Washington, November 17 (ANI): Astronomers will tie together the largest collection of the world's radio telescopes ever assembled to work as a single observing tool in a project aimed at improving the precision of the reference frame scientists use to measure positions in the sky.
For 24 hours, starting November 18, and ending November 19, 35 radio telescopes located on seven continents will observe 243 distant quasars.
The quasars, galaxies with supermassive black holes at their cores, are profuse emitters of radio waves, and also are so distant that, despite their actual motions in space, they appear stationary as seen from Earth.
This lack of apparent motion makes them ideal celestial landmarks for anchoring a grid system, similar to earthly latitude and longitude, used to mark the positions of celestial objects.
Data from all the radio telescopes will be combined to make them work together as a system capable of measuring celestial positions with extremely high precision.
The technique used, called very long baseline interferometry (VLBI), has been used for decades for both astronomical and geodetic research.
However, no previous position-measuring observation has used as many radio telescopes or observed as many objects in a single session.
The previous record was a 23-telescope observation.
The new reference frame uses a set of 295 quasars to define positions, much like surveyor's benchmarks in a suburban subdivision.
Because even with 35 radio telescopes around the world, there are some gaps in sky coverage, the upcoming observation will observe 243 of the 295.
By observing so many quasars in a single observing session, problems of linking positions from one observing session to another can be avoided, according to the astronomers.
The result will be a much stronger, more precise, reference grid.
Telescopes in Asia, Australia, Europe, North America, South America, Antarctica, and in the Pacific will participate.
Improving the celestial positional grid will allow astronomers better to pinpoint the locations and measure the motions of objects in the sky.
As astronomers increasingly study objects using multiple telescopes observing at different wavelengths, such as visible light, radio, infrared, the improved positional grid will allow more accurate overlaying of the different images.
The improved celestial reference frame also strengthens a terrestrial reference frame used for radio-telescope measurements that contribute to geophysical research. (ANI)