China
2024.06.02 06:36 GMT+8

China's Chang'e-6 lands on far side of moon to collect samples

Updated 2024.06.02 18:31 GMT+8
CGTN

China's Chang'e-6 probe landed on the far side of the moon on Sunday at 6:23 a.m. Beijing Time, aiming to collect samples from the South Pole-Aitken (SPA) Basin within two days, which will be brought back to Earth, according to the China National Space Administration (CNSA). 

Supported by the Queqiao-2 relay satellite, the lander-ascender combination of the Chang'e-6 probe landed at the designated landing area in the SPA Basin. Video footage of the lunar landing released by the CNSA is shown below.

The Chang'e-6 mission has made technological breakthroughs, including lunar retrograde orbit design and control technology. It will go on to complete key tasks such as the intelligent, rapid sampling from the lunar far side and lunar surface take-off, said the CNSA. 

The probe of Chang'e-6, which is named after the Chinese moon goddess, consists of an orbiter, a returner, a lander and an ascender. Since its launch on May 3, it has gone through various stages such as Earth-moon transfer, near-moon braking, lunar orbiting and landing descent. The lander-ascender combination separated from the orbiter-returner combination on May 30.

An illustration shows the lander-ascender combination of China's Chang'e-6 probe landing in the South Pole-Aitken (SPA) Basin on the far side of the moon, June 2, 2024. /CNSA

Lunar landing

The landing site of the Chang'e-6 is at an impact crater known as the Apollo Basin, located within the SPA Basin. The choice was made for the Apollo Basin's potential value for scientific exploration, as well as the conditions of the landing area, including communication and telemetry conditions and the flatness of the terrain, said Huang Hao, a space expert from the China Aerospace Science and Technology Corporation (CASC).

At 6:09 a.m. on Sunday, the lander fired its 7,500-newton-thrust engine to slow down and began to descend from about 15 kilometers above the lunar surface. In this process, the cameras on the lander snapped pictures of the landing area and transmitted them to computers on the lander to identify possible hazards on the surface, such as large rocks, so that the craft could maneuver to avoid them.

An animation shows how the Queqiao-2 relay satellite works. /CMG

At about 100 meters above the lunar surface, the combination suspended its descent and hovered for a moment to conduct accurate detection of smaller obstacles and determine the final landing spot before continuing to descend at a slower, steady speed, said the CNSA. 

The Chang'e-6 probe faces a different terrain to the Chang'e-5 sample mission. To sample-retrieve from the lesser-known far side, the probe needs a relay satellite for communication and needs to be even more efficient and time-sensitive.

"Though the far side of the moon is more rugged, we can choose a relatively better place to land," Lu Yuntong from the China Aerospace Science and Technology Corporation told CGTN.

An illustration shows the Chang'e-6 probe's elliptical orbit around the moon in different periods. /CMG

International payloads

The Chang'e-6 probe carried four international scientific payloads.

They are the DORN (Detection of Outgassing Radon) from the French Space Agency, NILS (The Negative Ions at the Lunar Surface) from the European Space Agency, as well as a retroreflector from Italy. These three instruments will carry out exploratory scientific tasks on the far side of the moon.

The DORN is to study how radon, a noble gas, escapes from the lunar regolith, and how this radioactive gas and other forms of matter like water are transported in the moon's exosphere. The NILS will be used to measure solar winds that reflect from the lunar surface upon reaching the moon, while the laser retroreflector mainly aims to measure the distance between Earth and the moon.

The probe also carried a cube satellite from Pakistan known as ICUBE-Q, which separated from the Chang'e-6 orbiter on May 8 to carry out exploration activities, such as capturing images of the moon.

Sampling process

Due to the moon's obstruction, the Earth-moon communication window period on the far side of the moon, even with the help of the Queqiao-2 relay satellite service, is still shorter than that on the near side. 

Chang'e-6 is poised for a faster sampling process compared to its predecessor. It's expected to take roughly 14 hours, a significant reduction from the 22 hours required by Chang'e-5. About 1,000 instructions were sent during the entire sampling process of Chang'e-5 but for Chang'e-6, the number is expected to be reduced to about 400.

As it is scheduled to complete sampling in around two days after landing, Chang'e-6 has adopted two methods of moon sampling: using a drill to collect subsurface samples and grabbing samples on the surface with a robotic arm.

A Long March-5 rocket, carrying the Chang'e-6 spacecraft, blasts off from its launchpad at the Wenchang Space Launch Site in south China's Hainan Province, May 3, 2024. /CNSA

To guarantee a smooth sampling process on the moon, the Chang'e-6 probe development team, led by space expert Jin Shengyi from the CASC, built a meticulous simulation lab in advance. The lab replicates the lunar landing site, complete with environment, rock distribution and lunar soil conditions based on Chang'e-6's exploration data. By simulating the environment, the team can develop and verify sampling strategies and equipment control procedures, ensuring the accuracy of instructions sent to the probe.

In a major leap for lunar exploration, Chang'e-6 boasts an intelligent sampling process that allows the probe to autonomously execute instructions and make real-time decisions based on sensor data, reducing the need for constant communication with Earth. 

Essentially, Chang'e-6 can break down complex instructions into smaller actions, verify their success using on-board sensors, and adjust its approach as needed without waiting for further commands from mission control. This significantly streamlines the sampling process and minimizes delays caused by Earth-moon signal lag.

(CGTN's Wu Lei and Lu Lidan also contributed to the story.)

Read More:

China's lunar exploration: What to expect from Chang'e-6 mission

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