Hubble Reveals Helix Nebula

Image credit: Hubble

One of the most detailed images ever taken of the Helix Nebula was unveiled in celebration of Astronomy Day on May 10th. The composite picture was made by blending photos taken by the Hubble Space Telescope and a telescope at Kitt Peak Observatory. The photograph is so detailed because the nebula is close (650 light-years) and visually the same size as our Moon in the night sky.

In one of the largest and most detailed celestial images ever made, the coil-shaped Helix Nebula is being unveiled tomorrow in celebration of Astronomy Day (Saturday, May 10).

The composite picture is a seamless blend of ultra-sharp NASA Hubble Space Telescope (HST) images combined with the wide view of the Mosaic Camera on the National Science Foundation’s 0.9-meter telescope at Kitt Peak National Observatory, part of the National Optical Astronomy Observatory, near Tucson, Ariz. Astronomers at the Space Telescope Science Institute assembled these images into a mosaic. The mosaic was then blended with a wider photograph taken by the Mosaic Camera. The image shows a fine web of filamentary “bicycle-spoke” features embedded in the colorful red and blue gas ring, which is one of the nearest planetary nebulae to Earth.

Because the nebula is nearby, it appears as nearly one-half the diameter of the full Moon. This required HST astronomers to take several exposures with the Advanced Camera for Surveys to capture most of the Helix. HST views were then blended with a wider photo taken by the Mosaic Camera. The portrait offers a dizzying look down what is actually a trillion-mile-long tunnel of glowing gases. The fluorescing tube is pointed nearly directly at Earth, so it looks more like a bubble than a cylinder. A forest of thousands of comet-like filaments, embedded along the inner rim of the nebula, points back toward the central star, which is a small, super-hot white dwarf.

The tentacles formed when a hot “stellar wind” of gas plowed into colder shells of dust and gas ejected previously by the doomed star. Ground-based telescopes have seen these comet-like filaments for decades, but never before in such detail. The filaments may actually lie in a disk encircling the hot star, like a collar. The radiant tie-die colors correspond to glowing oxygen (blue) and hydrogen and nitrogen (red).

Valuable Hubble observing time became available during the November 2002 Leonid meteor storm. To protect the spacecraft, including HST’s precise mirror, controllers turned the aft end into the direction of the meteor stream for about half a day. Fortunately, the Helix Nebula was almost exactly in the opposite direction of the meteor stream, so Hubble used nine orbits to photograph the nebula while it waited out the storm. To capture the sprawling nebula, Hubble had to take nine separate snapshots.

Planetary nebulae like the Helix are sculpted late in a Sun-like star’s life by a torrential gush of gases escaping from the dying star. They have nothing to do with planet formation, but got their name because they look like planetary disks when viewed through a small telescope. With higher magnification, the classic “donut-hole” in the middle of a planetary nebula can be resolved. Based on the nebula’s distance of 650 light-years, its angular size corresponds to a huge ring with a diameter of nearly 3 light-years. That’s approximately three-quarters of the distance between our Sun and the nearest star.

The Helix Nebula is a popular target of amateur astronomers and can be seen with binoculars as a ghostly, greenish cloud in the constellation Aquarius. Larger amateur telescopes can resolve the ring-shaped nebula, but only the largest ground-based telescopes can resolve the radial streaks. After careful analysis, astronomers concluded the nebula really isn’t a bubble, but is a cylinder that happens to be pointed toward Earth.

Original Source: Hubble News Release

NASA Selects New Shuttle Program Manager

Image credit: NASA

NASA announced on Friday that William Parsons will become the new manager for the space shuttle program, replacing Ronald Dittemore who resigned on April 23. Previous to this position, Parsons was the director for NASA?s John C. Stennis Space Center in Mississippi. Dittemore had made plans to leave the position long before the Columbia disaster, but decided to stay on longer to help coordinate the investigation.

NASA today announced the selection of William (Bill) W. Parsons as the new manager for the Space Shuttle Program. Parsons, the director of the NASA John C. Stennis Space Center (SSC) in south Mississippi, succeeds Ronald D. Dittemore, who announced his resignation April 23.

“Bill is a talented leader, motivator, and he’s deeply devoted to the success of the Space Shuttle program,” said William F. Readdy, Associate Administrator of Space Flight at NASA Headquarters in Washington. “His management, technical experience, and dedication to safety are vital as we move forward and prepare to start flying again.”

Parsons has served as Center Director since August 2002. He was first assigned to SSC in 1997 as the Chief of Operations of the Propulsion Test Directorate. Parsons relocated to NASA Johnson Space Center (JSC) in Houston to become the Director of the Center Operations Directorate, and he later served as the Deputy Director of JSC. He returned to SSC in 2001, and he served as Director of the Center Operations and Support Directorate.

“I welcome the opportunity to work with Bill. He knows the space flight family and he knows the Space Shuttle program,” said Michael C. Kostelnik, Deputy Administrator for the International Space Station and Space Shuttle programs at Headquarters in Washington. “NASA is about the people who fly, fix, maintain and design our vehicles, and I know we’ve found a terrific leader to help guide the team through this difficult time.”

“This is a critical position for the agency as we begin to focus our Return to Flight efforts in the wake of the Columbia tragedy,” said NASA Administrator Sean O’Keefe. “The Space Shuttle Program, the entire space flight community, and the nation will be served by Bill’s great leadership. He will be missed by our colleagues at Stennis, but the benefits to all the NASA family will be tremendous.” Parsons began his career in the United States Marine Corps as an Infantry Officer, then worked as a manufacturing engineer and later as an aerospace engineer at Cape Canaveral Air Force Station in Florida.

In 1990, Parsons joined the NASA team at Kennedy Space Center (KSC) as a Launch Site Support Manager in the Shuttle Operations Directorate, worked as an Executive Management Intern, and later as the Shuttle Flow Director of the Shuttle Operations Directorate at KSC. In 1996, he became Manager of the Space Station Hardware Integration Office at KSC.

“From the first time I saw a Space Shuttle launch, I knew I wanted to be a part of NASA and America’s space exploration efforts,” said Parsons. “This is a challenging time for the program, but the people of NASA have a long, successful history of overcoming adversity. I’m proud to be a part of the Return to Flight effort and look forward to getting the Space Shuttle safely flying again.”

Parsons has received numerous honors, including NASA’s Exceptional Service Medal; the National Intelligence Medal of Achievement; the Silver Snoopy, awarded by astronauts for outstanding performance in flight safety and mission success; the Center Directors’ Commendation; and the Commandants Certificate of Commendation from the United States Marine Corps.

He graduated from the University of Mississippi with a Bachelor of Engineering degree. He also holds a Master of Science degree in Engineering Management from the University of Central Florida.

Stennis Deputy Director Michael Rudolphi will serve as interim director until a permanent successor is named.

Original Source: NASA News Release

Japanese Rocket Launches Asteroid Probe

A Japanese M-5 rocket lifted off on Friday carrying a spacecraft which will be the first to ever collect samples from the surface of an asteroid. Called Muses-C, the spacecraft will take only two years to reach asteroid 1998 SF 36 – one of the Earth?s closest space neighbours ? and then return to Earth by 2007. A grapefruit-sized marker imprinted with nearly 900,000 names will also be dropped onto the asteroid?s surface.

Space Pioneer Unveils Rocket Prototype

Aerospace pioneer Bart Rutan has created what he calls the world’s first private space program. The three-person capsule, rocket and launch aircraft, together dubbed SpaceShipOne, were unveiled at Scaled Composite’s facilities in California on Friday to several hundred guests. Rutan and his team plans a series of test flights culminating at an attempt to win the X-Prize (the first privately built spacecraft to reach space).

Columbia Investigators Release Preliminary Report

Image credit: NASA

The Columbia Accident Investigation Board, the group attempting to determine what destroyed the space shuttle Columbia in February, released some preliminary recommendations for NASA to prevent future shuttle accidents. They recommended increased inspections of several shuttle components as well as taking images of the shuttles while they’re in orbit by various space-based cameras to detect any damage.

Houston, Texas — The Columbia Accident Investigation Board today issued two preliminary recommendations to NASA. Additionally, the Board issued several facts regarding the shuttle program.

Recommendation One: Prior to return to flight, NASA should develop and implement a comprehensive inspection plan to determine the structural integrity of all Reinforce Carbon-Carbon (RCC) system components. This inspection plan should take advantage of advanced non-destructive inspection technology.

This recommendation was issued because of the board’s finding that current inspection techniques are not adequate to assess structural integrity of RCC, supporting structure, and attaching hardware.

Recommendation Two: Prior to return to flight, NASA should modify its Memorandum of Agreement with National Imagery and Mapping Agency (NIMA) to make on-orbit imaging for each Shuttle flight a standard requirement.

This recommendation was issued because of the board’s finding that the full capabilities of the United States Government to image the Shuttle on orbit were not utilized.

Facts Regarding RCC Components — The board will include the following facts in its final report:

* The Reinforced Carbon-Carbon (RCC) system (including all RCC, supporting structure and attaching hardware) is an essential component of the Space Shuttle Orbiter Thermal Protection System (TPS) and has a Criticality Rating of 1 (loss of crew – loss of vehicle).

* The RCC composite consists of a reinforced carbon-carbon substrate that carries the structural loads, a tetraethyl orthosilicate impregnation that reduces inherent substrate porosity, a silicon carbide treatment that protects the substrate from oxidation, and a sealant coating that provides additional oxidation protection. These composite structures are attached to the shuttle by a metal support system.

* During initial manufacturing acceptance, the integrity of production composites used in the RCC system is checked at various points in production by physical tap, ultrasonic, radiographic, eddy current, weight gain, and visual tests. In addition, a flat plate control panel made in parallel with the production piece is destructively tested at various points in the production process.

* A projected design mission life has been established for each RCC component. These projections are based on analysis correlated to simulated flight load testing, and assume the presence of sound composite material and metal support structure.

* Visual external inspections and tactile checks are the only specified post flight inspections of RCC composite components. The planned interval for removing RCC composite components for more thorough inspection is typically many flights, unless their removal is dictated by an observed visual surface condition or necessitated by the requirement to provide access for other operations.

* Non-destructive testing of some post-flight RCC components has shown indications of RCC material defects not previously identified by visual inspection methods currently employed.

Facts Regarding Shuttle Imaging — The board will include the following facts in its final report:

* The U.S. Government has the capability to image the Shuttle on orbit.

* A Memorandum of Agreement exists between NASA and NIMA regarding on-orbit imaging of the Shuttle.

* During the flight of STS-107, there were no on-orbit images taken of sufficient resolution to assess the Orbiter’s condition.

The CAIB issued these recommendations and findings in advance of their appearance in the final report. The board’s final report will be issued later this summer. It will include the probable cause of the accident, contributing factors, findings and additional recommendations.

Original Source: CAIB News Release

Satellite Monitors Dangerous Glacier

Image credit: NASA

NASA’s Terra satellite is keeping a watchful camera pointed towards a glacier in the mountains of Peru. A large crack has appeared in the sheet of ice, and it could crumble into Lake Palcacocha, sending a wall of water and rubble into a nearby town of 60,000 people. This has been a controversial announcement, however, with several US and Peruvian geologists feel that the danger is exaggerated.

An Earth-monitoring instrument aboard NASA’s Terra satellite is keeping a close eye on a potential glacial disaster-in-the-making in Peru’s spectacular, snow-capped Cordillera Blanca (White Mountains), the highest range of the Peruvian Andes.

Data from NASA’s Advanced Spaceborne Thermal Emission and Reflection Radiometer (Aster) is assisting Peruvian government officials and geologists in monitoring a glacier that feeds Lake Palcacocha, located high above the city of Huaraz, 270 kilometers (168 miles) north of Lima. An ominous crack has developed in the glacier. Should the large glacier chunk break off and fall into the lake, the ensuing flood could hurtle down the Cojup Valley into the Rio Santa Valley below, reaching Huaraz and its population of 60,000 in less than 15 minutes.

“Remote sensing instruments like Aster can serve a vital role in mountain hazard management and disaster mapping by providing rapid access to data, even in regions not easily accessible by humans,” explained Dr. Michael Abrams, associate Aster team leader at NASA’s Jet Propulsion Laboratory, Pasadena, Calif.

“Aster’s unique vantage point from space gives scientists another tool with which to see early signs of potential glacial flood-burst events and to monitor changes in glacial behavior over time. In Huaraz, Peruvian authorities and scientists will incorporate Aster data along with data from ground-based monitoring techniques to better assess current conditions and take steps necessary to reduce risks to human lives and property,” Abrams said.

Comparison images of the area and more information are available at: http://photojournal.jpl.nasa.gov/catalog/PIA03899. Huaraz can be seen in the images’ left-center, with Lake Palcacocha in the images’ upper right corners at the head of a valley, below the snow and glacier cap. The left image was acquired on November 5, 2001; the right on April 8, 2003.

Glacial flood-bursts, known by Peruvians as “aluviones,” occur periodically when water is released abruptly from a previously ice-dammed lake alongside, within, or above a glacier. The release can be caused by various triggering events. These flood-bursts typically arrive with little or no warning, carrying liquid mud, large rock boulders and blocks of ice.

The Rio Santa Valley is no stranger to such disasters. Since 1702, floods caused by glaciological conditions have repeatedly caused death and destruction in the region. One particularly devastating event in 1941 destroyed approximately one-third of Huaraz, killing an estimated 5,000 to 7,000 people. Since then, the Peruvian government has emphasized control of the water level in Lake Palcacocha and other lakes in the region that pose similar threats. The efforts appear to have worked; since 1972, no destructive floods resulting from the breakout of glacial lakes have occurred. Nevertheless, officials are still monitoring the current situation closely.

Aster’s broad spectral coverage and high spectral resolution is ideally suited for monitoring dynamic conditions and changes in Earth’s landscape over time, including glacial advances and retreats. Its 14 spectral bands measure from the visible to the thermal infrared wavelength region, and it can “see” at a resolution of 15 to 90 meters (about 50 to 300 feet).

Aster provides scientists in numerous disciplines with critical information used for surface mapping and monitoring of dynamic conditions and changes over time. Example applications include monitoring glacial advances and retreats and potentially active volcanoes; identifying crop stress; determining cloud morphology and physical properties; evaluating wetlands; monitoring thermal pollution and coral reef degradation; mapping surface temperatures of soils and geology; and measuring surface heat balance. It can also image the same area as frequently as every other day in response to urgent priorities.

Aster is one of five Earth-observing instruments launched December 18, 1999, on NASA’s Terra satellite. Japan’s Ministry of Economy, Trade and Industry built the instrument. A joint U.S./Japan science team is responsible for validation and calibration of the instrument and the data products.

The Terra satellite is part of NASA’s Earth Science Enterprise, a program dedicated to understanding the Earth as an integrated system and applying Earth system science to improve prediction of climate, weather and natural hazards using the unique vantage point of space.

The California Institute of Technology in Pasadena manages JPL for NASA.

Original Source: NASA/JPL News Release

X-Rays Seen from Brown Dwarf Star

Image credit: Chandra

The latest photos released from the Chandra X-Ray Observatory show x-rays produced from a brown dwarf which is orbiting a binary star system at a distance of 2.75 times that of the Pluto Charon orbit around the Sun. The star system is 180 light-years away from Earth in the constellation of Hydra. The brown dwarf, TWA 5B, is a failed star between 15 and 40 times the size of Jupiter.

A Chandra observation revealed X-rays produced by TWA 5B, a brown dwarf star orbiting a young binary star system known as TWA 5A. The star system is 180 light years from the Earth and a member of a group of about a dozen young stars in the Hydra constellation. The brown dwarf orbits the binary star system at a distance about 2.75 times that of Pluto’s orbit around the Sun.

The sizes of the sources in the image are due to an instrumental effect that causes the spreading of pointlike sources. For a comparison of the actual size of TWA 5B to the Sun and the planet Jupiter, see the illustration below.

Brown dwarfs are often referred to as “failed stars” because they are under the mass limit (about 80 Jupiter masses, or 8 percent of the mass of the Sun) needed to spark the nuclear fusion of hydrogen to helium which supplies the energy for stars such as the Sun. Lacking any central energy source, brown dwarfs are intrinsically faint and draw their energy from a very gradual shrinkage or collapse.

Young brown dwarfs, like young stars, have turbulent interiors. When combined with rapid rotation, this turbulent motion can lead to a tangled magnetic field that can heat their upper atmospheres, or coronas, to a few million degrees Celsius. The X-rays from both TWA 5A and TWA 5B are from their hot coronas.

TWA 5B is estimated to be only between 15 and 40 times the mass of Jupiter, making it one of the least massive brown dwarfs known. Its mass is rather near the boundary (about 12 Jupiter masses) between planets and brown dwarfs, so these results could have implications for the possible X-ray detection of very massive planets around stars.

Original Source: Chandra News Release

Mars Rover Delayed to Fix Glitch

NASA engineers will need to disassemble both of their Mars rovers to fix an electrical device which could have caused a catastrophic short circuit later in the mission. This delay will push the launch of the first rover a week to no earlier than June 6, with the second launching two weeks later as scheduled. The twin rovers will perform a series of geologic experiments on Mars to search for evidence of past water.

Russia’s President Vow’s Additional Space Station Support

During a video conference with the crew of the International Space Station on Saturday, Russian President Vladimir Putin said that they would send additional spacecraft during the US freeze on shuttle flights. “If it comes to it, we will look at the question of Russia taking on further work in the ISS.” A replacement 2-man crew is due to launch on April 26.

Six New Moons Found Around Jupiter

Image credit: University of Hawaii

Astronomers from the University of Hawaii have discovered six new moons for Jupiter, pushing the planet’s satellite count to 58 – the largest group of moons in the Solar System. These aren’t terribly big moons, though, only a kilometer or so across. The moons were discovered as part of an ongoing search using the world’s largest digital cameras at the Subaru and Canada-France-Hawaii telescopes atop Mauna Kea.

The majority of the new satellites were first seen in early February 2003 by Scott S. Sheppard and David C. Jewitt from the Institute for Astronomy, University of Hawaii along with Jan Kleyna of Cambridge University. The satellites were detected using the world’s two largest digital cameras at the Subaru (8.3 meter diameter) and Canada-France-Hawaii (3.6 meter diameter) telescopes atop Mauna Kea in Hawaii. Both telescopes and their imaging cameras represent the latest technology has to offer. Recoveries were performed at the University of Hawaii 2.2 meter with help from Yanga Fernandez and Henry Hsieh also from the University of Hawaii. Brian Marsden of the Harvard-Smithsonian Center for Astrophysics performed the orbit fitting for the new satellites.

The first 7 satellites were formally announced by the International Astronomical Union on Circular No. 8087 on March 4, 2003 while the eighth was announced on Circular No. 8088 on March 6, the 9th through 12th on Circular No. 8089 on March 7, S/2003 J13 through J20 were announced in April, and S/2003 J21 in May*. Except for S/2003 J20, all the new Jupiter satellites appear to have distant retrograde orbits (ie. their orbital rotation is opposite to Jupiter’s rotation) like the majority of the known irregular satellites of Jupiter. The satellite S/2003 J20 appears to be a prograde satellite dynamically distinct from any other known Jupiter satellite.

Original Source: IFA News Release