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The experiment uses [[bolometer]]s<ref name="Crill">{{cite journal|title=BOOMERANG: A Balloon-borne Millimeter Wave Telescope and Total Power Receiver for Mapping Anisotropy in the Cosmic Microwave Background|journal=[[The Astrophysical Journal Supplement Series|ApJS]]|volume=148|pages=527–541|doi=10.1086/376894|arxiv=astro-ph/0206254|last1=Crill|first1=B. P.|display-authors=etal|date=October 2003|bibcode=2003ApJS..148..527C}}</ref> for radiation detection. These bolometers are kept at a temperature of 0.27 [[kelvin]]. At this temperature the material has a very low heat capacity according to the [[Debye model|Debye law]], thus incoming microwave light will cause a large temperature change, proportional to the intensity of the incoming waves, which is measured with sensitive thermometers.
The experiment uses [[bolometer]]s<ref name="Crill">{{cite journal|title=BOOMERANG: A Balloon-borne Millimeter Wave Telescope and Total Power Receiver for Mapping Anisotropy in the Cosmic Microwave Background|journal=[[The Astrophysical Journal Supplement Series|ApJS]]|volume=148|pages=527–541|doi=10.1086/376894|arxiv=astro-ph/0206254|last1=Crill|first1=B. P.|display-authors=etal|date=October 2003|bibcode=2003ApJS..148..527C}}</ref> for radiation detection. These bolometers are kept at a temperature of 0.27 [[kelvin]]. At this temperature the material has a very low heat capacity according to the [[Debye model|Debye law]], thus incoming microwave light will cause a large temperature change, proportional to the intensity of the incoming waves, which is measured with sensitive thermometers.


An off-axis 1.3-meter primary mirror<ref name="Crill"/> focuses the microwaves onto the focal plane which consist of 16 horns. These horns, operating at 145&nbsp;GHz, 245&nbsp;GHz and 345&nbsp;GHz, are arranged into 8 pixels. Only a tiny fraction of the sky can be seen concurrently, so the telescope has to rotate to scan the whole field of view.
An off-axis 1.3-meter primary mirror<ref name="Crill"/> focuses the microwaves onto the focal plane, which consist of 16 horns. These horns, operating at 145&nbsp;GHz, 245&nbsp;GHz and 345&nbsp;GHz, are arranged into 8 pixels. Only a tiny fraction of the sky can be seen concurrently, so the telescope must rotate to scan the whole field of view.


==Results==
==Results==

Revision as of 05:58, 5 March 2016

BOOMERanG experiment
The Telescope being readied for launch
Alternative namesBalloon Observations Of Millimetric Extragalactic Radiation and Geophysics Edit this at Wikidata
Location(s)Antarctica Edit this at Wikidata
Telescope styleballoon-borne telescope
cosmic microwave background experiment
radio telescope Edit this on Wikidata
Websitecmb.phys.cwru.edu/boomerang/ Edit this at Wikidata
  Related media on Commons

In astronomy and observational cosmology, The BOOMERanG experiment (Balloon Observations Of Millimetric Extragalactic Radiation ANd Geophysics) was an experiment which measured the cosmic microwave background radiation of a part of the sky during three sub-orbital (high altitude) balloon flights. It was the first experiment to make large, high fidelity images of the CMB temperature anisotropies, and is best known for the discovery in 2000 that the geometry of the universe is close to flat,[1] with similar results from the competing MAXIMA experiment.

By using a telescope which flew at over 42,000 meters high, it was possible to reduce the atmospheric absorption of microwaves to a minimum. This allowed massive cost reduction compared to a satellite probe, though only a tiny part of the sky could be scanned.

The first was a test flight over North America in 1997. In the two subsequent flights in 1998 and 2003 the balloon was launched from McMurdo Station in the Antarctic. It was carried by the Polar vortex winds in a circle around the South Pole, returning after two weeks. From this phenomenon the telescope took its name.

The BOOMERanG team was led by Andrew E. Lange of Caltech and Paolo de Bernardis of the University of Rome La Sapienza.[2]

Instrumentation

The experiment uses bolometers[3] for radiation detection. These bolometers are kept at a temperature of 0.27 kelvin. At this temperature the material has a very low heat capacity according to the Debye law, thus incoming microwave light will cause a large temperature change, proportional to the intensity of the incoming waves, which is measured with sensitive thermometers.

An off-axis 1.3-meter primary mirror[3] focuses the microwaves onto the focal plane, which consist of 16 horns. These horns, operating at 145 GHz, 245 GHz and 345 GHz, are arranged into 8 pixels. Only a tiny fraction of the sky can be seen concurrently, so the telescope must rotate to scan the whole field of view.

Results

CMB Anisotropy measured by BOOMERanG

Together with experiments like the Saskatoon experiment, TOCO, MAXIMA, and others, the BOOMERanG data from 1997 and 1998 determined the angular diameter distance to the surface of last scattering with high precision. When combined with complementary data regarding the value of Hubble's constant, the Boomerang data determined the geometry of the Universe to be flat,[1] supporting the supernova evidence for the existence of dark energy. The 2003 flight of Boomerang resulted in extremely high signal-to-noise ratio maps of the CMB temperature anisotropy, and a measurement of the polarization of the CMB.[4]

References

  1. ^ a b de Bernardis, P.; et al. (27 April 2000). "A Flat Universe from High-Resolution Maps of the Cosmic Microwave Background Radiation". Nature. 404 (6781): 955–959. arXiv:astro-ph/0004404. doi:10.1038/35010035. PMID 10801117.
  2. ^ Glanz, James (27 April 2000). "Clearest Picture of Infant Universe Sees It All and Questions It, Too". The New York Times. Retrieved 2010-02-23.
  3. ^ a b Crill, B. P.; et al. (October 2003). "BOOMERANG: A Balloon-borne Millimeter Wave Telescope and Total Power Receiver for Mapping Anisotropy in the Cosmic Microwave Background". ApJS. 148: 527–541. arXiv:astro-ph/0206254. Bibcode:2003ApJS..148..527C. doi:10.1086/376894.
  4. ^ MacTavish, C. J.; et al. (August 2006). "Cosmological Parameters from the 2003 Flight of BOOMERANG". ApJ. 647: 799–812. arXiv:astro-ph/0507503. Bibcode:2006ApJ...647..799M. doi:10.1086/505558.