Lockheed Martin Delivers NASA's Space Infrared Telescope Facility

Yahoo! Finance ^ | 3/7/03 | Lockheed Martin Space Systems Company

[NormsRevenge]

Press Release

Source: Lockheed Martin Space Systems Company

Lockheed Martin Space Systems Delivers NASA's Space Infrared Telescope Facility to Kennedy Space Center for April Launch
Friday March 7, 2:01 pm ET

SUNNYVALE, Calif., March 7 /PRNewswire-FirstCall/ -- NASA's Space Infrared Telescope Facility (SIRTF) has completed integration, testing and prelaunch checkout at Lockheed Martin Space Systems in Sunnyvale, California, and has been delivered to the NASA Kennedy Space Center in Florida for an April 2003 launch. SIRTF's Cryogenic Telescope Assembly, which includes the scientific instruments, was built by Ball Aerospace in Boulder, Colo., and was delivered to Space Systems in Sunnyvale in February 2002 and integrated with the Lockheed Martin-built spacecraft.

"We are very pleased to have completed integration and testing of NASA's latest space observatory," said John Straetker, Lockheed Martin SIRTF program manager. "Environmental and other comprehensive tests done here in Sunnyvale have confirmed that SIRTF is a healthy Observatory, ready for integration with the launch vehicle. We look forward with anticipation to the upcoming launch."

SIRTF is a cryogenically-cooled space observatory that will conduct infrared (IR) astronomy during a two and one-half-to-five year mission beginning in 2003. SIRTF completes NASA's family of Great Observatories that also includes the Hubble Space Telescope, the Chandra X-Ray Observatory and the Compton Gamma Ray Observatory. The SIRTF program, a cornerstone of NASA's Origins Program, is managed by the Jet Propulsion Laboratory in Pasadena, Calif. for NASA's Office of Space Science in Washington DC.

The spaceborne SIRTF observatory comprises a 0.85-meter diameter telescope and three scientific instruments capable of performing imaging and spectroscopy in the 3-180 micron wavelength regime. Incorporating the latest in large-format infrared detector array technology, SIRTF will provide more than a 100-fold increased in scientific capability over previous IR missions. Cornell University, University of Arizona, and the Harvard-Smithsonian Center for Astrophysics have provided the instruments for SIRTF.

An important feature of the SIRTF mission is the adoption of a solar orbit. To reach this orbit, the spacecraft will be launched on a Delta 7920 launch vehicle with slightly greater than terrestrial escape velocity. The resulting orbit will have SIRTF trailing the Earth in its orbit around the Sun. This orbit makes better use of launch capability than do many possible alternate orbits that would keep SIRTF in orbit around the Earth. It permits excellent, uninterrupted viewing of a large portion of the sky without the need for Earth-avoidance maneuvers. In addition, the absence of heat input from the Earth provides a stable thermal environment and allows the exterior of the telescope to reach a low temperature via radiative cooling.

A one meter-diameter transmitting antenna fixed to the bottom of the spacecraft will be used twice each day to transmit 12 hours of stored science data to stations of NASA's Deep Space Network. In this manner, an adequate average data rate of 85 kbps-- corresponding to one image from SIRTF's largest array every 10 seconds -- can be maintained over the lifetime of the mission.

SIRTF's scientific potential is rooted in four basic physical principles that define the importance of infrared investigations for studying astrophysical problems:

    -- Infrared observations reveal cool states of matter: Solid bodies in
       space -- ranging in size from sub-micron-sized interstellar dust grains
       to giant planets -- have temperatures spanning the range from 3K to
       1500K (above which nearly all solids evaporate). Most of the energy
       radiated by objects in this temperature range lies in the infrared part
       of the spectrum. Infrared observations are therefore of particular
       importance in studying low-temperature environments such as dusty
       interstellar clouds where stars are forming and the icy surfaces of
       planetary satellites and asteroids.
    -- Infrared observations explore the hidden Universe: Cosmic dust
       particles effectively obscure parts of the visible Universe and block
       our view of many critical astronomical environments. This dust becomes
       transparent in the infrared, where observers can probe optically
       invisible regions such as the center of our Galaxy (and other galaxies)
       and dense clouds where stars and planets may be forming. For many
       objects -- including dust-embedded stars, active galactic nuclei, and
       even entire galaxies -- the visible radiation absorbed by the dust and
       re-radiated in the infrared accounts for virtually the entire
       luminosity.
    -- Infrared observations access unique spectral features: Emission and
       absorption bands of virtually all molecules and solids lie in the
       infrared, where they can be used to probe conditions in cool celestial
       environments. Many atoms and ions have spectral features in the
       infrared that can be used for diagnostic studies of stellar atmospheres
       and interstellar gas, exploring regions that are too cool or too dust-
       enshrouded to be reached with optical observations.
    -- Infrared observations reach back to the early life of the cosmos: The
       cosmic redshift which results from the general expansion of the
       Universe inexorably shifts energy to longer wavelengths in an amount
       proportional to an object's distance. Because of the finite speed of
       light, objects at high redshift are observed as they were when the
       Universe and those objects were much younger. As a result of the
       expansion of the Universe, most of the optical and ultraviolet
       radiation emitted from stars, galaxies, and quasars since the beginning
       of time now lies in the infrared. How and when the first objects in the
       Universe formed will be learned in large part from infrared
       observations.

Apart from a few windows at short wavelengths, all of the infrared radiation emitted by the above objects is absorbed by Earth's atmosphere. Worse, the infrared emission of the atmosphere itself blinds astronomers peering through those windows. Hence the need for a cooled space-based infrared observatory with high sensitivity -- SIRTF.

NASA's Origins Program follows the chain of events that began with the birth of the Universe at the Big Bang. It seeks to understand the entire process of cosmic evolution from the formation of chemical elements, galaxies, stars and planets, through the mixing of chemicals and energy that cradles life on Earth, to the earliest self-replicating organisms and the profusion of life. In short, Origins hopes to answer the fundamental questions: Where did we come from? Are we alone?

Lockheed Martin Space Systems Company is one of the major operating units of Lockheed Martin Corporation. Space Systems designs, develops, tests, manufactures, and operates a variety of advanced technology systems for military, civil and commercial customers. Chief products include a full-range of space launch systems, including heavy-lift capability, ground systems, remote sensing and communications satellites for commercial and government customers, advanced space observatories and interplanetary spacecraft, fleet ballistic missiles and missile defense systems.

For more information about Lockheed Martin Space Systems, see our website at http://lmms.external.lmco.com .

CONTACT: Buddy Nelson, +1-510-797-0349, or pager, +1-888-916-1797, or buddynelson@mac.com, for Lockheed Martin Space Systems Company.

[gomaaa]

I have friends who worked on the one of detectors for this thing! Very cool stuff. Lots of potential for big discoveries.

[NormsRevenge]

A couple of shots at this link. Space Infrared Telescope Facility (SIRTF)

Pretty cool .. 8-\

[dts32041]

How are they launching, you mean they are going to use a rocket and not the shuttle.

Maybe they are learning something?

[Ernest_at_the_Beach]

NASA's Origins Program follows the chain of events that began with the birth of the Universe at the Big Bang. It seeks to understand the entire process of cosmic evolution from the formation of chemical elements, galaxies, stars and planets, through the mixing of chemicals and energy that cradles life on Earth, to the earliest self-replicating organisms and the profusion of life. In short, Origins hopes to answer the fundamental questions: Where did we come from? Are we alone?

They need to hurry:

'Phantom menace' may rip up cosmos

[Ernest_at_the_Beach]

Shuttle can only put objects in Earth orbit, needs to go out farther!

[Physicist]

There was a contest to name this telescope a couple of years back. Evidently they have yet to pick a winner.

The name I submitted was "Shapley" (after the astronomer Harlow Shapley).

[NormsRevenge]

Caltech SIRTF site

About SIRTF

JPL/NASA - Space Infrared Telescope Facility Arrives at KSC

[NormsRevenge]

[Ken522]

So like how is the satellite going to transmit its data to Earth when it is on the other side of the sun? The article said it'll be in a independent orbit around the sun behind the earth ... dazed and confused ...

[Physicist]

It will be at one of the Earth's Lagrange points.

[KevinDavis]

So we could probaly detect other planets with this telescope?

[KevinDavis]

Shuttle can only put objects in Earth orbit, needs to go out farther!

or we develop something better than the space shuttle that can go out farther than Earth.

[Rain-maker]

http://sirtf.caltech.edu/index.shtml   (click for larger images)            

[gomaaa]

That would be cool, but VERY expensive. We'll be lucky to get a revamped shuttle at this point. Most satellites are put in space by unmanned rockets anyway. They fail much more often than our manned flights do, but since noone dies, it's not as big of a deal.

I don't think they could detect planets in other solar systems with this. I think the article is referring to studies of planets and moons within our own solar system. The way they detect planets around other stars is extremely cool, though! There is so little light given off by these things that it's unlikely we'll be able to directly see many, so they have to infer these planets existence through other means.

If you have two stars, say with about the same mass, they will orbit not one or the other, but a common point in the middle, like a dumbbell being spun around. The Earth and the sun do the same thing, but the Sun is so much bigger that it's really not detectable and it looks just as though the Earth was orbiting the stationary Sun. The thing is that planets the size of Jupiter are so big that they actually force a little wobble in the Sun's position as they go around each other. We can detect this little wobble in other stars and have shown evidence of dozens of planets about the size of Jupiter that way. There is a professor where I work who is trying to prove the existence of planets around stars with large clouds of dust around them by looking at patterns in the dust. We'll see if she turns up anything!

[Brett66]

The Keck and ESO's VLT should be able to see larger exo-planets directly. Keck is almost ready to begin a search for exo-planets and the VLT should be ready in a year or two. Keck has already demonstrated adaptive optics and interferometry capabilities, but I don't think it has used both at the same time. It will need all of these methods to see an extra-solar Jupiter.

[KevinDavis]

I would prefer ways to find Earth like planets so we could go there...

[Brett66]

IIRC, I think the Keck and VLT telescopes can detect Earth-sized planets using the wobble method. So we could probably find terrestrial, Earth-sized planets in the "life zones" of various stars, but we wouldn't be able to directly see them. Now NASA is planning it's Terrestrial Planet Finder mission which will be able to get chemical spectographs of the atmosphere of exo-planets and it could concievably tell us whether life and/or civilization exist on exo-planets out to 40 light years. It will be able to directly image an Earth-like exo-planet, but it would only look like a dot of light. Also the ESA is wanting to launch the Darwin mission, which is a space based interferometer with six 1.5 meter telescopes. It will have greater resolution than the Terrestrial Planet Finder, they're planning to launch around 2014. That's a long time to wait, but it will be amazing to see the results start coming in. We could actually have an answer to whether life exists in other solar systems by 2020.

[NormsRevenge]

Space Telescope Sciences Institute

Chandra X-ray Observatory Center

http://search.yahoo.com/search?p=planet+discovery+telescope

• First Detection Made of an Extrasolar Planet's Atmosphere

• Extrasolar Planet in Double Star System Discovered from La Silla

[NormsRevenge]

http://hubblesite.org/