What is CERN?

Here’s another great video from Sixty Symbols featuring professor Ed Copeland giving his entertaining description of CERN, the “Mecca for physicists” and home of the famous Large Hadron Collider. (Hopefully it will tide you over until the latest news is presented on July 4 regarding the ongoing hunt for the ever-elusive Higgs field!) Enjoy.

“On each of these experiments there are something like 3,000 physicists involved. So they’re not all here at the same time, of course… the cafeteria would be a nightmare if that was the case.”

– Prof. Ed Copeland

Brilliant.

Mars Has Watery Insides, Just Like Earth

Researchers from the Carnegie Institution have found that water is present in surprisingly Earthlike amounts within Mars’ mantle, based on studies of meteorites that originate from the Red Planet. The findings offer insight as to how Martian water may have once made its way to the planet’s surface, as well as what may lie within other terrestrial worlds.

Earth has water on its surface (obviously) and also within its crust and mantle. The water content of Earth’s upper mantle — the layer just below the crust —  is between 50 and 300 ppm (parts per million). This number corresponds to what the research team has identified within the mantle of Mars, based on studies of two chunks of rock — called shergottites — that were blasted off Mars during an impact event 2.5 million years ago.

“We analyzed two meteorites that had very different processing histories,” said Erik Hauri, the analysis team’s lead investigator from the Carnegie Institute . “One had undergone considerable mixing with other elements during its formation, while the other had not. We analyzed the water content of the mineral apatite and found there was little difference between the two even though the chemistry of trace elements was markedly different. The results suggest that water was incorporated during the formation of Mars and that the planet was able to store water in its interior during the planet’s differentiation.”

The water stored within Mars’ mantle may have made its way to the surface through volcanic activity, the researchers suggest, creating environments that were conducive to the development of life.

Like Earth, Mars may have gotten its water from elements available in the neighborhood of the inner Solar System during its development. Although Earth has retained its surface water while that on Mars got lost or frozen, both planets appear to have about the same relative amounts tucked away inside… and this could also be the case for other rocky worlds.

“Not only does this study explain how Mars got its water, it provides a mechanism for hydrogen storage in all the terrestrial planets at the time of their formation,” said former Carnegie postdoctoral scientist Francis McCubbin, who led the study.

The team’s research is published in the July edition of the journal Geology. Read more on the Carnegie Institution for Science’s site here.

Image: The remains of what appears to be a river delta within Eberswalde crater on Mars, imaged by ESA’s Mars Express. Credit: ESA/DLR/FU Berlin (G. Neukum).

The Challenge of Landing on Mars

The folks at NASA/JPL posted this amazing video to their YouTube channel today, highlighting the incredible engineering feat it will be to land the Curiosity Rover onto the surface of Mars. Because of Curiosity’s weight and size, the traditional “airbag” method isn’t going to cut it. Instead, Curiosity will be lowered gently to the surface of Mars via a rocket-propelled “skycrane”. It makes the landing even more complex and dangerous, and introduces a whole new level of risk into the landing. But once we get that SUV-sized rover crawling around the surface of Mars, all that risk will be totally worth it.

I’d also like to give NASA kudos in the production design of this feature. It really felt like I was watching a movie trailer, and not some dusty instructional video from a stodgy space agency. If NASA wants to inspire and educate, they hit the nail squarely on the head with this video. Okay, maybe it was a little over the top. I’m waiting to see a cameo from Batman, but still… nice work.

Astrophoto: Supernova PTF11kly During and After

It was literally an event of stellar proportions! In August 2011, a new Type Ia supernova was seen in spiral galaxy M101 a.k.a the Pinwheel Galaxy, located 25 million light-years away. Called PTF11kly, the bright supernova was a target for many astrophotographers. But what does it look like now? Here is a side-by-side comparison by Bill Schlosser from Ohio. It shows his image of the supernova on Sept. 26th, 2011 and then more recently, on June 9th, 2012. “The first was taken through my Astro Tech 10″ RC (I have since sold it) and the second through my TEC 140mm APO,” Bill wrote, and it clearly shows the supernova at its height (brightest object in the left picture, in the lower left side of the galaxy) to what it is today — a small blue blob in the right-hand image. Bill is wondering if it is possibly a becoming nebula now?

Great comparison shots! Check out Bill’s Flickr page for more great photos.

Want to get your astrophoto featured on Universe Today? Join our Flickr group or send us your images by email (this means you’re giving us permission to post them). Please explain what’s in the picture, when you took it, the equipment you used, etc.

Early “Elemental” Galaxy Found 12.4 Billion Light Years Away

This is definitely a story about a galaxy long ago and far away. An international team of researchers using the Atacama Large Millimeter/submillimeter Array (ALMA) has observed a “submillimeter galaxy” located about 12.4 billion light-years away. Their observations have revealed that the elemental composition of this galaxy in the early universe, at only 1.3 billion years after the Big Bang, was already close to the current elemental composition of the Universe. This means that intense star formation was taking place at that early point in the Universe’s history.

A submillimeter galaxy is a type of galaxy which has intense star formation activity and is covered by large amounts of dust. Since dust blocks observations in visible light, using ALMA’s millimeter wavelength capabilities can penetrate and see though dust clouds. In addition, ALMA also has extraordinary sensitivity, which is capable of catching even extremely faint radio signals. This is one of the most distant galaxies ALMA has ever observed.

The team was able to examine the chemical composition of the galaxy, called LESS J0332, and detected an emission line that contained nitrogen. To do this, they compared the brightness ratio of the observed emission lines from nitrogen and carbon with theoretical calculations. Their results showed that the elemental composition of LESS J0332, especially the abundance of nitrogen, is significantly different from that of the Universe immediately after the Big Bang – which consisted of almost only hydrogen and helium — but was much more similar to that of our Sun today, where a variety of elements exist abundantly.

It took 12.4 billion years for the emission lines from LESS J0332 to reach us, which means that the team was able to observe the galaxy located in the young universe at 1.3 billion years after the Big Bang.

“Submillimeter galaxies are thought to be relatively massive galaxies in the growth phase. Our research, revealing that LESS J0332 already has an elemental composition similar to the sun, shows us that the chemical evolution of these massive galaxies occurred rapidly made in the early universe, that is to say, in the early universe active star formation occurred for a short period of time,” said Tohru Nagao from Kyoto University, co-author of the paper.

The observations were made with ALMA, even though construction is not yet completed; only 18 antennas were used in this observation, while ALMA will be equipped with 66 antennas when completed.

This research was published in the “Letters” section of the journal, “Astronomy & Astrophysics.”

Lead image caption: Artist impression of the submillimeter galaxy LESS J0332 observed the ALMA at the 5000-meter altitude plateau. [Credit: NAOJ]

Source: ALMA

Weekly Space Hangout – June 21, 2012

In this edition of the Weekly Space Hangout, we welcome a new participant: Mike Wall, senior writer at Space.com. We were also joined by Alan Boyle from MSNBC’s Cosmic Log, Ian O’Neill from Discovery Space, and Amy Shira Teitel from Vintage Space.

This week we talked about using black holes as particle detectors, the recent launch of a female Chinese astronaut, the historical echoes of China and the Soviet Union launching women into space, and the newly announced asteroid telescope by the B612 Foundation.

We record the Weekly Space Hangout on Google+ every Thursday at 10 am Pacific / 1 pm Eastern. Circle Fraser on Google+, to see the show when it’s happening live.

NuSTAR Successfully Deploys Huge Mast

Nine days after launch — and right on schedule — the newest space mission has deployed its unique mast, giving it the ability to see the highest energy X-rays in our universe. The Nuclear Spectroscopic Telescope Array, or NuSTAR, successfully deployed its lengthy 10-meter (33-foot) mast on June 21, and mission scientists say they are one step closer to beginning its hunt for black holes hiding in our Milky Way and other galaxies.

“It’s a real pleasure to know that the mast, an accomplished feat of engineering, is now in its final position,” said Yunjin Kim, the NuSTAR project manager at the Jet Propulsion Laboratory. Kim was also the project manager for the Shuttle Radar Topography Mission, which flew a similar mast on the Space Shuttle Endeavor in 2000 and made topographic maps of Earth.

NuSTAR will search out the most elusive and most energetic black holes, to help in our understanding of the structure of the universe.

NuSTAR has many innovative technologies to allow the telescope to take the first-ever crisp images of high-energy X-ray, and the long mast separates the telescope mirrors from the detectors, providing the distance needed to focus the X-rays.

This is the first deployable mast ever used on a space telescope; the mast was folded up in a small canister during launch.

At 10:43 a.m. PDT (1:43 p.m. EDT) engineers at NuSTAR’s mission control at UC Berkeley in California sent a signal to the spacecraft to start extending the mast, a stable, rigid structure consisting of 56 cube-shaped units. Driven by a motor, the mast steadily inched out of a canister as each cube was assembled one by one. The process took about 26 minutes. Engineers and astronomers cheered seconds after they received word from the spacecraft that the mast was fully deployed and secure.

The NuSTAR team will now begin to verify the pointing and motion capabilities of the satellite, and fine-tune the alignment of the mast. In about five days, the team will instruct NuSTAR to take its “first light” pictures, which are used to calibrate the telescope.
Less than 20 days later, science operations are scheduled to begin.

“With its unprecedented spatial and spectral resolution to the previously poorly explored hard X-ray region of the electromagnetic spectrum, NuSTAR will open a new window on the universe and will provide complementary data to NASA’s larger missions, including Fermi, Chandra, Hubble and Spitzer,” said Paul Hertz, NASA’s Astrophysics Division Director.

NuSTAR launched on an Orbital Science Corporation’s Pegasus rocket, which was dropped from a carrier plane, the L-1011 “Stargazer,” also from Orbital.

Lead image caption: Artist’s concept of NuSTAR in orbit. NuSTAR has a 33-foot (10-meter) mast that deploys after launch to separate the optics modules (right) from the detectors in the focal plane (left). Image credit: NASA/JPL-Caltech

Source: JPL

Recent Earth-Passing Asteroid is Much Bigger Than Originally Estimated

An asteroid that recently passed by Earth is about twice as large as originally estimated, and it would have had serious global consequences if it had impacted Earth. Asteroid 2012 LZ1 was only discovered on June 10, 2012 by Rob McNaught at the Siding Spring Observatory in Australia. This Near Earth Object was thought to be fairly large, 502 meters (1,650 feet) wide, and quite bright. But astronomers using the planetary radar system at Arecibo Observatory were able to better determine the asteroid’s size, rotation rate and shape and found it to be about 1 kilometer (0.6 miles) wide and actually quite dark.

Scientists consider a kilometer-wide asteroid is at the size threshold that could set off an extinction-level event if it were to hit Earth.

“This object turned out to be quite a bit bigger than we expected, said Dr. Ellen Howell from Arecibo, “which shows how important radar observations can be, because we’re still learning a lot about the population of asteroids.”

2012 LZ1 sneaked by our planet at about 5.3 million km (3.35 million) miles away, or about 14 times the distance between Earth and the Moon on June 14, and it won’t be back in Earth’s vicinity again until June 12th, 2053, and then will be about 3 times as distant.
The Arecibo astronomers have determined it won’t be a threat to Earth for at least 750 years.

“The sensitivity of our radar has permitted us to measure this asteroid’s properties and determine that it will not impact the Earth at least in the next 750 years,” said Dr. Mike Nolan, Director of Planetary Radar Sciences at the Arecibo Observatory.

Several amateur astronomers were able to image 2012 LZ1, and the original thinking was that it was very bright. Instead, the new size determination suggests that 2012 LZ1 must be quite dark, reflecting only 2-4% of the light that hits it.

This is another reminder that we don’t know everything about all the potential asteroid threats that are out there, and more searches need to be done to find and track as many of the near Earth asteroid population as possible. Asteroid 2012 LZ1 has been classified as a Potentially Hazardous Asteroid, which are asteroids larger than approximately 100 meters that can come closer to our planet than 0.05 AU (7.4 million km, 4.65 million miles). As of now, none of the known PHAs is on a collision course with our planet, but both amateur and professional astronomers are finding new ones all the time, sometimes with just a few hours’ notice of a close approach.

Lead image caption: Asteroid 2012 LZ1 as seen by the Haleakala-Faulkes Telescope North on June 13, 2012. Credit: Nick Howes, Ernesto Guido & Giovanni Sostero.

Source: Arecibo Observatory via SpaceRef.

The “Deep Blue Sea” of the Sun

Looking like an intricate pen-and-ink illustration, the complex and beautiful structures of the Sun’s surface come to life in yet another stunning photo by Alan Freidman, captured from the historic Mount Wilson Observatory near Los Angeles, California.

Click below for the full-size image in all its hydrogen alpha glory.


An oft-demonstrated master of solar photography, Alan took the image above while preparing for the transit of Venus on June 5 — which he also skillfully captured on camera (see a video below).

Hydrogen is the most abundant element found on the sun. The sun’s “surface” and the layer just above it — the photosphere and chromosphere, respectively — are regions where atomic hydrogen exists profusely in upper-state form. It’s these absorption layers that hydrogen alpha imaging reveals in detail.

The images above are “negatives”… check out a “positive” version of the same image here.

” The seeing was superb… definitely the best of the visit and among the best solar conditions I’ve ever experienced,” Alan writes on his blog.

The video below was made by Alan on June 5, showing Venus transiting the Sun while both passed behind a tower visible from the Observatory.

Alan’s work is always a treat… see more of his astrophotography on his website AvertedImagination.com.

Image © Alan Friedman. All rights reserved.

A Gamma-Ray Burst as Music

This is awesome.

What would a gamma-ray burst sound like? No one really knows, but members of the team that work with the Fermi Large Area Telescope (LAT) have translated gamma-ray measurements into musical notes and have created a “song” from the photons from one of the most energetic of these powerful explosions, GRB 080916C which occurred in September of 2008.

“In translating the gamma-ray measurements into musical notes we assigned the photons to be “played” by different instruments (harp, cello, or piano) based on the probabilities that they came from the burst,” the team wrote in the Fermi blog. “By converting gamma rays into musical notes, we have a new way of representing the data and listening to the universe.”
Continue reading “A Gamma-Ray Burst as Music”