Mapping the Hidden Dark Matter

Image credit: Berkeley

Dark matter is an invisible halo of material that seems to surround every galaxy. Astronomers can’t see it, but they know it’s there by the effect of its gravity; there seems to be 10 times as much dark matter as regular matter. Until now, astronomers believed that dark matter probably formed an even mist of particles in space, but researchers from UC Berkeley and MIT have created a computer simulation of how dark matter might clump together into larger chunks of material.

The “dark matter” that comprises a still-undetected one-quarter of the universe is not a uniform cosmic fog, says a University of California, Berkeley, astrophysicist, but instead forms dense clumps that move about like dust motes dancing in a shaft of light.

In a paper submitted this week to Physical Review D, Chung-Pei Ma, an associate professor of astronomy at UC Berkeley, and Edmund Bertschinger of the Massachusetts Institute of Technology (MIT), prove that the motion of dark matter clumps can be modeled in a way similar to the Brownian motion of air-borne dust or pollen.

Their findings should provide astrophysicists with a new way to calculate the evolution of this ghost universe of dark matter and reconcile it with the observable universe, Ma said.

Dark matter has been a nagging problem for astronomy for more than 30 years. Stars within galaxies and galaxies within clusters move in a way that indicates there is more matter there than we can see. This unseen matter seems to be in a spherical halo that extends probably 10 times farther than the visible stellar halo around galaxies. Early proposals that the invisible matter is comprised of burnt-out stars or heavy neutrinos have not panned out, and the current favorite candidates are exotic particles variously called neutrilinos, axions or other hypothetical supersymmetric particles. Because these exotic particles interact with ordinary matter through gravity only, not via electromagnetic waves, they emit no light.

“We’re only seeing half of all particles,” Ma said. “They’re too heavy to produce now in accelerators, so half of the world we don’t know about.”

The picture only got worse four years ago when “dark energy” was found to be even more prevalent than dark matter. The cosmic account now pegs dark energy at about 69 percent of the universe, exotic dark matter at 27 percent, mundane dark matter – dim, unseen stars – at 3 percent, and what we actually see at a mere 1 percent.

Based on computer models of how dark matter would move under the force of gravity, Ma said that dark matter is not a uniform mist enveloping clusters of galaxies. Instead, dark matter forms smaller clumps that look superficially like the galaxies and globular clusters we see in our luminous universe. The dark matter has a dynamic life independent of luminous matter, she said.

“The cosmic microwave background shows the early effects of dark matter clumping, and these clumps grow under gravitational attraction,” she said. “But each of these clumps, the halo around galaxy clusters, was thought to be smooth. People were intrigued to find that high-resolution simulations show they are not smooth, but instead have intricate substructures. The dark world has a dynamic life of its own.”

Ma, Bertschinger and UC Berkeley graduate student Michael Boylan-Kolchin performed some of these simulations themselves. Several other groups over the past two years have also showed similar clumping.

The ghost universe of dark matter is a template for the visible universe, she said. Dark matter is 25 times more abundant than mere visible matter, so visible matter should cluster wherever dark matter clusters.

Therein lies the problem, Ma said. Computer simulations of the evolution of dark matter predict far more clumps of dark matter in a region than there are clumps of luminous matter we can see. If luminous matter follows dark matter, there should be nearly equivalent numbers of each.

“Our galaxy, the Milky Way, has about a dozen satellites, but in simulations we see thousands of satellites of dark matter,” she said. “Dark matter in the Milky Way is a dynamic, lively environment in which thousands of smaller satellites of dark matter clumps are swarming around a big parent dark matter halo, constantly interacting and disturbing each other.”

In addition, astrophysicists modeling the motion of dark matter were puzzled to see that each clump had a density that peaked in the center and fell off toward the edges in the exact same way, independent of its size. This universal density profile, however, appears to be in conflict with observations of some dwarf galaxies made by Ma’s colleague, UC Berkeley professor of astronomy Leo Blitz, and his research group, among others.

Ma hopes that a new way of looking at the motion of dark matter will resolve these problems and square theory with observation. In her Physical Review article, discussed at a meeting earlier this year of the American Physical Society, she proved that the motion of dark matter can be modeled much like the Brownian motion that botanist Robert Brown described in 1828 and Albert Einstein explained in a seminal 1905 paper that helped garner him the 1921 Nobel Prize in Physics.

Brownian motion was first described as the zigzag path traveled by a grain of pollen floating in water, pushed about by water molecules colliding with it. The phenomenon refers equally to the motion of dust in air and dense clumps of dark matter in the dark matter universe, said Ma.

This insight “let’s us use a different language, a different point of view than the standard view,” to investigate the movement and evolution of dark matter, she said.

Other astronomers, such as UC Berkeley emeritus professor of astronomy Ivan King, have used the theory of Brownian motion to model the movement of hundreds of thousands of stars within star clusters, but this, Ma said, “is the first time it has been applied rigorously to large cosmological scales. The idea is that we don’t care exactly where the clumps are, but rather, how clumps behave statistically in the system, how they scatter gravitationally.”

Ma noted that the Brownian motion of clumps is governed by an equation, the Fokker-Planck equation, that is used to model many stochastic or random processes, including the stock market. Ma and collaborators are currently working on solving this equation for cosmological dark matter.

“It is surprising and delightful that the evolution of dark matter, the evolution of clumps, obeys a simple, 90-year-old equation,” she said.

The work was supported by the National Aeronautics and Space Administration.

Original Source: UC Berkeley

Voyager is Nearing the Edge of the Solar System

Image credit: NASA

NASA’s Voyager 1 spacecraft has nearly reached the outer limits of the solar system to a region of space, called the heliosheath, where the solar wind blows against interstellar gas. In order to pass into this area; however, Voyager will first pass through a turbulent region called the termination shock. This is the first time scientists have ever gathered data about these distant areas of the solar system. Launched on September 5, 1977, Voyager 1 is now 13 billion km away from the Sun.

NASA’s Voyager 1 spacecraft is about to make history again as the first spacecraft to enter the solar system’s final frontier, a vast expanse where wind from the Sun blows hot against thin gas between the stars: interstellar space. However, before it reaches this region, Voyager 1 must pass through the termination shock, a violent zone that is the source of beams of high-energy particles.

Voyager’s journey through this turbulent zone will give scientists their first direct measurements of our solar system’s unexplored final frontier, called the heliosheath, and scientists are debating if this passage has already begun. Two papers about this research are being published in Nature on November 5, 2003. The first paper, by Dr. Stamatios M. Krimigis of the Johns Hopkins University Applied Physics Laboratory, Laurel, Md., and his team, gives evidence supporting the claim that Voyager 1 passed beyond the termination shock. The second paper, by Dr. Frank B. McDonald of the University of Maryland, College Park, and his team, gives evidence against this claim. A third paper, published October 30, 2003 in Geophysical Research Letters by Dr. Leonard F. Burlaga of NASA’s Goddard Space Flight Center, Greenbelt, Md., and collaborators, gives evidence that Voyager 1 did not pass beyond the termination shock. (Refer to Image 2a for an illustration of the termination shock and heliosheath).

“The Voyager 1 observations show we have entered into a new part of the solar system. Regardless of whether we crossed the termination shock or not, the teams are excited because this has never been seen before – the observations are different here than in the inner solar system,” said Dr. Eric Christian, Discipline Scientist for the Sun Earth Connection research program at NASA Headquarters, Washington, DC.

“Voyager 1 has seen striking signs of the region deep in space where a giant shock wave forms as the wind from the Sun abruptly slows and presses outward against the interstellar wind. The observations surprised and puzzled us, so there is much to be discovered as Voyager begins exploring this new region at the outer edge of the solar system,” said Dr. Edward Stone, Voyager Project Scientist, California Institute of Technology, Pasadena, Calif.

At more than eight billion miles (13 billion km) from the Sun, Voyager 1 is the most distant object built by humanity. Launched on September 5, 1977, it explored the giant planets Jupiter and Saturn before being tossed out toward deep space by Saturn’s gravity. It now approaches, and may have temporarily entered, the region beyond termination shock.

The termination shock is where the solar wind, a thin stream of electrically charged gas blown constantly from the Sun, is slowed by pressure from gas between the stars. At the termination shock, the solar wind slows abruptly from its average speed of 300 – 700 km per second (700,000 – 1,500,000 mph). (Refer to Movie 4 to see how this heats the solar wind in the heliosheath).

The exact location of the termination shock is unknown, and it originally was thought to be closer to the Sun than Voyager 1 currently is. As Voyager 1 cruised ever farther from the Sun, it confirmed that all the planets were inside an immense bubble blown by the solar wind, and the termination shock was much more distant (Animation 1).

Estimating the location of the termination shock is hard because we don’t know the precise conditions in interstellar space, and even what we do know, the speed and pressure of the solar wind, changes which causes the termination shock to expand, contract, and ripple. You can see a similar effect every time you wash dishes (Movie 3). If you place a plate underneath a stream of water, you notice the water spreads out over the plate in a relatively smooth flow. The water flow has a rough edge where the water slows down abruptly and piles up. The edge is like the termination shock, and as the water flow changes, the shape and size of the rough edge change.

From about August 1, 2002 to February 5, 2003, scientists noticed unusual readings from the two energetic particle instruments on Voyager 1, indicating it had entered a region of the solar system unlike any encountered before. This led some to claim that Voyager may have entered a transitory feature of the termination shock. Just as small bumps and “fingers” appear and disappear in the rough edge of the water flow over a plate, Voyager might have entered a temporary “finger” in the edge of the termination shock.

The controversy would be resolved easily if Voyager could still measure the speed of the solar wind, because the solar wind slows abruptly at the termination shock. However, the instrument that measures solar wind speed no longer functions on the venerable spacecraft, so scientists must use data from the instruments that are still working to infer if Voyager pierced the termination shock.

Evidence for crossing the shock includes Voyager’s observation that high-velocity electrically-charged particles (electrons and ions) increased more than 100 times during the August 1, 2002 to February 5, 2003 period. This would be expected if Voyager passed the termination shock, because the shock naturally accelerates electrically charged particles that bounce back and forth like ping pong balls between the fast and slow winds on the opposite sides of the shock.

Secondly, the particles were flowing outward, past Voyager and away from the Sun. This would be expected if Voyager already crossed beyond the termination shock, because the acceleration region in the termination shock would now be behind the spacecraft. Third, an indirect measure of the solar wind speed indicated the solar wind was slow during this period, as would be expected if Voyager was beyond the shock.

“We have used an indirect technique to show that the solar wind slowed down from about 700,000 mph to much less than 100,000 mph. This same technique was used by us before, when the instrument measuring the solar wind speed was still working, and the agreement between the two measurements was better than 20% in most cases,” said Krimigis.

Evidence against entry into the shock includes the observation that while there was a dramatic increase in low-speed particles, they weren’t seen at the somewhat higher speeds scientists believe the termination shock generates.

However, the strongest evidence against entry is Voyager’s observation that the magnetic field did not increase during this period. According to theoretical models, this must happen whenever the solar wind slows down. Imagine a highway with moderate traffic. If something makes the drivers slow down, say a puddle of water, the cars pile up – their density increases. In the same way, the density (intensity) of the magnetic field carried by the solar wind will increase if the solar wind slows down.

“The analysis of the Voyager 1 magnetic field observations in late 2002 indicate that it did not enter a new region of the distant heliosphere by having crossed the termination shock. Rather, the magnetic field data had the characteristics to be expected based upon many years of previous observations, although the intensity of energetic particles observed is unusually high,” said Burlaga.

The teams agree that Voyager 1 has seen a new phenomenon: a six-month period when low-energy particles were very abundant and flowing away from the Sun. When the unusual period ended, both agree that Voyager 1 was back in the solar wind, so if this was a temporary passage beyond the termination shock, the shock will be seen again, probably in the next couple years. Finally, the observations indicate that the termination shock is a lot more complicated than anyone thought.

For their original missions to Jupiter and Saturn, Voyager 1 and sister spacecraft Voyager 2 were destined to regions of space where solar panels would not be feasible, so each was equipped with three radioisotope thermoelectric generators to produce electrical power for the spacecraft systems and instruments. Still operating in remote, cold and dark conditions 26 years later, the Voyagers owe their longevity to these Department of Energy-provided generators, which produce electricity from the heat generated by the natural decay of plutonium dioxide.

The Voyagers were built by NASA’s Jet Propulsion Laboratory (JPL) in Pasadena, Calif., which continues to operate both spacecraft 26 years after their launch. The spacecraft are controlled and their data returned through NASA’s Deep Space Network (DSN), a global spacecraft tracking system also operated by JPL. The Voyager Project Manager is Ed Massey of JPL. The Voyager Project Scientist is Dr. Edward Stone of the California Institute of Technology.

Original Source: NASA News Release

Leonid Meteors on November 17

Image credit: NASA

The Leonid meteor shower will be making an appearance on November 17, 2003, and it might be an impressive show. These meteors are the minute dust trails of Comet 55P/Tempel-Tuttle which flash in the sky as they strike the Earth’s atmosphere. In past years, the Leonids have been very impressive, sometimes thousands of meteors have been seen. Astronomers aren’t sure how many will strike the Earth this year – it could be anywhere from a couple an hour to several hundred per hour. The best views will be in Europe, but the rest of the world will still get a show if they watch the skies after midnight.

It’s back! After exceptional displays in recent years, the Leonid meteor shower will appear under dark skies November 17, 2003. Although no one knows for sure what the shower has in store for us, estimates range from a few meteors up to hundreds of meteors per hour at the peak.

Predicting meteor rates, particularly for the highly variable Leonid shower, is akin to estimating the number of snowflakes that will fall on an area of ground. You simply can’t know until it’s all over. And in the case of the Leonids, only observers outside will find out what happens.

The remarkable activity seen during the past few years came about because Earth crossed through regions that the shower’s parent comet, 55P/Tempel-Tuttle, had visited. This year, the timing of Earth’s passage across the comet’s orbit favors observers in Europe. They should see the shower’s peak before dawn on November 18. For North America, the peak arrives the previous evening, although the best views still should come after midnight. Light from the Last Quarter Moon interferes somewhat, but the brighter Leonids should shine through nicely.

Mythology and finding Leo
The Leonids are named after the constellation Leo the Lion. If you trace all the meteor trails backward, they would meet within the boundaries of that constellation. In Greek and Roman mythology, Leo represents the Nemean Lion, whose slaying was the first of Hercules’s twelve labors. To find Leo in the sky, first locate the Big Dipper in the northeast. Poke a hole in the bottom of the Big Dipper’s bowl. As the water runs out, you may hear a mighty roar as the water falls on the back of Leo. In 2003, Leo is even easier to locate. Simply look for the Moon in the early morning hours of November 18, when the Last Quarter Moon will be in the center of the constellation. Adding to the spectacle, the planet Jupiter will be shining brilliantly just to the lower left of the Moon. Jupiter will appear as the brightest starlike object in the sky.

What are meteors?
Meteors are small particles of rock and metal that Earth encounters (runs into) during its orbit around the Sun. In space, these particles are called meteoroids. When they burn up in Earth’s atmosphere, we observe bright streaks called meteors. If they survive the fiery passage through our thick blanket of air and land on Earth, they are called meteorites. No meteorites are generated from meteor showers – the particles are too small.

All meteor showers are caused by comets. As a comet swings around the Sun, heat from the Sun vaporizes the ice in the comet, releasing small particles (meteoroids). Sometimes the orbit of this debris crosses Earth’s orbit. When our planet runs into this stream of particles, we experience a meteor shower.

The Leonid meteor shower is caused by comet 55P/Tempel-Tuttle. This comet was discovered in 1865 by Ernst Tempel and in 1866 by Horace Tuttle. The comet itself is about 2.5 miles (4 kilometers) in diameter and orbits the Sun during a period of slightly more than 33 years. When it makes its closest approach to the Sun, the comet also passes close to Earth’s orbit. This last happened on February 28, 1998. The encounter with the debris stream from Tempel-Tuttle lasts several days, but the most intense part of the encounter typically lasts only two to three hours.

Leonid meteors are fast (they move at 35 to 40 miles per second), and some leave smoke trails that can last a number of seconds. Many Leonids are also bright. Usually, Leonid meteors are white or bluish-white, but in recent years, some observers reported yellow-pink- and copper-colored meteors.

Observing the event
To see the meteors, you’ll need a clear, dark sky. Dark means at least 40 miles from any large city. No telescope is required. In fact, the naked eye works best. Take a lawn chair, cookies, fruit, and a non-alcoholic beverage. (Alcohol interferes with your eyes’ dark adaptation as well as your visual perception of events.) Most importantly, dress warmly, preferably in layers, because Leonid-watching involves no movement or exercise. You’ll be either sitting or standing, and – because it’s November – you will get cold.

Usually, the best advice for meteor-spotters is to go out after midnight during the showers. This is when your part of Earth faces the same direction as the planet’s orbit around the Sun. Earth, therefore, is running into the meteor stream. This year, however, because of the times of the shower’s peak and moonrise, a better plan is to begin observing at dusk on Monday, November 17, and keep watching until the cookies run out.

After sunset, face east and look one-third to one-half of the way up in the sky. Glancing around won’t hurt anything. After moonrise, turn around so you are facing west (away from the Moon) and look overhead.

Photographing meteors
The Leonid meteor shower is not only a wonderful event to observe visually but also a wonderful shower to photograph. On a non-shower night, it’s difficult to photograph meteors because they can occur in any part of the sky. Because meteors move so quickly, they don’t register well on film. With the Leonid shower, however we expect many bright meteors throughout the night.

You will have more success photographing meteors under a dark sky because the background glow will be lowest. Low background illumination allows you to expose the film for longer intervals of time, increasing the chances of capturing meteors on film. Select a camera that allows you to take time exposures, a cable release to minimize vibrations when you open the shutter, and a tripod to steady your camera. Set the camera’s lens wide open (the smallest f-stop on the lens), and set the focus to infinity. Use fast film – ISO 400 or higher. Whether it’s color or black-and-white film is up to you. Expose each frame for ten to twenty minutes. Good luck!

For the most up-to-date astronomy information and beautiful astronomical images, be sure to check out Astronomy magazine and Astronomy.com.

Original Source: Astronomy Magazine News Release

Mars Rover Should Work Fine

Image credit: NASA/JPL

NASA engineers have been working through a problem with one of the Mars rovers currently traveling to the Red Planet, and they think they’ve got a solution. Back in August, engineers detected that Spirit’s M?ssbauer spectrometer – a device for identifying iron-bearing rocks – was sending back incorrect readings. They’ve been able to compensate for the readings, so long as Spirit continues to behave on Mars as it’s working right now. The rovers will land on Mars in January 2004.

A series of tests of one of the science instruments on NASA’s Mars Exploration Rover Spirit has enabled engineers and scientists to identify how to work around an apparent problem detected in August.

Tests now indicate that all of the science instruments on both Spirit and its twin, Opportunity, are in suitable condition to provide full capabilities for examining the sites on Mars where they will land in January.

Spirit’s M?ssbauer spectrometer, a tool for identifying the types of iron-bearing minerals in rocks and soil, returned data that did not fit expectations during its first in-flight checkup three months ago. A drive system that rapidly vibrates a gamma-ray source back and forth inside the instrument appeared to show partial restriction in its motion.

“The drive system is adjustable. We can change its velocity. We can change its frequency,” said Dr. Steve Squyres of Cornell University, Ithaca, N.Y., principal investigator for the rovers’ science instruments. “We’ve found a set of parameters that will give us good M?ssbauer science if the instrument behaves on Mars the way it is behaving now.”

The corrective countermeasures include using a higher frequency of back-and-forth motion. “With these settings, whatever happened during launch will not decrease the quality of the data we get from the instrument,” said Dr. G?star Klingelh?fer, of Johannes Gutenberg University, Mainz, Germany, lead scientist for the M?ssbauer spectrometers on both rovers. “The instrument was designed with enough margin in its performance that we can make this change with no significant science impact.”

A possible explanation for the instrument’s behavior since launch is that intense vibration of the spacecraft during launch shook something inside the spectrometer slightly out of position, he said.

Landings on Mars are risky. Most attempts over the years have failed. And even if the spacecraft survives the landing, there is the potential that individual components could be damaged. “One remaining issue with the M?ssbauer Spectrometer on Spirit, as with all the instruments, is that we can’t be one hundred percent sure it?ll operate on Mars the way it?s operating now,” Squyres said. “We?ll breathe easier once we?ve done all our post-landing health checks.”

Another fact that has emerged from the in-flight checkouts of the M?ssbauer spectrometers on both spacecraft is that the internal calibration channel of the M?ssbauer spectrometer on Opportunity is not functioning properly. But because the instrument has the redundancy of a separate, completely independent external calibration method, this problem will not hamper use of that instrument, Squyres said.

Spirit is on course to arrive at Mars’ Gusev Crater at 04:35 Jan. 4, 2004, Universal Time, which is 8:35 p.m. Jan. 3, Pacific Standard Time and 11:35 p.m. Jan. 3, Eastern Standard Time. (These are “Earth received times,” meaning they reflect the delay necessary for a speed-of-light signal from Mars to reach Earth; on Mars, the landing will have happened nearly 10 minutes earlier.) Three weeks later, Opportunity will arrive at a level plain called Meridiani Planum on the opposite side of Mars from Gusev. Each rover will examine its landing area for geological evidence about the history of water there, key information for assessing whether the site ever could have been hospitable to life.

As of 13:00 Universal Time on Nov. 5 (5 a.m. PST; 8 a.m. EST), Spirit will have traveled 367.4 million kilometers (228.3 million miles) since its launch on June 10 and will still have 119.6 million kilometers (74.3 million miles) to go before reaching Mars. Opportunity will have traveled 296 million kilometers (184 million miles) since its launch on July 7 and will still have 160 million kilometers (99.2 million miles) to go to reach Mars.

The Jet Propulsion Laboratory, a division of the California Institute of Technology, manages the Mars Exploration Rover project for NASA’s Office of Space Science, Washington, D.C. Additional information about the project is available from JPL at http://mars.jpl.nasa.gov/mer and from Cornell University, Ithaca, N.Y., at http://athena.cornell.edu.

Original Source: NASA/JPL News Release

NASA Marks the Third Year of People on the Station

Image credit: NASA

As of Sunday, November 2, the International Space Station has had humans on board for three years. The current crew, Expedition 8, arrived on board only a few weeks ago to replace Expedition 7 who had been on board for six months. With the loss of the space shuttle Columbia earlier this year, construction on the station has come to a halt. 76,000 kg of new equipment is currently being readied for launch, including scientific laboratories and new solar panels.

In a period that has exemplified the benefits of international cooperation in space, the International Space Station will complete a third year of permanent human presence aboard on Sunday, Nov. 2.

The third year of humans living aboard the station has been marked by the perseverance of the orbiting laboratory and international partnership through the tragedy of the Columbia accident.

“Every endeavour that continuously pushes the boundaries of human achievment can have times of both great triumph and great tragedy. The space agencies and nations around the world that are our partners in the Station understand that and they have experienced it,” ISS Program Manager Bill Gerstenmaier said. “The perseverance of crewed operations aboard the Station this year has brought the partnership closer together, and it will strengthen the Station through both the improvements in safety that we plan and the lessons we learn together.”

The eighth resident crew — Commander and NASA ISS Science Officer Mike Foale and Flight Engineer Alexander Kaleri — began a six-month stay aboard the complex Oct. 20.

The station remains the largest, most sophisticated and most powerful spacecraft ever built. Until the Space Shuttle fleet returns to flight, the transport of supplies and crews to the Station will be conducted by Russian spacecraft. The majority of power, cooling, volume and research capacity on the station are supplied by U.S. components. The station has a mass of almost 400,000 pounds and an interior volume roughly equal to that of a three-bedroom house. The U.S. Destiny Laboratory now houses seven different research facilities. The International Space Station partnership includes NASA; Rosaviakosmos, the Russian Space Agency; the Canadian Space Agency; the European Space Agency; and the Japanese Aerospace Exploration Agency.

At the Kennedy Space Center, Fla., 168,000 pounds of additional Station components are being prepared for launch when the Space Shuttle returns to flight. Those components will triple the number of science facilities aboard the orbiting laboratory, increase the total power available for research by over 80 percent and triple the surface area of the Station’s solar arrays. Among components at KSC is the second Station laboratory, the Japanese Experiment Module named Kibo.

Original Source: NASA News Release

The Largest Flare Ever Seen

Image credit: NOAA

A massive flare erupted on the surface of the Sun yesterday that was so bright that it temporarily blinded the instruments on solar observation satellites. Astronomers believe this was the brightest flare that has ever been seen in modern times. Fortunately, this flare, and the following coronal mass ejection fired off to the side of the Sun, so very little material is expected to reach the Earth. The most powerful flares are the X-class; the most powerful flare ever seen before now was an X-20, but this could be an X-30, or even higher.

The NOAA Space Environment Center in Boulder, Colo., reports that an intense explosion occurred on the sun Tuesday at 2:29 p.m. EST. The violent eruption saturated X-ray detectors on NOAA?s GOES satellite, which monitors the sun and produces a new image every minute. NOAA space weather forecasters are still analyzing the event to see if this solar explosion will trigger another bout of radiation and geomagnetic storms. (Click NOAA satellite image for larger view of sun taken on Nov. 4, 2003, at 3:14 p.m. EST. Click here to view latest solar images. Please credit ?NOAA.?)

The explosion occurred in NOAA Region 486, an area that was about to rotate out of view of the Earth. This storm may only deal a glancing blow at the Earth given the position of the solar eruption. This region of the sun will be squarely aimed at Earth once again during Thanksgiving week.

(Click here to view mpeg animation of the sun with the latest solar eruption. The images begin Nov. 3 at 4:06 p.m. EST and end on Nov. 4 at 4:02 p.m. EST. Please note that this is a large file. Please credit “NOAA.”)

NOAA scientists are amazed at the amount of solar activity during the last two weeks. During this cycle of the sun, almost four years past solar maximum, explosions of this magnitude are a rarity.

NOAA forecaster Bill Murtagh said that a radio blackout is in progress. ?This is an R-5 extreme event. They don?t get much bigger than this.? An R-5 event is at the top of the NOAA space weather scales, which run 1 to 5.

Original Source: NOAA News Release

Sun Launches Three More Flares

Image credit: NOAA

It looks like the Sun isn’t done with us yet. Over the last 24-hours, the Sun has hurled three more giant flares towards the Earth. None of these were as large as the flares that struck the Earth last week, but they’re still fairly strong. This should give people in the Northern and Southern latitudes another chance to see an aurora. The sunspots which have been generating all the storms are now rotating over to the side of the Sun and then they’ll go behind it, but they could return again in a few weeks to batter the Earth again.

The series of solar storms that have pummeled Earth continues as forecasters at the NOAA Space Environment Center in Boulder, Colo., observed three more explosions on the sun during the past 24 hours. The largest flare produced a coronal mass ejection, CME, that could strike Earth’s magnetic field by midday Monday. Forecasters are predicting a strong to severe (G-3 to G-4) storm for Monday and Tuesday, as measured by the NOAA space weather scales that run 1 to 5. This storming will provide another chance for those in the northern tier of the U.S. to see the northern lights or Aurora Borealis. (Click NOAA satellite image for larger view of sun taken on Nov. 3, 2003, at 11:34 a.m. EST. Click here to view latest solar images. Please credit ?NOAA.?)

Strong solar radiation and radio blackout storms were in progress on Sunday as a result of the large eruptions. NOAA sun spot regions 486 and 488, which produced these flares, are gradually moving to the western part of the sun and should be rotating out of sight in the next day or so. This might provide Earth with a break from the severe space storms it has experienced over the last 10 days. However, these regions could return to the front side of the sun in several weeks as they rotate back into view. In the 11-year solar cycle, The Earth is currently about three years past solar maximum. Solar maximum is the time when the sun is most active. Right now the sun is in its solar minimum phase.

NOAA is dedicated to enhancing economic security and national safety through the prediction and research of weather and climate-related events and providing environmental stewardship of the nation?s coastal and marine resources. NOAA is part of the U.S. Department of Commerce.

Original Source: NOAA News Release

Giant Mirror Arrives at New Observatory

Image credit: UA

The construction of the world’s most powerful optical telescope took a significant step forward this week when the first of its huge mirrors was delivered. The Mount Graham International Observatory’s Large Binocular Telescope will eventually have twin 8.4 metre mirrors linked together, giving it an effective size of 11.8 metres. But the observatory will be able to view extremely faint objects as if it was 22.8 metres across – that’s 10 times the resolving power of the Hubble Space Telescope. The observatory will be completed in 2005.

The world?s most powerful optical telescope, which will allow astronomers to see planets around nearby stars in our galaxy, took a giant step closer to completion late last week when the first of its huge 27-foot diameter mirrors inched up a tortuous mountain road to its new home at Arizona?s Mount Graham International Observatory.

The 18-ton borosilicate “honeycomb” mirror was escorted up the mountain by a team of scientists, engineers, police, and heavy-haul specialists to the Large Binocular Telescope (LBT) facility. The mirror and its all-steel transport box, which together weighed 55 tons, were transported over 122 miles of Interstate and state highway, then up the narrow hairpin turns of the 29-mile Swift Trail to the Mount Graham International Observatory (MGIO) high above Safford, Ariz.

The journey to 10,480-foot-high Emerald Peak was a two-stage, multi-day affair that required five months of intense planning and preparation. This included a full-scale trial run with a dummy mirror in September.

“Everyone is aware that there?s real glass in there this time,” said J.T. Williams as the huge, yellow 48-wheeled transport rig rolled off pavement and onto the gravel road leading to the observatory. Williams, telescope assembly supervisor, walked every inch of the mountain road to inspect the surface and measure the turns during the transport operation.

Precision road grading by MGIO and Arizona Department of Transportation crews smoothed the worst of the washboard stretches of gravel, and haulers soon discovered that the near-vertical mirror load traveled best with a slight increase in speed over the washboard sections.

The mirror?s journey to Mount Graham began on Thursday, Oct. 23, when the Mirror Lab team and workers from Precision Heavy Haul, Inc. (PHH) loaded the mirror transport box and its precious cargo at UA?s Mirror Lab, which is located in the campus football stadium. The mirror-carrying convoy pulled out of the lab hours before dawn on Friday, accompanied by a 25-vehicle police escort that was organized by Mike Thomas of the UA Police Department. The police car-and-motorcycle escort formed a rolling blockade as the mirror rolled down I-10 and State Highway 191. They provided both traffic and mirror safety as the convoy averaged 45 mph to the MGIO base camp at the base of the Pinaleno Mountains.

Last Monday, Oct. 27, the team at base camp transferred the mirror to PHH?s Goldhofer trailer for the three-day, 29-mile journey to the telescope?s home on Emerald Peak. This 8,000-foot climb was made at about one mile per hour.

The Goldhofer trailer rests on six sets of eight wheels. Each wheel set has an independent hydraulic system that allowed the trailer to be accurately leveled, keeping the mirror upright as it negotiated the road?s banked turns.

“This is probably the most challenging job we?ve done,” said PHH President Mike Poppe, who expertly drove the Goldhofer to the telescope. PHH Vice President Jim Mussmann rode on the Goldhofer and monitored hydraulics, constantly adjusting the trailer to maintain the mirror’s center of gravity.

PHH, which is based in Phoenix, hauled the mirror cell (the structure that holds the mirror and its support system) to the LBT a week earlier and transported many other telescope parts to Mount Graham in 2002.

“Arizona was very fortunate to partner with Precision Heavy Haul, a group that wanted to work with the university as a team of one,” said LBT Associate Director Jim Slagle. “The alliance of Arizona scientists and engineers working alongside Precision Heavy Haul on the proper way to bring these pieces up the mountain turned out to be a successful operation.”

Although the mirror was transported to the mountain last week, its journey began back in 1997 when it was spun cast in the Mirror?s Lab?s giant rotating furnace. The Mirror Lab team has been developing new mirror technologies for the past two decades under the direction of UA Regents? Professor J. Roger Angel.

After it was cast, the mirror was polished using the lab?s innovative stressed-lap technique. The face of the deeply parabolic mirror (f/1.14) mirror is precise within a millionth of an inch over its entire surface.

The Mirror Lab is about to begin polishing the LBT?s second 8.4-meter primary mirror.

Work on the LBT began with construction of the telescope building in 1996 and is scheduled to be completed in 2005 when both mirrors are installed at the $100 million facility. The two mirrors together are valued at $22 million. The telescope building is a 16-story structure, the top ten floors of which rotate.

The LBT will have twin 8.4-meter mirrors on a single telescope mount, giving it the light-collecting area of an 11.8-meter (39-foot-diameter) telescope. But what really excites astronomers is that the LBT will make images of even faint objects as sharp as a 22.8-meter (75-foot) telescope would. This is nearly ten times sharper than the images from the Hubble Space Telescope. When the LBT is fully operational, it will be the world?s most powerful optical telescope, capable of imaging planets beyond our solar system. It will allow astronomers to peer deeper into the universe than ever before.

Astronomers won?t have to wait to 2005, however, to begin using the telescope. It will see first light with its first mirror next summer.

The telescope is a compact, stiff and innovative design produced by UA engineer Warren Davison in collaboration with Roger Angel and engineers in Italy. The major mechanical parts for the LBT were fabricated, pre-assembled and tested at the Ansaldo-Camozzi steel works in Milan, one of Italy?s oldest steel manufacturers. Then the telescope was disassembled and shipped by freighter to Houston, Texas, and overland to Safford, Ariz. The Italian-made mirror cell continued to the Mirror Lab, where Integration Team Leader Steve Warner and his team integrated the mirror support system into the cell for final optical tests before PHH hauled the mirror cell to the mountain two weeks ago.

Astronomers were delighted when the mirror reached its home last week.

“I?m both excited and exhausted simultaneously,” said LBT Project Director John M. Hill, who couldn?t be pried away from the mirror after it arrived at the 10,000-foot-high telescope enclosure on Thursday, Oct. 30. “We?ve been working on this mirror for a long time, and it?s great to see it ready to install in the telescope.”

LBT Associate Director Jim Slagle echoed Hill?s enthusiasm. “I?m terrifically excited,” he said. “Today we?re going to have an observatory. For the first time, we have a mirror. We have a mirror cell. And we?re going to have a telescope.”

Steward?s Associate Director Buddy Powell added, “This is a significant milestone in the process to make available the most powerful optical telescope in the world. It would not have been possible without the support of people in Graham County (Arizona), the State of Arizona, Ohio, Italy, and Germany. It is a perfect example of what people from wide and diverse backgrounds can accomplish by working together. We are very proud of their accomplishment.”

Steward Observatory Director Peter Strittmatter said, “Getting the first LBT 8.4-meter mirror to the observatory on Mount Graham is a major accomplishment, and a huge relief. The LBT team and those involved in the transportation are to be congratulated on their achievement. Arizonan?s can take enormous pride in this project.”

The University of Arizona, which also represents Arizona State University and Northern Arizona University on the project, holds a quarter partnership in the LBT. The Instituto Nazionale di Astrofisica, representing observatories in Florence, Bologna, Rome, Padua, Milan and elsewhere in Italy, is also quarter partner in the project. The Ohio State University and the Research Corp. each holds a one-eighth share, with Research Corp. providing participation for the University of Notre Dame, the University of Minnesota, and the University of Virginia. Germany is the fourth quarter partner in LBT, with contributing science institutions in Heidelberg, Potsdam, Munich, and Bonn.

Original Source: UA News Release

First Light for New Infrared Observatory

Image credit: UH IfA

Astronomers from the University of Hawaii’s Institute for Astronomy released new images from their brand new 16-megapixel camera installed on the 2.2 metre telescope on Mauna Kea. This new camera provides a tremendous increase in resolution over the 1-megapixel camera the telescope was using before, and makes this telescope one of the most powerful on Earth for Infrared astronomy. The newly-released image is of galaxy NGC 891, which is 10 million light-years away in the constellation of Andromeda.

Astronomers from the University of Hawaii (UH), Institute for Astronomy (IfA) today released the first image from a gigantic new 16 Megapixel infrared camera recently mounted on the UH 2.2-meter (88-inch) Telescope on Mauna Kea. The new camera provides a sixteen-fold increase in sky coverage together with much higher sensitivity than the 1-Megapixel cameras in widespread use on telescopes for the last decade. Until larger telescopes have similar cameras, it makes the 30-year-old UH 2.2-meter telescope the most powerful in the world for infrared imaging.

The development of this new technology has been driven by the requirements of NASA’s James Webb Space Telescope (JWST), the next step beyond the Hubble Space Telescope and planned for launch within ten years. This 6 meter class space telescope with six times the collecting area of Hubble will be launched into an orbit far beyond the moon where it will cool to temperatures of -400 degrees Fahrenheit, allowing extremely sensitive infrared observations. NASA has selected the UH/RSC (Rockwell Scientific Company) detector technology for the camera on JWST and is expected to adopt it for several other instruments.

Funded by a nearly $7 million award from NASA Ames Research Center, a team at the IfA Hilo facility headed up by Dr. Don Hall, former IfA director, has partnered with the Rockwell Scientific Company in Camarillo, CA, in a four year program to develop 4 Megapixel chips utilizing new infrared detector materials and state of the art silicon chips which, at a size of nearly 2″ x 2″, are some of the largest ever produced. In partnership with GL Scientific, a Honolulu small business, the team has innovated a new approach to mounting the individual 4 Megapixel chips so that four of them can be “tiled” into a 16 Megapixel camera. This approach allows for even larger “mosaic” cameras in the future.

Hall emphasized that the project was run from Hilo. “The IfA team provided technical direction of both the development effort at Rockwell Scientific and the silicon chip fabrication at the UMC foundry in Taiwan,” he said. “In addition, we have established in Hilo a facility to test these new detectors that is widely regarded as the best available”. Hall also commented “complex instruments like this camera usually require extensive de-bugging once they are mounted at the telescope. It is a tribute to the technical excellence of the IfA staff and the superb equipment at the IfA facility that this camera produced science data on its first night”.

The galaxy imaged, NGC 891, is in the constellation Andromeda at a distance of about 10 million light years. It is of particular scientific interest because it is very similar to our own Milky Way Galaxy but is seen almost exactly edge-on. Dr. Richard Wainscoat and Peter Capak, who are analyzing the image, emphasized the importance of being able to image the entire galaxy in a single exposure with the new camera. “With smaller cameras, galaxies such as NGC 891 had to be imaged in small postage stamp sized pieces that had to be painstakingly pieced together – the new camera produces a better image in a tiny fraction of the time,” Wainscoat said. “By allowing us to image very large areas of the sky, this camera will allow us to detect some of the most distant galaxies in the Universe”.

Along with the JWST, large ground based telescopes are already racing to take advantage of this new technology. Two Mauna Kea projects, the Canada-France-Hawaii Telescope and the Gemini Telescopes, are forging ahead with 16 Megapixel infrared cameras and Rockwell Scientific has orders for several other cameras for telescopes in Chile.

IfA Director Dr. Rolf Kudritzki said “This project is an excellent example of IfA’s nurturing of extremely high-tech projects in its Hilo facility and there is an institutional commitment to continued support of such activities. It is particularly gratifying that a number of the key personnel on this project grew up in Hilo and were recruited back from the Mainland and that several others were recruited directly as graduates of UH Hilo. The project also provided important training for undergraduate assistants from UH Hilo, many of whom have gone on to positions in related fields”.

The Institute for Astronomy at the University of Hawaii conducts research into galaxies, cosmology, stars, planets, and the Sun. Its faculty and staff are also involved in astronomy education, deep space missions, and in the development and management of the observatories on Haleakala and Mauna Kea. Refer to http://www.ifa.hawaii.edu/ for more information about the Institute.

Original Source: IFA News Release

ESO Provides Views of N44 Nebula

Image credit: ESO

The European Southern Observatory has released new images of nebula N44 in the Large Magellanic Cloud. Astronomers used the ESO’s Wide-Field-Imager on the 2.2 metre La Silla Observatory to capture the area with unprecedented clarity. N44 is approximately 1,000 light-years across and contains about 40 bright luminous blue stars. The blue stars live for a very short time and then explode as supernovae – some have already exploded in the area, creating some of the nebula’s visible material.

The two best known satellite galaxies of the Milky Way, the Magellanic Clouds, are located in the southern sky at a distance of about 170,000 light-years. They host many giant nebular complexes with very hot and luminous stars whose intense ultraviolet radiation causes the surrounding interstellar gas to glow.

The intricate and colourful nebulae are produced by ionised gas [1] that shines as electrons and positively charged atomic nuclei recombine, emitting a cascade of photons at well defined wavelengths. Such nebulae are called “H II regions”, signifying ionised hydrogen, i.e. hydrogen atoms that have lost one electron (protons). Their spectra are characterized by emission lines whose relative intensities carry useful information about the composition of the emitting gas, its temperature, as well as the mechanisms that cause the ionisation. Since the wavelengths of these spectral lines correspond to different colours, these alone are already very informative about the physical conditions of the gas.

N44 [2] in the Large Magellanic Cloud is a spectacular example of such a giant H II region. Having observed it in 1999 (see ESO PR Photos 26a-d/99), a team of European astronomers [3] again used the Wide-Field-Imager (WFI) at the MPG/ESO 2.2-m telescope of the La Silla Observatory, pointing this 67-million pixel digital camera to the same sky region in order to provide another striking – and scientifically extremely rich – image of this complex of nebulae. With a size of roughly 1,000 light-years, the peculiar shape of N44 clearly outlines a ring that includes a bright stellar association of about 40 very luminous and bluish stars.

These stars are the origin of powerful “stellar winds” that blow away the surrounding gas, piling it up and creating gigantic interstellar bubbles. Such massive stars end their lives as exploding supernovae that expel their outer layers at high speeds, typically about 10,000 km/sec.

It is quite likely that some supernovae have already exploded in N44 during the past few million years, thereby “sweeping” away the surrounding gas. Smaller bubbles, filaments, bright knots, and other structures in the gas together testify to the extremely complex structures in this region, kept in continuous motion by the fast outflows from the most massive stars in the area.
The new WFI image of N44

The colours reproduced in the new image of N44, shown in PR Photo 31a/03 (with smaller fields in more detail in PR Photos 31b-e/03) sample three strong spectral emission lines. The blue colour is mainly contributed by emission from singly-ionised oxygen atoms (shining at the ultraviolet wavelength 372.7 nm), while the green colour comes from doubly-ionised oxygen atoms (wavelength 500.7 nm). The red colour is due to the H-alpha line of hydrogen (wavelength 656.2 nm), emitted when protons and electrons combine to form hydrogen atoms. The red colour therefore traces the extremely complex distribution of ionised hydrogen within the nebulae while the difference between the blue and the green colour indicates regions of different temperatures: the hotter the gas, the more doubly-ionised oxygen it contains and, hence, the greener the colour is.

The composite photo produced in this way approximates the real colours of the nebula. Most of the region appears with a pinkish colour (a mixture of blue and red) since, under the normal temperature conditions that characterize most of this H II region, the red light emitted in the H-alpha line and the blue light emitted in the line of singly-ionised oxygen are more intense than that emitted in the line of the doubly-ionised oxygen (green).

However, some regions stand out because of their distinctly greener shade and their high brightness. Each of these regions contains at least one extremely hot star with a temperature somewhere between 30,000 and 70,000 degrees. Its intense ultraviolet radiation heats the surrounding gas to a higher temperature, whereby more oxygen atoms are doubly ionised and the emission of green light is correspondingly stronger, cf. PR Photo 31c/03.

Original Source: ESO News Release