In the wilderness of Daocheng, southwest China’s Sichuan Province, 4,400 meters above sea level, Chinese scientists are constructing a cosmic ray observation station on an area equivalent to 200 soccer fields.
Huge rocks left from the Ice Age have been blasted. Different detectors are being installed to form a huge “net” to catch the particles generated by cosmic rays in the atmosphere, to help scientists study both the micro and the macro worlds in the universe, Xinhua reported.
Three huge underground pools, more than triple the size of the Water Cube (National Aquatic Center) in Beijing, will hold detectors to collect high-energy photons generated by remote celestial bodies. Surrounding the pools, 12 telescopes will be erected to conduct high-precision measurement of cosmic rays with the highest energy.
Construction of the first half of the observation station, known as Large High-Altitude Air Shower Observatory (LHAASO), is due to be finished at the end of this year, and the whole project completed at the end of 2020, said Cao Zhen, chief scientist of LHAASO and a researcher at the Institute of High Energy Physics (IHEP) of the Chinese Academy of Sciences, the report said.
Discovered in 1912, cosmic rays are still largely an enigma. They are direct samples of matter from outside the solar system. Physicists are still pondering where they come from and how they can be accelerated to ultra-high energies.
Now scientists have found most cosmic rays are atomic nuclei. All the natural elements in the periodic table are present in cosmic rays. About 90% of them are the nuclei of hydrogen (protons); about 9% are helium nuclei (alpha particles); and the other heavier elements, electrons, gamma rays, neutrinos and antimatter particles make up the other 1%.
Since most cosmic rays are charged, their paths through space are deflected by magnetic fields. On their journey to Earth, the magnetic fields of the galaxy, the solar system, and the earth scramble their flight paths so much that we can no longer know exactly where they came from.
Many countries have invested heavily in the study of cosmic rays. China, the United States, Russia, Japan, Germany and other countries have established observation stations.
China’s cosmic ray detection began in the early 1950s. Chinese scientists built the country’s first cosmic ray observatory on a 3,200-meter-high mountain in southwest China’s Yunnan Province. Its scientific equipment was advanced by international standards at the time.
However, the “Cultural Revolution” from 1966 to 1976 hindered the research. When Chinese scientists returned to the study, they found they lagged far behind their peers abroad.
After China launched its reform and opening-up, Tan Youheng, a researcher with the IHEP, went to study in Japan. He was inspired by the air shower array technology for cosmic ray detection, and determined to conduct similar work in China.
After returning to China, he applied to build a world-class cosmic ray observation base.
Under the leadership of Tan and other scientists, China began to build an international cosmic ray observatory in Yangbajing Town, Tibet, at an altitude of 4,300 meters, in 1989.
Chinese scientists have since cooperated with Japanese and Italian scientists to conduct observations in Yangbajing.
This year, the China-Japan collaboration discovered the highest-energy cosmic gamma rays ever observed, opening a new window on the extreme universe.
When Cao Zhen was working in Yangbajing, he began to draw up a plan for a new-generation cosmic ray observation base. He aimed to make it a world-leading observatory.
He and his team spent five years investigating potential sites in Tibet, Qinghai, Yunnan and Sichuan.
Daocheng was eventually chosen due to its high altitude, convenient transport, stable power supply, sufficient water resources and support from the local government.
Infrastructure construction started in July 2016, and the building of the observatory officially began in June 2018.
The main objective of LHAASO is to search for the origin of cosmic rays, and study their acceleration and transmission mechanisms, said Cao.
In the second huge pool of LHAASO, which is 5 meters below ground, water Cherenkov detectors have been installed to form an array, and they will be submerged in 100,000 tonnes of the purest water in the world.
“The water comes from nearby lakes and rivers and has gone through strict purification. Only transparent pure water can make the detectors catch the signals generated by high-energy particles clearly,” said Chen Mingjun, deputy director of the Cherenkov detector array.
After being on the plateau for a year, Chen lost more than 15 kg due to the hard work, but he said he is lucky to participate in such a grand project.
Foreign peers have been amazed at the speed of LHASSO’s construction. It’s not only a result of the scientists’ efforts, but also of the complete industrial production capacity of China. It’s the embodiment of China’s overall national strength, said Cao.
He said the LHASSO project has drawn world attention. Scientists from Russia, Switzerland, Poland, the Czech Republic and other countries hope to bring their scientific equipment to the observatory.
“After completing the LHASSO project, China is expected to lead the world in the field of cosmic ray research,” Cao said.