Alaskan Moondogs



Discover the cosmos! Each day a different image or photograph of our fascinating universe is featured, along with a brief explanation written by a professional astronomer.


2016 March 21


See Explanation. Clicking on the picture will download the highest resolution version available.



Alaskan Moondogs
Image Credit & Copyright: Sebastian Saarloos
Explanation: What's happened to the sky? Moonlight illuminates a snowy scene in this night land and skyscape made on 2013 January from Lower Miller Creek, Alaska, USA. Overexposed near the mountainous western horizon is the first quarter Moon itself, surrounded by an icy halo and flanked left and right by moondogs. Sometimes called mock moons, a more scientific name for the luminous apparitions is paraselenae (plural). Analogous to a sundog or parhelion, a paraselene is produced by moonlight refracted through thin, hexagonal, plate-shaped ice crystals. As determined by the crystal geometry, paraselenae are seen at an angle of 22 degrees or more from the Moon. Compared to the bright lunar disk, paraselenae are faint and easier to spot when the Moon is low.

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Tomorrow's picture: gravity's rainbows

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Authors & editors: Robert Nemiroff (MTU) & Jerry Bonnell (UMCP)
NASA Official: Phillip Newman Specific rights apply.
NASA Web Privacy Policy and Important Notices
A service of: ASD at NASA / GSFC
& Michigan Tech. U.


The Great Nebula in Carina

The Great Nebula in Carina: APOD: 2016 March 23 - The Great Nebula in Carina



Discover the cosmos! Each day a different image or photograph of our fascinating universe is featured, along with a brief explanation written by a professional astronomer.


2016 March 23


See Explanation. Clicking on the picture will download the highest resolution version available.



The Great Nebula in Carina
Image Credit & Copyright: Damian Peach/SEN
Explanation: In one of the brightest parts of Milky Way lies a nebula where some of the oddest things occur. NGC 3372, known as the Great Nebula in Carina, is home to massive stars and changing nebulas. The Keyhole Nebula (NGC 3324), the bright structure just above the image center, houses several of these massive stars and has itself changed its appearance. The entire Carina Nebula spans over 300 light years and lies about 7,500 light-years away in the constellation of Carina. Eta Carinae, the most energetic star in the nebula, was one of the brightest stars in the sky in the 1830s, but then faded dramatically. Eta Carinae is the brightest star near the image center, just left of the Keyhole Nebula. While Eta Carinae itself maybe on the verge of a supernova explosion, X-ray images indicate that much of the Great Carina Nebula has been a veritable supernova factory.

Tomorrow's picture: open space

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Authors & editors: Robert Nemiroff (MTU) & Jerry Bonnell (UMCP)
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NASA Web Privacy Policy and Important Notices
A service of: ASD at NASA / GSFC
& Michigan Tech. U.


Hickson 91 in Piscis Austrinus

Hickson 91 in Piscis Austrinus: APOD: 2016 March 24 - Hickson 91 in Piscis Austrinus



Discover the cosmos! Each day a different image or photograph of our fascinating universe is featured, along with a brief explanation written by a professional astronomer.


2016 March 24


See Explanation. Clicking on the picture will download the highest resolution version available.



Hickson 91 in Piscis Austrinus
Image Credit & Copyright: CHART32 Team, Processing - Johannes Schedler
Explanation: Scanning the skies for galaxies, Canadian astronomer Paul Hickson and colleagues identified some 100 compact groups of galaxies, now appropriately called Hickson Compact Groups (HCGs). This sharp telescopic image captures one such galaxy group, HCG 91, in beautiful detail. The group's three colorful spiral galaxies at the center of the field of view are locked in a gravitational tug of war, their interactions producing faint but visible tidal tails over 100,000 light-years long. Their close encounters trigger furious star formation. On a cosmic timescale the result will be a merger into a large single galaxy, a process now understood to be a normal part of the evolution of galaxies, including our own Milky Way. HCG 91 lies about 320 million light-years away in the constellation Piscis Austrinus. But the impressively deep image also catches evidence of fainter tidal tails and galaxy interactions close to 2 billion light-years distant.

Tomorrow's picture: close comet

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Authors & editors: Robert Nemiroff (MTU) & Jerry Bonnell (UMCP)
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NASA Web Privacy Policy and Important Notices
A service of: ASD at NASA / GSFC
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Thursday, March 24, 2016

UFO Attack Video | Real UFO Attack Caught On Camera Over Russia | UFO Si...





Breaking-UFO Attack Caught Over Syria | UFO Attack Video 2016 | UFO Sigh...





BEST UFO SIGHTINGS WORLDWIDE of 2015 Compilation Section 51





UFO, how it works? Lets go inside of alien spaceship!





UFO SIGHTINGS - Best UFO PICS EVER! REAL PHOTOS!





Tuesday, March 22, 2016

KGB Agent Record of Alien Races [Leaked]





Third Reich - Operation UFO (Nazi Base In Antarctica) HD - UFO Documentary





The NAZI UFO Conspiracy & Secret Technology [Full Documentary Films]





Real UFO Footage USA Fighter Jets vs UFO | OVNI (UFO) sobre Toledo Spai...





Sunday, March 20, 2016

18 Billion Solar Mass Black Hole Rotates At 1/3 Speed Of Light

18 Billion Solar Mass Black Hole Rotates At 1/3 Speed Of Light:



Black-hole-powered galaxies called blazars are the most common sources detected by NASA's Fermi Gamma-ray Space Telescope. As matter falls toward the supermassive black hole at the galaxy's center, some of it is accelerated outward at nearly the speed of light along jets pointed in opposite directions. When one of the jets happens to be aimed in the direction of Earth, as illustrated here, the galaxy appears especially bright and is classified as a blazar. Credits: M. Weiss/CfA


Way up in the constellation Cancer there's a 14th magnitude speck of light you can claim in a 10-inch or larger telescope. If you saw it, you might sniff at something so insignificant, yet it represents the final farewell of chewed up stars as their remains whirl down the throat of an 18 billion solar mass black hole, one of the most massive known in the universe.Astronomers know the object as OJ 287, a quasar that lies 3.5 billion light years from Earth. Quasars or quasi-stellar objects light up the centers of many remote galaxies. If we could pull up for a closer look, we'd see a brilliant, flattened accretion disk composed of heated star-stuff spinning about the central black hole at extreme speeds.As matter gets sucked down the hole, jets of hot plasma and energetic light shoot out perpendicular to the disk. And if we're so privileged that one of those jet happens to point directly at us, we call the quasar a "blazar". Variability of the light streaming from the heart of a blazar is so constant, the object practically flickers.A recent observational campaign involving more than two dozen optical telescopes and NASA's space based SWIFT X-ray telescope allowed a team of astronomers to measure very accurately the rotational rate the black hole powering OJ 287 at one third the maximum spin rate — about 56,000 miles per second (90,000 kps) —  allowed in General Relativity  A careful analysis of these observations show that OJ 287 has produced close-to-periodic optical outbursts at intervals of approximately 12 years dating back to around 1891. A close inspection of newer data sets reveals the presence of double-peaks in these outbursts.To explain the blazar's behavior, Prof. Mauri Valtonen of the University of Turku (Finland) and colleagues developed a model that beautifully explains the data if the quasar OJ 287 harbors not one buy two unequal mass black holes — an 18 billion mass one orbited by a smaller black hole.OJ 287 is visible due to the streaming of matter present in the accretion disk onto the largest black hole. The smaller black hole passes through the larger's the accretion disk during its orbit, causing the disk material to briefly heat up to very high temperatures. This heated material flows out from both sides of the accretion disk and radiates strongly for weeks, causing the double peak in brightness.The orbit of the smaller black hole also precesses similar to how Mercury's orbit precesses. This changes when and where the smaller black hole passes through the accretion disk.  After carefully observing eight outbursts of the black hole, the team was able to determine not only the black holes' masses but also the precession rate of the orbit. Based on Valtonen's model, the team predicted a flare in late November 2015, and it happened right on schedule.The timing of this bright outburst allowed Valtonen and his co-workers to directly measure the rotation rate of the more massive black hole to be nearly 1/3 the speed of light. I've checked around and as far as I can tell, this would make it the fastest spinning object we know of in the universe. Getting dizzy yet?

The post 18 Billion Solar Mass Black Hole Rotates At 1/3 Speed Of Light appeared first on Universe Today.

Kuiper Belt Objects Point The Way To Planet 9

Kuiper Belt Objects Point The Way To Planet 9:



Artist's impression of Planet Nine as an ice giant eclipsing the central Milky Way. Credit: ESO/Tomruen/nagualdesign


On January 20th, 2016, researchers Konstantin Batygin and Michael E. Brown of Caltech announced that they had found evidence that hinted at the existence of a massive planet at the edge of the Solar System. Based on mathematical modeling and computer simulations, they predicted that this planet would be a super-Earth, two to four times Earth's size and 10 times as massive. They also estimated that, given its distance and highly elliptical orbit, it would take 10,000 - 20,000 years to orbit the Sun.Since that time, many researchers have responded with their own studies about the possible existence of this mysterious "Planet 9". One of the latest comes from the University of Arizona, where a research team from the Lunar and Planetary Laboratory have indicated that the extreme eccentricity of distant Kuiper Belt Objects (KBOs) might indicate that they crossed paths with a massive planet in the past.For some time now, it has been understood that there are a few known KBOs who's dynamics are different than those of other belt objects. Whereas most are significantly controlled by the gravity of the gas giants planets in their current orbits (particularly Neptune), certain members of the scattered disk population of the Kuiper Belt have unusually closely-spaced orbits.When Batygin and Brown first announced their findings back in January, they indicated that these objects instead appeared to be highly clustered with respect to their perihelion positions and orbital planes. What's more, their calculation showed that the odds of this being a chance occurrence were extremely low (they calculated a probability of 0.007%).Instead, they theorized that it was a distant eccentric planet that was responsible for maintaining the orbits of these KBOs. In order to do this, the planet in question would have to be over ten times as massive as Earth, and have an orbit that lay roughly on the same plane (but with a perihelion oriented 180° away from those of the KBOs).Such a planet not only offered an explanation for the presence of high-perihelion Sedna-like objects - i.e. planetoids that have extremely eccentric orbits around the Sun. It would also help to explain where distant and highly inclined objects in the outer Solar System come from, since their origins have been unclear up until this point.In a paper titled "Coralling a distant planet with extreme resonant Kuiper belt objects", the University of Arizona research team - which included Professor Renu Malhotra, Dr. Kathryn Volk, and Xianyu Wang - looked at things from another angle. If in fact Planet 9 were crossing paths with certain high-eccentricity KBOs, they reasoned, it was a good bet that its orbit was in resonance with these objects.To break it down, small bodies are ejected  from the Solar System all the time due to encounters with larger objects that perturb their orbits. In order to avoid being ejected, smaller bodies need to be protected by orbital resonances. While the smaller and larger objects may pass within each others' orbital path, they are never close enough that they would able to exert a significant influence on each other.This is how Pluto has remained a part of the Solar System, despite having an eccentric orbit that periodically cross Neptune's path. Though Neptune and Pluto cross each others orbit, they are never close enough to each other that Neptune's influence would force Pluto out of our Solar System. Using this same reasoning, they hypothesized that the KBOs examined by Batygin and Brown might be in an orbital resonance with the Planet 9.As Dr.  Malhotra, Volk and Wang told Universe Today via email:

"The extreme Kuiper belt objects we investigate in our paper are distinct from the others because they all have very distant, very elliptical orbits, but their closest approach to the Sun isn’t really close enough for them to meaningfully interact with Neptune. So we have these six observed objects whose orbits are currently fairly unaffected by the known planets in our Solar System. But if there’s another, as yet unobserved planet located a few hundred AU from the Sun, these six objects would be affected by that planet."
After examining the orbital periods of these six KBOs - Sedna, 2010 GB174, 2004 VN112, 2012 VP113, and 2013 GP136 - they concluded that a hypothetical planet with an orbital period of about 17,117 years (or a semimajor axis of about 665 AU), would have the necessary period ratios with these four objects. This would fall within the parameters estimated by Batygin and Brown for the planet's orbital period (10,000 - 20,000 years).Their analysis also offered suggestions as to what kind of resonance the planet has with the KBOs in question. Whereas Sedna's orbital period would have a 3:2 resonance with the planet, 2010 GB174 would be in a 5:2 resonance, 2994 VN112 in a 3:1, 2004 VP113 in 4:1, and 2013 GP136 in 9:1. These sort of resonances are simply not likely without the presence of a larger planet.

"For a resonance to be dynamically meaningful in the outer Solar System, you need one of the objects to have enough mass to have a reasonably strong gravitational effect on the other," said the research team. "The extreme Kuiper belt objects aren’t really massive enough to be in resonances with each other, but the fact that their orbital periods fall along simple ratios might mean that they each are in resonance with a massive, unseen object."

But what is perhaps most exciting is that their findings could help to narrow the range of Planet 9's possible location. Since each orbital resonance provides a geometric relationship between the bodies involved, the resonant configurations of these KBOs can help point astronomers to the right spot in our Solar System to find it.

But of course, Malhotra and her colleagues freely admit that several unknowns remain, and further observation and study is necessary before Planet 9 can be confirmed:

"There are a lot of uncertainties here. The orbits of these extreme Kuiper belt objects are not very well known because they move very slowly on the sky and we’ve only observed very small portions of their orbital motion. So their orbital periods might differ from the current estimates, which could make some of them not resonant with the hypothetical planet. It could also just be chance that the orbital periods of the objects are related; we haven’t observed very many of these types of objects, so we have a limited set of data to work with."
Ultimately, astronomers and the rest of us will simply have to wait on further observations and calculations. But in the meantime, I think we can all agree that the possibility of a 9th Planet is certainly an intriguing one! For those who grew up thinking that the Solar System had nine planets, these past few years (where Pluto was demoted and that number fell to eight) have been hard to swallow.But with the possible confirmation of this Super-Earth at the outer edge of the Solar System, that number could be pushed back up to nine soon enough!Further Reading: arXiv.org

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Cassini Watches Star Through Enceladus’ Plume

Cassini Watches Star Through Enceladus’ Plume:

When the Cassini probe first saw the plumes coming from Saturn’s moon Enceladus, it was a surprise. When it dipped through the plumes, some questions about the basic nature of the phenomenon were answered. But there are still many more questions, and today Cassini has an opportunity to find some answers.

Cassini will be in a perfect position today to observe the light from Epsilon Orionis, the central star in Orion’s belt, as it passes through Enceladus’ plume. This type of observation is known as a stellar occultation, and it promises to provide new information about the composition and density of the plume. Cassini’s Ultraviolet Imaging Spectrograph (UVIS) will do the capturing, and once the information is relayed back to Earth, it will be analyzed for clues.

An artist's impression of the plumes coming from Enceladus. Image: NASA/JPL.
An artist’s impression of the plumes coming from Enceladus. Image: NASA/JPL.
We already know a few things about Enceladus’ plumes. First of all, Enceladus itself is any icy world, with subsurface oceans. The moon is locked in an orbital resonance, which creates its eccentric orbit. This eccentric orbit is responsible for heating the south polar oceans, which drives material through the ice sheets and creates its stunning plumes, in a process known as cryovolcanism. (Radioactive decay might also have something to do with heating.)

Cassini has been at Saturn’s system for 12 years, and has gradually painted a more detailed picture of Enceladus. Over time, we’ve learned that the plumes themselves are similar to what comets are made of. Cassini initially detected mostly water vapor, with traces of molecular nitrogen, methane, and carbon dioxide. Later, the presence of the hydrocarbons propane, formaldehyde, and acetylene was confirmed.

This is all very interesting, but why would anyone other than chemistry geeks care? Because the universe, including our Solar System, is largely a cold, sterile place. And the plumes coming from Enceladus indicate the presence of water, potentially warm, salty, water at that. And warm water might mean life, or the potential for life.

Cassini has previously observed two other stellar occultations. But with today’s observation, we stand to learn even more about the plumes of Enceladus. We’ll not only learn more about their density and composition, but since is the third such occultation to be observed, we’ll learn something about the plume’s behaviour over time. We probably won’t learn anything definitive about Enceladus’ life-supporting potential, but we will almost certainly find another piece of the puzzle, and fill in a blank spot in our knowledge.

And that’s what science is all about.

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