Yesterday at 9:00 PM, Australian Eastern Standard Time, the Ingenuity helicopter – which landed on Mars with the Perseverance rover in February – took off from the surface of Mars. More importantly, it floated for about 30 seconds, ten feet above the surface and came right back down.
It may not sound like a huge achievement, but it is. Ingenuity’s Flight is the first powered flight of an airplane on another planet. It marks a milestone in the story of human space exploration.
While the Apollo 11 spacecraft famously landed on the Moon, upon relaunch it simply had to leave the Moon’s gravity and return to Earth. However, to keep flying in the environment of a world without atmosphere is a different story.
It took six years to make Ingenuity’s now historic helicopter. We can understand why, once we understand the complexity of what was required.
Today I witnessed the history. Now you can too. You are watching a video of the #MarsHelicopterfirst flight – a real “Wright Brothers” moment.
Check it all out:
✅ Spin-up
✅ Take off
✅ Move
✅ Turn
✅ LandingRead more: https://t.co/FIsf5RfHGjpic.twitter.com/hucsBY2RDE
– NASA’s Persistence Mars Rover (@NASAPersevere) April 19, 2021
Why local flights on Mars are so important
There are several technological challenges of conducting a helicopter flight on another world. First and foremost, helicopters need an atmosphere to fly.
A helicopter’s blades or “rotors” must spin fast enough to generate a force called “lift”. But lift can only be generated in the presence of some kind of atmosphere. Although Mars has an atmosphere, it is much, much thinner than Earth’s – about 100 times thinner, in fact.
Flying Ingenuity in Mars’ atmosphere is therefore the equivalent of flying a helicopter on Earth at an altitude of 30,000 feet. For reference, commercial planes fly between 30,000-40,000 feet above the Earth’s surface, and the tallest we’ve ever been in a helicopter on Earth is 42,000 feet.
To test the craft on Earth, a pressurized chamber was needed from which a lot of air would have been extracted to simulate the Martian atmosphere.
Then there is the gravity of Mars, which is about one third of the gravity on Earth. This actually gives us a small advantage. If Mars had the same atmosphere as Earth, the lower gravity means we could lift Ingenuity with less force than we would need here.
But while Mars’ gravity works in our favor, it is offset by the lack of atmosphere.
Ingenuity’s success marks the first time such a flight has even been attempted outside of Earth. And the reason for this could be simply that, as outlined above, this task is very, very difficult.
Read more: ‘7 Minutes of Terror’: A Look at the Technology That Will Need Persistence to Survive the Mars Landing
Advanced manufacturing
There are two main ways Ingenuity was able to overcome the obstacles in the atmosphere of Mars. First, to generate lift, the two rotors (made of carbon fiber) had to spin much faster than any helicopter on Earth.
On Earth, most helicopters and drones have rotors spinning at about 400-500 revolutions per minute. The Ingenuity’s rotor turned at approximately 2,400 revolutions per minute.
It also has a clear airplane to wingspan ratio. Although Ingenuity’s body is about the size of a tissue box, the blades are 1.2m tip to tip.
Even sending the start-of-flight signal required a range of advanced technology. While radio signals only take a few minutes to travel between Earth and Mars, there was still a delay of hours for those signals to reach the helicopter.
This makes sense when you consider the journey those signals must take – from a computer on Earth, to a satellite dish, to the Mars Reconnaissance Orbiter, to the Perseverance rover, and then, finally, to the helicopter.
Remote-controlled flight on Mars
Ingenuity is what we call a “technology demonstrator”. Its sole purpose is simply to prove that it can complete a series of simple missions. In the coming weeks, the helicopter will operate three or four more flights, the most adventurous of which will involve take-off and travel approximately 300 meters from Perseverance.
Data extracted from the flights is analyzed and used as vital input for future designs of more advanced aircraft. Once this technology is applied, the potential will be enormous.
Drones and helicopters operating on Mars can act as scouts, checking the land in front of a rover to confirm that it is safe to travel there. Such planes could even help search for water and life on the surface of Mars.
And in 2035, the first humans are expected to land on Mars. Chances are, these crews will be trained in how to fly planes locally and in real-time, surveying the land for obstacles and dangerous terrain that could harm people or damage suits, planes or robbers.
A tribute to the past, with the future in sight
As a moving tribute to Earth’s first powered flight, scientists at the NASA Jet Propulsion Laboratory added a historical artifact to the Mars helicopter. A small piece of the wing of the Wright brothers’ 1903 flyer is attached to a cable under one of the solar panels.
This flight history item is the second piece of a terrestrial plane going into space; a similar piece of the wing was brought to the moon during the Apollo missions.
Missions are already breaking the barriers of powered flight on other worlds. In particular, the Dragonfly helicopter is planned to fly above the surface of Titan, one of Saturn’s moons, with arrival scheduled for 2034.
Perhaps it will also take a bit of Earth history for the ride as we continue our exploration of other planetary bodies, world by world. 
“We’ve been talking about our Wright brothers’ moment for so long. And here it is. ‘
MiMi Aung, #MarsHelicopter Project Manager, takes a moment to update the @NASAJPL team following the news of the successful Ingenuity test flight: pic.twitter.com/qeoQnOdXiK
– NASA (@NASA) April 19, 2021
This article by Gail Iles, Senior Lecturer in Physics, RMIT University, has been republished from The Conversation under a Creative Commons license. Read the original article.