CHINA’S "Little Bee" is busy searching for gamma-ray bursts, the strongest explosions in the universe.
The formal name of the square-shaped probe, set atop China’s Tiangong-2 space lab, is POLAR (an abbreviation of Polarimetry of Gamma-ray Bursts).
The device will help open a new window in the study of gamma-ray astronomy, says Zhang Shuangnan, principal investigator on the POLAR project and a chief scientist at the High Energy Physics Institute of the Chinese Academy of Sciences.
Tiangong-2 was launched in September, and last week the Shenzhou-11 spacecraft took two astronauts to a 30-day mission – China’s longest manned mission to date – in the space lab where they will prepare for the construction of a more complicated space station, conducting more than a dozen scientific experiments, most of them in cutting-edge fields of exploration.
POLAR is the only international cooperation project on Tiangong-2, involving scientists from the University of Geneva, the Paul Scherrer Institute in Switzerland and Poland’s Institute of Nuclear Physics.
"The 30-kilogram device can be regarded as a telescope," said Zhang, "but it is different from other telescopes, as it consists of 1,600 sensitive components to detect the polarization of gamma-ray bursts. They are like the 1,600 facets in the compound eyes of bees. That’s why we call it Little Bee."
"We hope to obtain accurate polarization information of the gamma-ray bursts for the first time ever to better understand the process of how the violent explosions happen," Zhang says.
Gamma-ray bursts are extremely energetic explosions that have been observed in distant galaxies. They are the brightest electromagnetic events known to occur in the universe. Bursts can last from milliseconds to several hours.
The intense radiation of most observed bursts is believed to be released during a supernova or hypernova as a rapidly rotating, high-mass star collapses to form a neutron star, quark star, or black hole. A subclass of bursts appear to originate from a different process: the merger of binary neutron stars.
Another aim of "Little Bee" is to determine whether gamma-ray bursts are related to gravitational waves.
"If we can detect gamma-ray bursts at the same time gravitational waves happen, it will help us better understand gravitational waves. That will be very interesting," Zhang says.
He estimates that "Little Bee" can detect about 100 gamma-ray bursts during its two-year operating period.
Zhang also wants to try something outside the plan.
He and his team have succeeded in locating signals from the Crab Pulsar neutron star by analyzing the data sent back by POLAR. (Xinhua)
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