Neil Armstrong took his historic “one small step” on the Moon in 1969. And just three years later, the last Apollo astronauts left our celestial neighbor. Since then, hundreds of astronauts have been launched into space, but mainly to the Earth-orbiting International Space Station. None has, in fact, ventured more than a few hundred kilometers from Earth.
The US-led Artemis program, however, aims to return humans to the Moon this decade – with Artemis 1 on its way back to Earth as part of its first test flight, going around the Moon.
The most relevant differences between the Apollo era and the mid-2020s are an amazing improvement in computer power and robotics. Moreover, superpower rivalry can no longer justify massive expenditure, as in the Cold War competition with the Soviet Union. In our recent book “The End of Astronauts”, Donald Goldsmith and I argue that these changes weaken the case for the project.
The Artemis mission is using Nasa’s brand new Space Launch System, which is the most powerful rocket ever – similar in design to the Saturn V rockets that sent a dozen Apollo astronauts to the Moon. Like its predecessors, the Artemis booster combines liquid hydrogen and oxygen to create enormous lifting power before falling into the ocean, never to be used again. Each launch therefore carries an estimated cost of between $2 billion (£1.7 billion) and $4 billion (£3.4 billion).
This is unlike its SpaceX competitor “Starship”, which enables the company to recover and reuse the first stage.
The benefits of robotics
Advances in robotic exploration are exemplified by the suite of rovers on Mars, where Perseverance, Nasa’s latest prospector, can drive itself through rocky terrain with only limited guidance from Earth. Improvements in sensors and artificial intelligence (AI) will further enable the robots themselves to identify particularly interesting sites, from which to gather samples for return to Earth.
Within the next one or two decades, robotic exploration of the Martian surface could be almost entirely autonomous, with human presence offering little advantage. Similarly, engineering projects – such as astronomers’ dream of constructing a large radio telescope on the far side of the Moon, which is free of interference from Earth – no longer require human intervention. Such projects can be entirely constructed by robots.
Instead of astronauts, who need a well-equipped place to live if they’re required for construction purposes, robots can remain permanently at their work site. Likewise, if mining of lunar soil or asteroids for rare materials became economically viable, this also could be done more cheaply and safely with robots.
Robots could also explore Jupiter, Saturn and their fascinatingly diverse moons with little additional expense, since journeys of several years present little more challenge to a robot than the six-month voyage to Mars. Some of these moons could in fact harbor life in their sub-surface oceans.
Even if we could send humans there, it might be a bad idea as they could contaminate these worlds with microbes form Earth.
The Apollo astronauts were heroes. They accepted high risks and pushed technology to the limit. In comparison, short trips to the Moon in the 2020s, despite the $90-billion cost of the Artemis program, will seem almost routine.
Something more ambitious, such as a Mars landing, will be required to elicit Apollo-scale public enthusiasm. But such a mission, including provisions and the rocketry for a return trip, could well cost Nasa a trillion dollars – questionable spending when we’re dealing with a climate crisis and poverty on Earth. The steep price tag is a result of a “safety culture” developed by Nasa in recent years in response to public attitudes.