Friday, 29 October 2010

HUBBLE DATA USED TO LOOK 10,000 YEARS INTO THE FUTURE


Astronomers are used to looking millions of years into the past. Now scientists have used the NASA/ESA Hubble Space Telescope to look thousands of years into the future. Looking at the heart of Omega Centauri, a globular cluster in the Milky Way, they have calculated how the stars there will move over the next 10,000 years.

The globular star cluster Omega Centauri has caught the attention of sky watchers ever since the ancient astronomer Ptolemy first catalogued it 2,000 years ago. Ptolemy, however, thought Omega Centauri was a single star. He didn't know that the "star" was actually a beehive swarm of nearly 10 million stars, all orbiting a common center of gravity.

The stars are so tightly crammed together that astronomers had to wait for the powerful vision of NASA's Hubble Space Telescope to peer deep into the core of the "beehive" and resolve individual stars. Hubble's vision is so sharp it can even measure the motion of many of these stars, and over a relatively short span of time.

A precise measurement of star motions in giant clusters can yield insights into how stellar groupings formed in the early universe, and whether an "intermediate mass" black hole, one roughly 10,000 times as massive as our Sun, might be lurking among the stars.

Analyzing archived images taken over a four-year period by Hubble's Advanced Camera for Surveys, astronomers have made the most accurate measurements yet of the motions of more than 100,000 cluster inhabitants, the largest survey to date to study the movement of stars in any cluster.

"It takes high-speed, sophisticated computer programs to measure the tiny shifts in the positions of the stars that occur in only four years' time," says astronomer Jay Anderson of the Space Telescope Science Institute in Baltimore, Md., who conducted the study with fellow Institute astronomer Roeland van der Marel. "Ultimately, though, it is Hubble's razor-sharp vision that is the key to our ability to measure stellar motions in this cluster."

Adds van der Marel: "With Hubble, you can wait three or four years and detect the motions of the stars more accurately than if you had waited 50 years on a ground-based telescope."

The astronomers used the Hubble images, which were taken in 2002 and 2006, to make a movie simulation of the frenzied motion of the cluster's stars. The movie shows the stars' projected migration over the next 10,000 years.

Identified as a globular star cluster in 1867, Omega Centauri is one of roughly 150 such clusters in our Milky Way Galaxy. The behemoth stellar grouping is the biggest and brightest globular cluster in the Milky Way, and one of the few that can be seen by the unaided eye. Located in the constellation Centaurus, Omega Centauri is viewable in the southern skies.

Images and more information about Omega Centauri:
 
* http://hubblesite.org/news/2010/28
* http://www.nasa.gov/hubble

The Release Was Received Jointly From The Space Telescope
Science Institute In Baltimore, Maryland, And The Hubble European
Space Agency Information Centre In Garching, Germany


NASA’S KEPLER SPACECRAFT TAKES PULSE OF DISTANT STARS


An international cadre of scientists that used data from NASA's Kepler spacecraft announced Tuesday the detection of stellar oscillations, or "starquakes," that yield new insights about the size, age and evolution of stars.

The results were presented at a news conference at Aarhus University in Denmark by scientists representing the Kepler Asteroseismic Science Consortium (KASC). The team studied thousands of stars observed by Kepler, releasing what amounts to a roster of some of humanity's most well-characterized stars.

Analysis of stellar oscillations is similar to how seismologists study earthquakes to probe the Earth's interior. This branch of science, called asteroseismology, produces measurements of stars the Kepler science team is anxious to have.

"Using the unparalleled data provided by Kepler, KASC scientists are quite literally revolutionizing our understanding of stars and their structures," said Douglas Hudgins, Kepler Program Scientist at NASA Headquarters in Washington. "What's more, they are doing so at no cost to the American taxpayer. All the KASC scientists are supported by research funding from their home countries. It is a perfect illustration of the tremendous value that our international partners bring to NASA missions."

In the results presented Tuesday, one oscillating star took center stage: KIC 11026764 has the most accurately known properties of any star in the Kepler field. In fact, few stars in the universe are known to similar accuracy. At an age of 5.94 billion years, it has grown to a little over twice the diameter of the Sun and will continue to do so as it transforms into a red giant. The oscillations reveal that this star is powered by hydrogen fusion in a thin shell around a helium-rich core.

"We are just about to enter a new area in stellar astrophysics," said Thomas Kallinger, lead author on a study of red giant stars and postdoctoral fellow at the Universities of British Columbia and Vienna. "Kepler provides us with data of such good quality that they will change our view of how stars work in detail."

KASC scientists also reported on the star RR Lyrae. It has been studied for more than 100 years as the first member of an important class of stars used to measure cosmological distances. The brightness, or light wave amplitude, of the star oscillates within a well-known period of about 13.5 hours. Yet during that period, other small cyclic changes in amplitude occur -- behavior known as the Blazhko effect.

The effect has puzzled astronomers for decades, but thanks to Kepler data, scientists may have a clue as to its origin. Kepler observations revealed an additional oscillation period that had never been previously detected. The oscillation occurs with a time scale twice as long as the 13.5-hour period. The Kepler data indicates the doubling is linked to the Blazhko effect.

"Kepler data ultimately will give us a better understanding of the future of our Sun and the evolution of our galaxy as a whole," said Daniel Huber, lead author on one of the KASC studies.

Launched in March 2009, Kepler was designed to discover Earth-size planets orbiting other stars. The spacecraft uses a huge digital camera, known as a photometer, to continuously monitor the brightness of more than 150,000 stars in its field of view as it orbits around the Sun. Kepler searches for distant worlds by looking for "transits," when a planet passes in front of a star, briefly causing it to dim. The amount of dimming reveals the size of the planet compared to the size of the star.

More information about the findings by the KASC scientists: http://astro.phys.au.dk/KASC/

More information about the Kepler mission: http://www.nasa.gov/kepler
http://www.nasa.gov/kepler


Thursday, 28 October 2010

Astronomers Discover Most Massive Neutron Star Yet Known

Pulses from neutron star (rear) are slowed as they pass near foreground white dwarf.
This effect allowed astronomers to measure masses of the system.

Source: The National Radio Astronomy Observatory

Astronomers using the National Science Foundation’s Green Bank Telescope (GBT) have discovered the most massive neutron star yet found, a discovery with strong and wide-ranging impacts across several fields of physics and astrophysics.

“This neutron star is twice as massive as our Sun. This is surprising, and that much mass means that several theoretical models for the internal composition of neutron stars now are ruled out,” said Paul Demorest, of the National Radio Astronomy Observatory (NRAO). “This mass measurement also has implications for our understanding of all matter at extremely high densities and many details of nuclear physics,” he added.

Neutron stars are the superdense “corpses” of massive stars that have exploded as supernovae. With all their mass packed into a sphere the size of a small city, their protons and electrons are crushed together into neutrons. A neutron star can be several times more dense than an atomic nucleus, and a thimbleful of neutron-star material would weigh more than 500 million tons. This tremendous density makes neutron stars an ideal natural “laboratory” for studying the most dense and exotic states of matter known to physics.

The scientists used an effect of Albert Einstein’s theory of General Relativity to measure the mass of the neutron star and its orbiting companion, a white dwarf star. The neutron star is a pulsar, emitting lighthouse-like beams of radio waves that sweep through space as it rotates. This pulsar, called PSR J1614-2230, spins 317 times per second, and the companion completes an orbit in just under nine days.
The pair, some 3,000 light-years distant, are in an orbit seen almost exactly edge-on from Earth. That orientation was the key to making the mass measurement.

As the orbit carries the white dwarf directly in front of the pulsar, the radio waves from the pulsar that reach Earth must travel very close to the white dwarf. This close passage causes them to be delayed in their arrival by the distortion of space-time produced by the white dwarf’s gravitation. This effect, called the Shapiro Delay, allowed the scientists to precisely measure the masses of both stars.

“We got very lucky with this system. The rapidly-rotating pulsar gives us a signal to follow throughout the orbit, and the orbit is almost perfectly edge-on. In addition, the white dwarf is particularly massive for a star of that type. This unique combination made the Shapiro Delay much stronger and thus easier to measure,” said Scott Ransom, also of NRAO.

The astronomers used a newly-built digital instrument called the Green Bank Ultimate Pulsar Processing Instrument (GUPPI), attached to the GBT, to follow the binary stars through one complete orbit earlier this year. Using GUPPI improved the astronomers’ ability to time signals from the pulsar severalfold.

The researchers expected the neutron star to have roughly one and a half times the mass of the Sun. Instead, their observations revealed it to be twice as massive as the Sun. That much mass, they say, changes their understanding of a neutron star’s composition. Some theoretical models postulated that, in addition to neutrons, such stars also would contain certain other exotic subatomic particles called hyperons or condensates of kaons.

“Our results rule out those ideas,” Ransom said.

Demorest and Ransom, along with Tim Pennucci of the University of Virginia, Mallory Roberts of Eureka Scientific, and Jason Hessels of the Netherlands Institute for Radio Astronomy and the University of Amsterdam, reported their results in the October 28 issue of the scientific journal Nature.

Their result has further implications, outlined in a companion paper, scheduled for publication in the Astrophysical Journal Letters. “This measurement tells us that if any quarks are present in a neutron star core, they cannot be ‘free,’ but rather must be strongly interacting with each other as they do in normal atomic nuclei,” said Feryal Ozel of the University of Arizona, lead author of the second paper.

There remain several viable hypotheses for the internal composition of neutron stars, but the new results put limits on those, as well as on the maximum possible density of cold matter.

The scientific impact of the new GBT observations also extends to other fields beyond characterizing matter at extreme densities. A leading explanation for the cause of one type of gamma-ray burst -- the “short-duration” bursts -- is that they are caused by colliding neutron stars. The fact that neutron stars can be as massive as PSR J1614-2230 makes this a viable mechanism for these gamma-ray bursts.

Such neutron-star collisions also are expected to produce gravitational waves that are the targets of a number of observatories operating in the United States and Europe. These waves, the scientists say, will carry additional valuable information about the composition of neutron stars.

“Pulsars in general give us a great opportunity to study exotic physics, and this system is a fantastic laboratory sitting out there, giving us valuable information with wide-ranging implications,” Ransom explained. “It is amazing to me that one simple number -- the mass of this neutron star -- can tell us so much about so many different aspects of physics and astronomy,” he added.

Monday, 25 October 2010

Stunning Spacecraft Photos Show Moon Eclipsing the Sun

Click on image to enlarge

On Oct. 7, 2010, NASA's Solar Dynamics Observatory, or SDO, observed its first lunar transit when the new moon passed directly between the spacecraft (in its geosynchronous orbit) and the sun. With SDO watching the sun in a wavelength of extreme ultraviolet light, the dark moon created a partial eclipse of the sun. Credit: NASA

NASA Readies Shuttle Discovery for Final Mission

by Staff WritersKSC FL (SPX) Oct 25, 2010

The countdown is on: NASA has only two shuttle launches left. The U.S. space agency is retiring its shuttle fleet next year and encouraging the development of commercial human spaceflight vehicles. Space shuttle Discovery is set to launch November 1
Last week, engineers found that Discovery had developed a fuel leak.
John Shannon, the space shuttle program manager at NASA's Johnson Space Flight Center in Houston, Texas, says engineers have the situation under control.
"We had a very small leak in the plumbing at a flange fitting, and the team has been working that very hard over the last week," Shannon told reporters Thursday.
"We did some troubleshooting on it, and it looked like the leak stopped."

Sunday, 24 October 2010

Group 1117, only one of the three big sunspots visible now

Visit Spaceweather.com for more information!

Runway opens at world's first spaceport

Virgin Galactic's VSS Enterprise made a celebratory flight over the runway

Commercial space travel took a step closer with the opening of the runway at the world's first spaceport in the US state of New Mexico.
The event was marked with a flypast of an aircraft carrying SpaceShip Two.
The vehicle has been designed to take fee-paying tourists on trips to the edge of space and back.
British billionaire Sir Richard Branson - whose Virgin group has backed the venture - said the first passenger trip should take place within 18 months.

Nikon Small World Competition

Image of Distinction, 2010

Dr. Marie Andersson
UCMR/Dep. Molecular Biology
Umeå Universitet
Umeå, Sweden
Drosophila sp. (fruit fly) eye, direct mount (20x)

University of Texas Students, Telescopes Help Discover Planets Around Elderly Binary Star

 The 2.1-meter (82-inch) Otto Struve Telescope at the University of Texas McDonald Observatory. Photo by Marty Harris/McDonald Observatory.


News Release: McDonald Observatory, The University of Texas, 21 October 2010
An international consortium of astronomers, including undergraduate and graduate
students at The University of Texas at Austin, have discovered a planetary system
consisting of at least two massive Jupiter-like planets orbiting the extremely close
binary star system NN Serpentis. The team used a wide variety of observations
taken over two decades from many telescopes, including two at The University of
Texas at Austin’s McDonald Observatory in West Texas.
|
The results are published
online in the current edition of the journal Astronomy & Astrophysics.
Because of the disturbing effects of a binary star system’s gravity, astronomers
normally do not expect to find planets in such systems, but the research team was
able to use the eclipses of the stars as a precise clock whose irregularities could be
used to detect planets in orbit around the binary.

Multi-University Project to Study 'Dark Energy' Receives $8 Million from National Science Foundation

Video to watch
 

















News Release: McDonald Observatory, The University of Texas, 20 October 2010

A project to discover the nature of dark energy, a mysterious force causing the expansion of the universe to speed up, has received an $8 million grant from the National Science Foundation (NSF).
The funds will be split among The University of Texas at Austin ($3.6 million), Texas A&M University ($3.9 million) and Penn State University ($.5 million), to support their respective roles in the Hobby-Eberly Telescope Dark Energy Experiment, or HETDEX. The project will be carried out at The University of Texas at Austin’s McDonald Observatory in west Texas.
“HETDEX is one of our gems within the university,” said William Powers Jr., president of The University of Texas at Austin. “It’s one of the projects being done here today that will still be talked about in a hundred years, the way we now read about discoveries by Newton and Einstein. This NSF grant is strong confirmation of the project’s importance and our commitment to it.”