Private companies find role in developing nuclear power for space travel
Nuclear-powered spacecraft could cut our travel time to Mars in half.
Space is about to go nuclear — at least if private companies get their way.
At the 23rd annual Commercial Space Transportation Conference (CST) in Washington, D.C., in January, a panel of nuclear technology experts and leaders in the commercial space industry spoke about developments of the technology that could propel future spacecraft faster and more efficiently than current systems can.
Nuclear technology has powered spacecraft such as NASA's Mars rovers, the Cassini mission and the two Voyagers that are currently exploring the outer reaches of our solar system. But those fuel sources rely on the passive decay of radioactive plutonium, converting heat from that process into electricity to power the spacecraft.
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Instead, the CST panelists discussed Nuclear Thermal Propulsion (NTP), a technology developed in the 1960s and '70s that relies on the splitting, or fission, of hydrogen atoms. Although fission is associated with more warlike images, the panel's experts emphasized the safety of nuclear thermal propulsion, which would use low-enriched uranium.
An NTP-powered spacecraft would pump hydrogen propellant through a miniature nuclear reactor core. Inside this reactor core, high energy neutrons would split uranium atoms in fission reactions; those freed neutrons would smack into other atoms and trigger more fission. The heat from these reactions would convert the hydrogen propellent into gas, which would produce thrust when forced through a nozzle.
This chain reaction is the key to NTP's power, panelist Venessa Clark, CEO of Atomos Space, a company that’s developing thermonuclear propulsion powered spacecraft to provide in-space transportation options to satellite operators, told Space.com. A soda-can-size fission reactor could propel humans to Mars in just three to four months, she said, about twice as fast as the currently estimated time it could take a chemically propelled ship to carry humans to the Red Planet.
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"The reason we want to use a reactor is we have a lot of power from [it], which is really what enables us to be so agile and move such heavy payloads so quickly," Clark said.
So where does the commercial sector fit in? According to Jeff Thornburg, CEO of Interstellar Technologies, an aerospace engineering company focused on propulsion, and another panelist, it's the speed that commercial ventures offer, which can get new technologies off the ground both literally and figuratively.
"I know how fast we've changed the dynamic and how we develop technologies for the commercial space sector for launch now, which didn't exist 20 years ago," Thornburg told Space.com. He wants to apply that same methodology to developing fast and efficient nuclear propulsion.
"I don't think the government's going to be able to move quickly enough to stay competitive in this technology area," Thornburg said. He noted that NASA is currently focused on its Artemis lunar program and launching to the moon doesn't necessarily require nuclear technology.
Sending astronauts to Mars and minimizing their time in a dangerous radiation environment however, may require a faster propulsion system, and that's what NTP technology might provide.
But the government still has to play some role, both Clark and Thornburg said. Government agencies like NASA and the military branches may be the first clients for these commercial companies. Clark noted NASA's recent pushes to partner with the private sector, such as its commercial lunar payload services program and its commercial crew program.
"Government players, NASA and also now the Air Force are looking at procuring services rather than funding the development of technology, which is really exciting for us," Clark said.
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JoAnna Wendel is a freelance science writer living in Portland, Oregon. She mainly covers Earth and planetary science but also loves the ocean, invertebrates, lichen and moss. JoAnna's work has appeared in Eos, Smithsonian Magazine, Knowable Magazine, Popular Science and more. JoAnna is also a science cartoonist and has published comics with Gizmodo, NASA, Science News for Students and more. She graduated from the University of Oregon with a degree in general sciences because she couldn't decide on her favorite area of science. In her spare time, JoAnna likes to hike, read, paint, do crossword puzzles and hang out with her cat, Pancake.
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newtons_laws Quote from article"Instead, the CST panelists discussed Nuclear Thermal Propulsion (NTP), a technology developed in the 1960s and '70s that relies on the splitting, or fission, of hydrogen atoms" Whoever wrote that needs to learn some basic nuclear physics. In nuclear thermal propulsion the atoms of a fissile heavy element (such as Uranium 235 in the designs mentioned) are split, hydrogen is the simplest and lightest of the elements and cannot be split (hydrogen atoms can however be joined together in the process of nuclear fusion, but that is a different process). Where hydrogen comes in is that in the NTP designs it is the propellant gas that is heated by the nuclear fission reactor to provide propulsion, hydrogen is chosen because being the lightest element it achieves the highest exhaust velocities.Reply -
Edward Coulter Agree with the first commenter. You can't fission hydrogen. The whole article requires review and a rewrite to get this weird nuclear concept clarified.Reply