The far side of the moon and distant Earth, imaged by China's Chang'e 5 T1 mission service module in 2014. The Chang'e 4 mission will launch toward the far side on Dec. 7, 2018.

China is getting set to launch the first-ever surface mission to the moon's far side.

The robotic Chang'e 4 mission is scheduled to launch atop a Long March 3B rocket on Friday (Dec. 7) at around 1:30 p.m. EST (1830 GMT; 2:30 a.m. on Dec. 8 local China time).

If all goes according to plan, Chang'e 4's lander-rover duo will touch down within the moon's South Pole‐Aitken (SPA) basin after a 27-day flight, then study both the surface and subsurface of this region. [China's Moon Missions Explained (Infographic)]

Both the lander and the rover were designed as backups for China's successful Chang'e 3 mission, which put a lander and a rover named Yutu down on the moon in December 2013.

As a prelude to the Chang'e 4, China launched the Queqiao relay satellite this past May. Queqiao is now positioned at the Earth-moon L2 Lagrange point — a place where the spacecraft can handle communications between ground controllers and the lander-rover mission on the far side.

China's Yutu moon rover, photographed on the lunar surface by the Chang'e 3 lander on Dec. 16, 2013. The Chang'e 4 mission to the lunar far side, which is scheduled to launch on Dec. 7, 2018, was designed as a backup for Chang'e 3. (Image credit: CASC/China Ministry of Defense)

Lots of scientific gear

Chang'e 4 is expected to touch down in Von Kármán Crater, within the SPA basin.

In a study published last month, Yingzhuo Jia, of the University of Chinese Academy of Sciences, and colleagues laid out the mission's chief scientific objectives. (Jia is also with the State Key Laboratory of Space Weather, National Space Science Center of the Chinese Academy of Sciences.)

The mission, Jia and team members wrote, aims to complete:

A low-frequency radio-astronomical study on the lunar surface;

A shallow-structure investigation at the lunar far side within the roving area;

Topographic and mineralogical composition studies of the lunar far side within the rover's patrol area.

The radio-astronomical study is particularly intriguing. The lunar far side always faces away from Earth, so it's is free from interference from our planet's ionosphere, human-made radio frequencies and auroral radiation noise. Solar radio emission is also blocked during the lunar night.

"Hence, the lunar far side has been believed as the best place for the low-frequency radio astronomical observation," the researchers wrote in the recent paper.

The paper also detailed the eight scientific payloads toted by the mission.

An artist's illustration of China's Queqiao relay satellite, which will relay data between controllers on Earth and China's Chang'e 4 lander-rover pair on the moon's far side. Queqiao launched in May of 2018; the Chang'e 4 duo will lift off on Dec. 7. (Image credit: CNSA)

The Chang'e 4 lander carries the Landing Camera (LCAM), the Terrain Camera (TCAM), the Low Frequency Spectrometer (LFS), and the Lunar Lander Neutrons and Dosimetry (LND), which was provided by Germany. The rover has four instruments as well: the Panoramic Camera (PCAM), the Lunar Penetrating Radar (LPR), the Visible and Near-Infrared Imaging Spectrometer (VNIS), and the Advanced Small Analyzer for Neutrals (ASAN), which was provided by Sweden.

The LFS was newly developed for Chang'e 4 lander; the other native Chinese payloads are inherited instruments from Chang'e 3, the researchers wrote.

The Queqiao relay satellite also carries an instrument called the Netherlands-China Low-Frequency Explorer (NCLE). The NCLE and the lander's LFS will carry out joint low-frequency radio-astronomical observations. [Moon Master: An Easy Quiz for Lunatics]

The LPR instrument will likely be able to detect subsurface structure on the robot's patrol route, and to detect the thickness and structure of the lunar regolith. The device is a nanosecond impulse radar with bistatic antennas.

It works like this: An ultra-wideband nanosecond impulse is produced by a transmitter, and then sent through the transmitting antenna down to lunar surface. The echo signal from the underground target is received by the receiving antenna, amplified in the receiver and then restored as a data record.

Biological experiment, too

According to a story earlier this year by China's state-run Xinhua news agency, Chang'e 4 will also carry a tin containing seeds of potato and arabidopsis, a small flowering plant related to cabbage and mustard. It may also tote silkworm eggs.

This "lunar mini biosphere" experiment was designed by 28 Chinese universities, led by southwest China's Chongqing University. The cylindrical tin, made from special aluminum alloy materials, weighs roughly 6.6 lbs. (3 kilograms).

A view of the moon's South Pole‐Aitken basin. (Image credit: NASA/Goddard Space Flight Center)

Impact basin

The SPA basin is the largest and oldest impact basin of the moon. Although the terrain is low, this region is not filled with mare basalts as other moon basins are, Jia and colleagues noted, suggesting that it may have a special thermal history and unique evolution features.

Studying the materials in the region could therefore help reveal the composition of the crust and even the mantle of the moon, the researchers wrote.

China's next lunar probe, Chang'e 5, is designed to bring select samples from the moon back to Earth. It builds upon a progression of Chinese moon explorers: the Chang'e 1 and Chang'e 2 orbiters in 2007 and 2010, respectively, Chang'e 3 in December 2013, and Chang'e 5 T1, which launched a test capsule on an around-the-moon journey in October 2014. The capsule parachuted safely back to Earth eight days after liftoff.

Leonard David is author of "Mars: Our Future on the Red Planet," published by National Geographic. The book is a companion to the National Geographic Channel series "Mars." A longtime writer for Space.com, David has been reporting on the space industry for more than five decades. Follow us @Spacedotcom, Facebook or Google+. This version of the story published on Space.com.