Having demonstrated that it has the operational capability to transport humans safely to the moon and back, the United States is moving on to its next major aim: It wants nuclear reactors in orbit and on the lunar surface by 2030. For such a feat, the National Aeronautics and Space Administration will have to work in conjunction with the Department of Defense and the Department of Energy.
In a post on X, the White House Office of Science and Technology Policy (OSTP) unveiled a document with new guidelines for federal agencies to establish the space nuclear technology road map for the coming years. This, they say, will ensure “US space superiority.”
At present, space instruments use solar power to operate. However, this is considered impractical for more complex purposes. Although technically there is always sunlight, the power is intermittent and almost always requires bulky batteries to store it.
Reactors produce fairly continuous energy for years through nuclear fission. They can also be used for so-called nuclear electric propulsion. Continuous output makes them the most viable option for lunar base subsistence, but they can also allow spacecraft to undertake long or complex missions without worrying about depleting a limited supply of chemical fuel.
Nuclear technology, in short, makes it possible to go farther, with more payload, for longer, and with fewer constraints.
According to the memorandum, the US goal is to put a medium-power reactor in orbit by 2028, with a variant designed for nuclear electric propulsion, and a first functional large reactor on the surface of the moon by 2030. To achieve this, both NASA and the Pentagon will develop energy technologies in parallel, using the current strategy of competition among contractors.
The reactors will have to be modular and scalable, and will have to include applications for both future life on the moon and space propulsion. For its part, the DOE will have to ensure that these projects have the fuel, infrastructure, and safety features necessary to achieve their objectives. In addition, the agency will evaluate whether the industry has the capacity to produce up to four reactors in five years.
The plan contemplates technologies that produce at least 20 kilowatts of electricity (kWe) for three years in orbit and at least five years on the lunar surface. In the meantime, they should have a design capable of raising power to 100 kWe. The first designs should arrive within a year.
Finally, the order tasks the OSTP with creating a road map for the initiative, noting obstacles and recommendations for addressing them.
“Nuclear power in space will give us the sustained electricity, heating, and propulsion essential to a permanent presence on the moon, Mars, and beyond,” OSTP posted. For his part, NASA administrator Jared Isaacman posted, “The time has come for America to get underway on nuclear power in space.” The message was followed by an emoji of a US flag.
The plan provides a common framework for each agency to work within. In the background, the race for space infrastructure is evidence of technological competition with China, which is also seeking advanced energy capabilities for the moon.
This story originally appeared in WIRED en Español and has been translated from Spanish.
