The Tianwen-2 mission was launched using a Long March 3B rocket from the Xichang Satellite Launch Centre located in China’s Sichuan province, as reported by the China National Space Administration. The launch occurred at 1:31 am local time, which corresponds to 3:31 am AEST.

Like Tianwen-1, which lifted off in July 2020 with two aims — delivering an orbiter and a rover to Mars — Tianwen-2 has two goals.

The mission’s initial goal is to fly by and collect the country’s first samples from an asteroid.

The space rock, called KamoÊ»oalewa or asteroid 2016 HO3, may be a chunk chipped off the moon, which has become a “quasi-satellite” near our planet.

The spacecraft will spend one year flying to the asteroid and another year orbiting and assessing potential landing sites.

This mission plans to return samples to Earth approximately 2 ½ years from now using a capsule. After this, the mission is set to travel for seven years to encounter an intriguing main belt comet known as 311P/Pan-STARRS for a flyby inspection.

Sometimes referred to as an active asteroid, the celestial object orbits between Mars and Jupiter and produces dusty, comet-like tails.

Both Kamoʻoalewa and 311P/Pan-STARRS are incredibly interesting targets that stem from populations of objects that, up until a couple of years ago, astronomers barely knew existed, said Dr Teddy Kareta, a postdoctoral associate of planetary science at Lowell Observatory in Flagstaff, Arizona.

“Now we get to study them up close in a kind of detail that will really revolutionise our understanding of them and objects like them,” Kareta said in an email.

“Plus, any time we see a new kind of Solar System object for the first time with a spacecraft … it’s like opening presents on your birthday.

“Whatever’s underneath the wrapping paper, it’s always exciting to see something for the first time and to try to do your best to understand it.”

Astronomers first discovered Kamoʻoalewa in 2016 using the Panoramic Survey Telescope and Rapid Response System, or Pan-STARRS, telescope in Hawaii.

Ben Sharkey, now a visiting senior faculty specialist at the University of Maryland, College Park, led a study published in November 2021 suggesting that the Ferris wheel-size asteroid may be a massive boulder ejected from the moon by an impact.

The name Kamoʻoalewa comes from a Hawaiian creation chant that alludes to an offspring travelling on its own.

It will be the smallest asteroid ever visited, measuring between 46 and 58 metres in diameter, Dr Patrick Michel, director of research exceptional class at the French National Centre for Scientific Research, said.

Michel also served as a co-investigator on missions by NASA and the Japan Aerospace Exploration Agency — OSIRIS-REx and Hayabusa2, respectively — that returned asteroid samples to Earth.

Bennu, the asteroid sampled by OSIRIS-REx, had a diameter similar to the height of the Empire State Building, or 492 metres.

Kamoʻoalewa is a quasi-satellite, a type of near-Earth asteroid that orbits the sun but sticks close to Earth, coming within about 9 million miles (14.5 million kilometres) of our planet.

“Until Ben Sharkey … saw that it reflected light like the Moon, we didn’t think there were chunks of the Moon out in near-Earth space,” Kareta said.

“The Moon’s covered in craters, but who knew that the violent formation of those craters might toss tennis-court-sized rocks seemingly intact that we could find and study thousands or millions of years later?”

Studying and sampling Kamoʻoalewa could help astronomers determine whether the space rock actually originated from the moon or if it just reflects light similarly, Kareta said.

Kareta is also involved with a study led by Sharkey that will use the James Webb Space Telescope to study Kamoʻoalewa in more detail next year.

“If it’s actually from the Moon, then we might be able to identify other lunar samples that have similar properties and help to get an idea of where it came from on the lunar surface,” Kareta said.

“If it just looks like the Moon but is actually from somewhere else, the sample will facilitate a radically more informed search for where KamoÊ»oalewa actually came from.”

The mission could also shed light on asteroids that can cause damage if they were to strike Earth.

Kamoʻoalewa is comparable in size to the object that devastated Tunguska in Siberia over a century ago, Michel said.

A roughly 30-metre-wide asteroid struck the Podkamennaya Tunguska River in a remote Siberian forest of Russia in 1908, according to The Planetary Society.

The event levelled trees and destroyed forests across 2150 square kilometres.

Orbiting and landing on such a small body is complicated, which is part of what makes the mission both interesting and risky, Michel said.

“To get into orbit, you really have to get very close, and even if you just follow it, the maneuvers remain very sensitive, because there’s really very little gravity and its rapid rotation forgives no mistakes,” Michel said.

“Plus, the plan is to get a sample, so there are not many areas where the probe can land safely.”

The space rock 311P/Pan-STARRS is one of the best-studied active asteroids, Kareta said.

“Even just (25) years ago, we didn’t know there were active asteroids at all — scientists thought that only icy comets from the outer Solar System could produce comet-like tails, but it turns out that a couple of dozen asteroids do so as well without much or any ice involved,” Kareta said.

Astronomers have come up with a number of hypotheses for why the object is throwing off dust, including posing the existence of pressure pockets that eject material and the idea that other objects could be impacting 311P/Pan-STARRS and releasing elements, Michel said.

Flying by the active asteroid could show exactly what processes are creating the dusty tails streaming from the object and might reveal possibilities scientists haven’t even considered, Kareta said.

“This will be the first time such an object is observed up close and we can determine which mechanism (there may be others) drives the activity,” Michel said.

The data gathered by Tianwen-2 could enhance a wide range of studies of objects within the inner solar system, which includes Mercury, Venus, Earth, Mars and the asteroid belt, Kareta said.

“There’s a tremendous amount we don’t know about either object,” Kareta said.

“I don’t think any spacecraft has ever gotten to its target and not found at least a few big surprises — I’m sure some of our current understanding for either object is completely wrong, and I’m excited to see how.”