NASA: The Propulsion We’re Supplying, It’s Electrifying

The Propulsion We’re Supplying, It’s Electrifying

Since the beginning of the space program, people have been captivated by big, powerful rockets—like NASA’s Saturn V rocket that sent Apollo to the lunar surface, or the Space Launch System that will produce millions of pounds of thrust as it sends Artemis astronauts back to the Moon.

But what if the most powerful propulsion system in NASA’s toolbox produces less than one pound of thrust while reaching speeds of up to 200,000 mph? What if it costs less, carries more, and uses less fuel?

This radical system is in-space electric propulsion. It can reduce the amount of fuel, or propellant, needed by up to 90% compared to chemical propulsion systems, saving millions in launch costs while providing greater mission flexibility.

Newton’s Third Law in Space

Chemical propulsion uses a fuel and an oxidizer, converting energy stored in the chemical bonds of the propellants, to produce a short, powerful thrust, or what we see as fire. It’s loud and exciting, but not all that efficient.

An electric propulsion system uses energy collected by either solar arrays (solar electric propulsion) or a nuclear reactor (nuclear electric propulsion) to generate thrust, eliminating many of the needs and limitations of storing propellants onboard.

That power is then converted and used to ionize—or positively charge—inert gas propellants like Xenon and Krypton (no, it’s not from Superman’s home planet). A combination of electric and magnetic fields (Hall effect thruster) or an electrostatic (gridded ion) field then accelerates the ions and pushes them out of the thruster driving the spacecraft to tremendous speeds over time. And instead of fire, its exhaust is a glowing greenish-blue trail, like something straight out of science fiction.

A simple illustration of how electric propulsion systems work
A simple illustration of how electric propulsion systems work
Credits: NASA/ATS Lisa Liuzzo

Drag race vs. road trip

A chemical spacecraft is a top fuel dragster as it departs Earth’s orbit toward its destination. The initial burst is quite powerful, but it can really only go in the direction it’s pointing when you stomp on the gas pedal. The spacecraft is off like a bullet, but after its fuel supply is exhausted, there is little ability to speed up, slow down or change direction. So, the mission is locked into specific launch windows and orbital departure timeframes, and it can make only minimal corrections along the way.

An electric propulsion spacecraft, once it’s in space, is out for a cross-country drive, limited only by the gas in the tank. The initial thrust is quite low, but it can continue accelerating for months or even years, and it can also slow down and change direction.

NASA’s Dawn mission is a perfect example. After launch, it accelerated toward Vesta in the asteroid belt. Because of the spacecraft’s small solar arrays it took over five years to get there, but as it approached, the spacecraft flipped 180-degrees, burned its thrusters to slow down and orbited for a year. When it was done, it fired back up and traveled to Ceres, where it still orbits today. This wouldn’t be possible with chemically propelled spacecraft. 

Systems like the one on Dawn are in wide use across NASA and the commercial sector, typically operating in the 1-10 kilowatt (kW) range. But as we prepare to use electric propulsion for more complex science and technology missions, and on human missions for the first time, we’re going to need more power.

More power for people!

The Power and Propulsion Element (PPE) for Gateway will demonstrate advanced, high-power solar electric propulsion around the Moon. It is a 60kW-class spacecraft, 50 of which can be dedicated to propulsion, making it about four times more powerful than current electric propulsion spacecraft. We do this not by building one big thruster, but by combining several into a string with giant solar arrays.

An illustration of the PPE-HALO in lunar orbit.
An illustration of the PPE-HALO in lunar orbit.
Credits: NASA

This advanced system will allow our orbiting platform to support lunar exploration for 15 years given its high fuel economy, and its ability to move while in orbit will allow explorers to land virtually anywhere on the Moon’s surface.

While it’s a critical piece of our Artemis lunar exploration plans, the PPE will also help drive U.S. commercial investments in higher power electric propulsion systems, like those that could be used to get to Mars.

Next stop, Mars

Future Mars transfer vehicles will need around 400kW-2 megawatts of power to successfully ferry our astronauts or cargo to and from the Red Planet. We’re still exploring vehicle and propulsion concepts for Mars, including a combination of nuclear electric and chemical propulsion and other emerging options like Nuclear Thermal Propulsion.

No matter how we get to the Moon and eventually Mars, one thing is for certain… the future of space exploration is exciting, one might even say it’s electrifying

Illustration of a Mars transit habitat and nuclear propulsion system that could one day take astronauts to Mars.
Illustration of a Mars transit habitat and nuclear propulsion system that could one day take astronauts to Mars.
Credits: NASA

Top Image: A solar electric propulsion Hall Effect thruster being tested under vacuum conditions at NASA. Credits: NASA

Source: Jimi Russell
NASA Glenn Research Center

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Two of a Space Kind: Apollo 12 and Mars 2020

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HOW IT WORKS: The International Space Station

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We Are Going to the Moon

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How We Are Going to the Moon

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With the Artemis program, NASA will land the first woman and next man on the Moon by 2024, using innovative technologies to explore more of the lunar surface than ever before.

We will collaborate with our commercial and international partners and establish sustainable exploration by 2028. Then, we will use what we learn on and around the Moon to take the next giant leap – sending astronauts to Mars.

THANK YOU FOR VIEWING!

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