Skip to main content

Thank you for visiting You are using a browser version with limited support for CSS. To obtain the best experience, we recommend you use a more up to date browser (or turn off compatibility mode in Internet Explorer). In the meantime, to ensure continued support, we are displaying the site without styles and JavaScript.

  • NEWS

‘The most terrifying moments’: India counts down to risky Moon landing

The ISRO Geosynchronous Satellite launch Vehicle MkIII carrying Chandrayaan-2.

Chandrayaan-2 launches from the Satish Dhawan Space Centre, Sriharikota, in July.Credit: AP/Shutterstock

After countless setbacks and delays, India will attempt to set a lander down on the Moon in the early hours of 7 September Indian time. If the landing is successful, the nation will be only the fourth to achieve such a feat.

Chandrayaan-2 shot into space six weeks ago — more than a year behind schedule — comprising an orbiter and a lander, Vikram, loaded with a six-wheeled rover. The mission’s main aims are to investigate the unexplored lunar south pole and provide the most detailed maps yet of sources of water on the Moon.

But before the exploration can begin, India’s space agency (ISRO) will have to put its faith in Vikram’s autonomous landing system, which will attempt to place the four-legged lander gently on the Moon’s surface. Although ISRO crash-landed an impact probe, released by the Chandrayaan-1 lunar orbiter, on the surface in 2008, the Chandrayaan-2 mission is the agency’s first attempt at a ‘soft’ landing.

When Vikram is 35 kilometres above the Moon’s surface, its thrusters will fire to slow the craft’s descent from a speed of 6 kilometres a second to almost zero. Although Vikram is designed to select a landing site free of large boulders, the team’s engineers worry that if the site is slightly sloping, or pockmarked with small rocks, the craft could topple, ending its mission.

The agency’s chief, Kailasavadivoo Sivan, said at a press conference last month that the automated landing will be the “most terrifying moments” for the organization.

Roving south

If the touchdown is successful, however, Vikram will be the first craft to land near the lunar south pole, where it will release the rover Pragyan, which can travel for up to 500 metres. Previous US, Soviet and Chinese missions have landed nearer the equator.

“The Chandrayaan-2 landing site will be in completely new terrain,” says Brett Denevi, a planetary scientist at Johns Hopkins University Applied Physics Laboratory in Laurel, Maryland.

The most important reason for choosing the site is the high likelihood of finding water there, says Mylswamy Annadurai, a former director of the ISRO Satellite Centre (now the U R Rao Satellite Centre) in Bengaluru, who led the Chandrayaan-2 project until he retired in July 2018.

Ever since Chandrayaan-1 detected signatures of frozen water on the Moon, scientists have been trying to identify deposits and calculate how much is there. This could help them to explain how water came to be on the Moon in the first place. Evidence gathered by Chandrayaan-1 and other spacecraft show there is water ice across the surface of south pole1,2, and possibly buried deposits too3.

Moon as viewed by Chandrayaan-2 LI4 Camera on 21 August 2019 19:03 UT

View of the Moon from one of Chandrayaan-2’s cameras.Credit: ISRO

The presence of water at the lunar south pole also makes it an attractive potential outpost for future astronaut missions, as does the fact the area is thought to be rich in minerals such as magnesium, iron, calcium and titanium. NASA is planning to send astronauts to the south pole by 2024. “There is a lot of international interest in the lunar south pole due to the resources it can provide,” says Denevi.

New instruments

Chandrayaan-2 carries 13 instruments from India and one from NASA, which is on the lander and will collect data to more precisely measure the distance from Earth to the Moon and better understand its orbit. Of the Indian instruments, eight are on the orbiter, which separated from the lander on 2 September and is currently circling the Moon.

Denevi says she’s most excited about the orbiter’s imaging infrared spectrometer, which will map light reflected off the lunar surface over a wide range of wavelengths. This information can be used to identify and quantify surface water, which absorbs light strongly at certain wavelengths. Although Chandrayaan-1 provided some of the first key evidence for water on the Moon, its wavelength range did not cover the full absorption band, making it difficult to calculate the abundance and distribution of water on the Moon4. “As far as I know, this will be the first time this full wavelength region has been covered,” Denevi says.

The same instrument will also make the first direct measurements of volatile substances, such as hydrogen and carbon dioxide, near the poles. This will help researchers to investigate the source, composition and distribution of volatiles in these regions, says Ryan Watkins, a lunar scientist at the Planetary Science Institute in Tucson, Arizona.

The orbiter is also carrying a radar operating at two frequencies to detect water ice inside permanently shadowed craters, and to map the thickness and electrical conductivity of lunar rocks, says Watkins. This will be the first radar mapper of this type to orbit the Moon, she says.

A probe on Vikram will also measure a strange phenomenon known as ‘Moonquakes’. The Moon has become some 50 metres ‘skinnier’ over the past several hundred million years, and, as it shrinks, its brittle crust breaks and generates quakes. Annadurai says there is much about the Moon’s core that is unknown, such as its size and composition, and Vikram’s data could help researchers to better understand it.

Although Vikram, which carries three instruments, and the Pragyan rover, which has two, are designed to last only one lunar day — about 14 Earth days — Sivan says they will be able to collect a wealth of data in that time. “The entire world is waiting for our data,” he says.

Nature 573, 13-14 (2019)



  1. Li, S. et al. Proc. Natl Acad. Sci. USA 115, 8907–8912 (2018).

    PubMed  Article  Google Scholar 

  2. Fisher, E. et al. Icarus 292, 74–85 (2017).

    Article  Google Scholar 

  3. Rubanenko, L., Venkatraman, J. & Paige, D. A. Nature Geosci. 12, 597–601 (2019).

    Article  Google Scholar 

  4. Pieters, C. et al. Science 326, 568–572 (2009).

    PubMed  Article  Google Scholar 

Download references


Nature Careers


Nature Briefing

Sign up for the Nature Briefing newsletter — what matters in science, free to your inbox daily.

Get the most important science stories of the day, free in your inbox. Sign up for Nature Briefing


Quick links