Einstein Observatory (HEAO-2) was the first fully imaging X-ray telescope put into space and the second of NASA's three High Energy Astrophysical Observatories. Named HEAO B before launch, the observatory's name was changed to honor Albert Einstein upon its successfully attaining orbit.[1]

Quick Facts Mission type, Operator ...
Einstein Observatory
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Einstein Observatory
Mission typeAstronomy
OperatorNASA
COSPAR ID1978-103A Edit this at Wikidata
SATCAT no.11101
WebsiteEinstein Observatory at NASA.gov
Mission duration4 years
Spacecraft properties
ManufacturerTRW
Dry mass3,130 kilograms (6,900 lb)
Start of mission
Launch date13 November 1978, 05:24 (1978-11-13UTC05:24) UTC
RocketAtlas SLV-3D Centaur-D1AR
Launch siteCape Canaveral LC-36B
End of mission
Last contact17 April 1981 (1981-04-18)
Decay date26 May 1982
Orbital parameters
Reference systemGeocentric
RegimeLow Earth
Perigee altitude465 kilometres (289 mi)
Apogee altitude476 kilometres (296 mi)
Inclination23.5°
Period94.0 minutes
Epoch13 November 1978 05:24:00 UTC
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Project conception and design

The High Energy Astronomy Observatory (HEAO) program originated in the late 1960's within the Astronomy Missions Board at NASA, which recommended the launch of a series of satellite observatories dedicated to high-energy astronomy. In 1970, NASA requested proposals for experiments to fly on these observatories, and a team organized by Riccardo Giacconi, Herbert Gursky, George W. Clark, Elihu Boldt, and Robert Novick responded in October 1970 with a proposal for an x-ray telescope. NASA approved four missions in the HEAO program, with the x-ray telescope planned to be the third mission.[2]

One of the three missions of the HEAO program was cancelled in February 1973, due to budgetary pressures within NASA that briefly resulted in the cancellation of the entire program, and the x-ray observatory was moved up to become the second mission of the program, receiving the designation HEAO B (later HEAO-2), and scheduled to launch in 1978.[3]

HEAO-2 was constructed by TRW Inc. and shipped to Marshall Space Flight Center in Huntsville, AL for testing in 1977.[4]

History

HEAO-2 was launched on November 13, 1978, from Cape Canaveral, Florida, on an Atlas-Centaur SLV-3D booster rocket into a near-circular orbit at an altitude of approximately 470 km and orbital inclination of 23.5 degrees.[5] The satellite was renamed Einstein upon achieving orbit, in honor of the centenary of the scientist's birth.

Einstein ceased operations on April 26 1981, when the exhaustion of the satellite's thruster fuel supply rendered the telescope inoperable.[6] The satellite reentered Earth's atmosphere and burned up on March 25, 1982.[7]

Instrumentation

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HEAO 2 diagram: B-1: Gas proportional counter, B-2: High definition camera detector, B-3: Crystal spectrometer, B-4: Gas proportional counter, B-5: Gas spectrometer solid detector, 1: Platform/bus, 2: Solar panel, 3: Optical bench, 4: Rear pre-collimator, 5: Wolter optics, 6: Front pre-collimator, 7: Sun visor, 8: Filters and spectrometer grids, 9: Star finders, 10: Locations reserved for experiments, 11: Central electronics, 12: Focal plane

Einstein carried a single large grazing-incidence focusing X-ray telescope that provided unprecedented levels of sensitivity. It had instruments sensitive in the 0.15 to 4.5 keV energy range. Four instruments were installed in the satellite, mounted on a carousel arrangement that could be rotated into the focal plane of the telescope:[8]

  • The High Resolution Imaging camera (HRI) was a digital x-ray camera covering the central 25 arcmin of the focal plane. The HRI was sensitive to x-ray emissions between 0.15 and 3 keV and capable of ~2 arcsec spatial resolution.
  • The Imaging Proportional Counter (IPC) was a proportional counter covering the entire focal plane. The IPC was sensitive to x-ray emissions between 0.4 and 4 keV and capable of ~1 arcmin spatial resolution.
  • The Solid State Spectrometer (SSS) was a cryogenically cooled silicon drift detector. The SSS was sensitive to x-ray emissions between 0.5 and 4.5 keV. The cryogen keeping the SSS at its operational temperature ran out, as expected, in October 1979.
  • Bragg Focal Plane Crystal Spectrometer (FPCS) was a Bragg crystal spectrometer. The FPCS was sensitive to x-ray emissions between 0.42 and 2.6 keV.

Additionally, the Monitor Proportional Counter (MPC) was a non-focal plane, coaxially-mounted proportional counter that monitored the x-ray flux of the source being observed by the active focal plane instrument.

Two filters could be used with the imaging detectors:

  • The Broad Band Filter Spectrometer consisted of aluminum and beryllium filters than could be placed into the x-ray beam to change the spectral sensitivity.
  • The Objective Grating Spectrometer transmission gratings.

Riccardo Giacconi was the principal investigator for all of the experiments on board Einstein.[9]

Scientific results

Einstein discovered approximately five thousand sources of x-ray emission during its operation[10] and was the first x-ray experiment able to resolve an image of the observed sources.

X-ray background

Surveys by early x-ray astronomy experiments showed a uniform diffuse background of x-ray radiation across the sky. The uniformity of this background radiation indicated that it originated outside of the Milky Way Galaxy, with the most popular hypotheses being a hot gas spread uniformly throughout space, or numerous distant point sources of x-rays (such as quasars) that appear to blend together due to their great distance. Observations with Einstein showed that a large portion of this x-ray background originated from distant point sources, and observations with later x-ray experiments have confirmed and refined this conclusion.[11]

Stellar x-ray emissions

Observations with Einstein showed that all stars emit x-rays.[12] Main sequence stars emit only a small portion of their total radiation in the x-ray spectrum, primarily from their corona, while neutron stars emit a very large portion of their total radiation in the x-ray spectrum.[11] Einstein data also indicated that coronal x-ray emissions in main sequence stars are stronger than was expected at the time.[13]

Galaxy clusters

The Uhuru satellite discovered x-ray emissions from a hot, thin gas pervading distant clusters of galaxies. Einstein was able to observe this gas in greater detail. Einstein data indicated that the containment of this gas within these clusters by gravity could not be explained by the visible matter within those clusters, which provided further evidence for studies of dark matter. Observations by Einstein also helped to determine the frequency of irregularly-shaped clusters compared to round, uniform clusters.[11]

Galactic jets

Einstein detected jets of x-rays emanating from Centaurus A and M87 that were aligned with previously-observed jets in the radio spectrum.[13]

See also

Sources

  • Schlegel, Eric M. (2002). The Restless Universe: Understanding X-ray Astronomy in the Age of Chandra and Newton. New York, NY: Oxford University Press. p. 22-23. ISBN 0-19-514847-9. OCLC 62867004.
  • Tucker, Karen; Tucker, Wallace (1986). The Cosmic Inquirers: Modern Telescopes and Their Makers. Cambridge, MA: Harvard University Press. ISBN 0-674-17436-4. OCLC 12582170.

References

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