Advancing the Webb Space Telescope
The Webb Space Telescope is one of the next generations observatories that will reside near the balance point (L2) between the Earth and Sun. Because the Webb is sensitive to infrared, its contributions will include looking to the earliest dawn of stellar structures. The mirror system is expected to be completed in 2007 in time for its planned 2011 launch.
Astrobiology Magazine — Balancing its position between the Sun and Earth’s gravity, a next generation of Space Observatory is beginning to come off the drawing boards and onto the lathes and lens grinders of machine shops. Scheduled for launch in 2011, the Webb Space Telescope was officially named today after James E. Webb, NASA’s second administrator. Particularly sensitive to the infrared range of the universe, the telescope is part of large-scale international collaborations which also may enable imaging some kinds of extrasolar planets.
NASA’s James Webb Space Telescope (JWST) moved a major step forward with the opening of a state-of-the-art facility that will machine the observatory’s optical components.
The new facility houses advanced computer-aided manufacturing and metrology equipment that will shape JWST’s optical components to a high degree of accuracy. The components consist of 18 hexagonal beryllium segments for JWST’s primary mirror, measuring 1.3 meters from tip to tip, and other mirror substrates and support structures.
Fabrication in the facility will begin later this month and will be completed in 2007.
“Axsys Technologies’ new facility is critical to providing the lightweight beryllium mirrors that enable JWST’s large aperture,” said Martin Mohan, JWST program manager, Northrop Grumman Space Technology. “The start of machining the beryllium blanks marks another key milestone accomplished on schedule for the JWST team.”
Manufacturing the observatory’s mirror is a four-step process, which is being performed by a team led by Ball Aerospace. Brush Wellman compresses beryllium into large segments called “blanks;” Axsys Technologies machines the blanks; Tinsley Laboratories grinds and polishes the mirrors; and Ball incorporates the mirrors into optical assemblies and mounts them on the telescope structure. Manufacturing all 18 mirrors will take approximately four-and-a-half years.
At Axsys Technologies, machining and etching of the blank’s backside will reduce the mirror mass by 92 percent, from 553 pounds (250 kilograms) to 46 pounds (21 kilograms); machining of the front side prepares the optical surface for subsequent grinding and polishing. Earlier this year, Axsys Technologies started machining an engineering development unit (mirror prototype) to demonstrate its capabilities.
The observatory features a 6.5-meter (20 feet) aperture primary mirror that will be the largest deployable telescope ever launched. Beryllium, one of the lightest of all metals, was selected as the mirror technology for its demonstrated track record operating at cryogenic temperatures (around -400 degrees Fahrenheit) on space-based telescopes.
JWST will peer into the infrared at great distances to search for answers to astronomers’ fundamental questions about the birth and evolution of galaxies, the size and shape of the universe, and the mysterious life cycle of matter. In addition to distant galaxies, the longer infrared wavelengths are sensitive to galaxies that are intrinsically red, such as elliptical galaxies and galaxies that have red colors due to a high degree of dust absorption. A component of NASA’s Origins Program, JWST will reside in an orbit 940,000 miles from Earth at the L2 Lagrange point after its launch in 2011.
- Hubble Space Telescope launches aboard Space Shuttle Discovery, as Earth Orbiting Observatory
- Hubble Space Telescope finds evidence of black hole in the center of M87
- Hubble Key Project begins studying Cepheid variable stars to better define Hubble Constant, and the size of the universe
- Sidney van den Bergh and Gustav Tammann debate Hubble Constant and the scale of the universe
- Jim Peebles and Michael Turner debate nature of universe and whether cosmology is solved
- Hubble Space Telescope detects an atmosphere around an extrasolar planet
- Chandra X-ray Observatory finds evidence for new matter in “quark stars”, matter so dense it exceeds terrestrial nuclear material with 1.2 million degree temperatures
- Final mission in NASA Great Observatory series, the infrared observatory, or Spitzer Space Telescope, finds evidence for organic molecules in intergalactic regions
- Microwave measurements precisely date the Big Bang at 13.7 billion years ago, with a remarkable 1% error prediction
- French COROT mission will look at 50,000 to 60,000 stars and should find a few dozen terrestrial planets and several hundred close-in gas-giant planets during a two- to three-year mission
- Kepler, Extrasolar Terrestrial Planet Detection Mission, designed to look for transiting or earth-size planets that eclipse their parent stars [survey 100,000 stars]. Scientists expect to find thousands of planets, and perhaps 50 Earth-like candidates.
- Likely de-orbit for Hubble Space Telescope [date announced is highly fluid but assumes no planned shuttle visits from NASA]
- Planned launch for Space Interferometery Mission (SIM)
- Planned launch for NASA-ESA Next Generation Space Telescope, or NGST [James Webb Space Telescope], a near-infrared telescope that will succeed the Hubble Space Telescope.
- Planned launch for TPF and Darwin missions
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