Pushchino Radio Astronomy Observatory

Pushchino Radio Astronomy Observatory
Organization	Astro Space Center of Lebedev Physical Institute (LPI), Russian Academy of Sciences
Location	Pushchino-on-Oka, Russia (near Moscow)
Coordinates	54°49′20″N 37°37′53″E / 54.82222°N 37.63139°ECoordinates: 54°49′20″N 37°37′53″E / 54.82222°N 37.63139°E
Established	April 11, 1956
Closed	still active
Website	http://www.prao.ru/
Telescopes
RT 22 (1959)	Four, separate, fully steerable, radio telescope with 22 meter mirrors
DKR 1000 (1964)	A wide-band radio telescope instrument
BSA/LPI (1973)	Large Phased Array
	Location of Pushchino Radio Astronomy Observatory
	Related media on Wikimedia Commons
	[edit on Wikidata]

Pushchino Radio Astronomy Observatory is a Russian (former Soviet) radio astronomy observatory. It was developed by Lebedev Physical Institute (LPI), Russian Academy of Sciences within a span of twenty years. It was founded on April 11, 1956, and currently occupies 70 000 square meters.^[1]

Radio astronomy in Russia

Historically, Russian radio astronomy (formerly Soviet) has had a permanent and stable connection with the P N Lebedev Physical Institute (LPI) of the Russian Academy of Sciences. The institute had both permanent stations and conducted expeditions to locations in the field in the Crimea region. These facilities, and expeditions were designed for research in radio astronomy beginning in the late 1940s.^[1]

A decade later the center for radio astronomy research had gravitated to the southern Moscow region (about 75 miles south of Moscow), in Pushchino (informally called Pushchino-on-Oka). Here a new observatory, the Pushchino Radio Astronomy Observatory was developed within twenty years as part of the LPI Astro Space Center. It has become one of the largest radio astronomy observatories in Russia and in the world (2001). It was founded in April, 11th, 1956 under the purview of the Academy of Sciences of the USSR.^[1]

History of equipment in use

The Pushchino Radio Astronomy Observatory has four notable radio telescopes (RT 22), each with mirrors at 22 meters. Constructed in 1959 these are fully steerable, and are designed to operate in millimeter and centimeter range of wavelength. Added to the equipage is the DKR 1000, a wide-band radio telescope instrument, on-line in 1964, operating in the meter wavelength range. The DKR 1000 has arms that are 40 by 1000 meters. In 1973, another telescope was added to this set. The nomenclature is Large Phased Array with the designation BSA/LPI, operating in the meter wavelength range. The DKR 1000 and BSA/LPI, are currently the largest radio telescopes in the world, which operate in the meter range.^[2]

Research divisions

The Observatory employs 45 researchers along with 60 engineers and technicians to accomplish staff the several major departments and several labs of the observatory. These are combined with 80 other people who perform administrative duties, workshops, garage, and a staff of guards. The departments and labs are designed to focus on scientific and technical aspects of observatory sciences.^[2]

The departments are as follows: Plasma astrophysics, Extragalactic radio astronomy, Pulsar physics, Space radio spectroscopy, and Pulsar astrometry. The laboratories are as follows: Radio astronomy equipment, Automation radio astronomy research, Computer engineering and information technology, and Radio telescopes of the meter wavelength range.^[2]

Main areas of research

radio astronomy for Astrophysics
molecular clouds physics
space masers
giant atoms in Space
star formation processes (research and investigation)
physical conditions in the diffuse interstellar medium
supernova remnants and the interstellar medium
radio emission of radio galaxies and quasars
interplanetary plasma and solar wind investigations
how perturbations propagate in the interplanetary plasma is studied
Northern Hemispheric isotope construction
catalogue of radio sources
active galactic nuclei are studied
VLBI (Very Large Baseline Interferometry)
pulsars physics which are neutron stars
pulsar radio emission is studied in the context of microstructure of pulse and the mechanism involved.
establish pulsar time scale by timing of pulsars.^[2]^[3]

Outstanding achievements

Alfven waves energy flow at 10 solar radii,

establish the existence of a planet near pulsar PSR BO329+54,

calalogue the spectra of 336 pulsars, discovery of a radio pulsar 102 MHz while observing X-ray radio source Geminga,

another radio pulsar discovered as the source of SGR 1900+14

an interplanetary scintillating method accomplishes a successful survey of compact radio sources.

References

1 2 3
"The observatory unique instrumentation system is briefly reviewed in a historical perspective. Key research areas and some major achievements are outlined, and the prospects of the observatory as (currently) part of the LPI Astro Space Center are examined."
- Dagkesamanskii, Rustam D (2009). "The Pushchino Radio Astronomy Observatory of the P N Lebedev Physical Institute Astro Space Center: yesterday, today, and tomorrow" (A very brief history of radio astronomy in Russia (formerly Soviet)). Physics-Uspekhi. 52 (11): 1159. Bibcode:2009PhyU...52.1159D. doi:10.3367/UFNe.0179.200911i.1225. Retrieved 2010-04-03.
- UFN, 2009, Volume 179, Number 11, Pages 1225–1235
1 2 3 4 Pushchino Scientific Centre, Pushchino, Moscow Region, 142290, Russia (2001). "Pushchino Radio Astronomy Observatory". PRAO/ASC/LPI/RAS. Retrieved 2010-04-03.
↑ Shabanova, Tatiana V. (1995). "Evidence for a Planet around the Pulsar PSR B0329+54". The Astrophysical Journal. 453: 779. Bibcode:1995ApJ...453..779S. doi:10.1086/176440.

External links

Pictures of the Pushchino Radio Astronomy Observatory, along with some information.

English Russia photo set with some descriptions
Physics Upsekhi page for article

General references

Book chapters:
Artyukh, Vadim S. (January 2002). Investigations of AGNS by the Interplanetary Scintillation Method. p. 185.

Kuzmin, Arkady (January 2002). Scattering of the low frequency Pulsar Radiation. p. 53.

Book citation: Sources and Scintillations: Refraction and Scattering in Radio Astronomy. Edited by Richard Strom, Peng Bo, Mark Walker, and Nan Rendong. IAU Colloquium 182. Sources and Scintillations. ISBN 978-1-4020-0048-5. Kluwer Academic Publishers, Dordrecht.

Reprinted from Astrophysics and Space Science, Volume 278 (1-2), 2001, p. 255.

This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.

[Radio-ast-russia-1] 1 2 3 "The observatory unique instrumentation system is briefly reviewed in a historical perspective. Key research areas and some major achievements are outlined, and the prospects of the observatory as (currently) part of the LPI Astro Space Center are examined."
Dagkesamanskii, Rustam D (2009). "The Pushchino Radio Astronomy Observatory of the P N Lebedev Physical Institute Astro Space Center: yesterday, today, and tomorrow" (A very brief history of radio astronomy in Russia (formerly Soviet)). Physics-Uspekhi. 52 (11): 1159. Bibcode:2009PhyU...52.1159D. doi:10.3367/UFNe.0179.200911i.1225. Retrieved 2010-04-03.

UFN, 2009, Volume 179, Number 11, Pages 1225–1235

[mwQg] Dagkesamanskii, Rustam D (2009). "The Pushchino Radio Astronomy Observatory of the P N Lebedev Physical Institute Astro Space Center: yesterday, today, and tomorrow" (A very brief history of radio astronomy in Russia (formerly Soviet)). Physics-Uspekhi. 52 (11): 1159. Bibcode:2009PhyU...52.1159D. doi:10.3367/UFNe.0179.200911i.1225. Retrieved 2010-04-03.

[mwUQ] UFN, 2009, Volume 179, Number 11, Pages 1225–1235

[PSC-page-2] 1 2 3 4 Pushchino Scientific Centre, Pushchino, Moscow Region, 142290, Russia (2001). "Pushchino Radio Astronomy Observatory". PRAO/ASC/LPI/RAS. Retrieved 2010-04-03.

[3] Shabanova, Tatiana V. (1995). "Evidence for a Planet around the Pulsar PSR B0329+54". The Astrophysical Journal. 453: 779. Bibcode:1995ApJ...453..779S. doi:10.1086/176440.