By Published: Sept. 23, 2021

Banner image: Artist's depiction of a "hot Jupiter" planet. (Credit:NASA/Ames/JPL-Caltech)

A new miniature satellite designed and built at Boulder’s (LASP) is providing proof that “cute” things can take on big scientific challenges.

The (TE) is slated to launch into space Sept. 27. The approximately $4 million spacecraft, a smaller-than-usual type of satellite known as a “CubeSat,” is about as large as a “family-sized box of Cheerios,” said LASP researcher Kevin France, principal investigator for the mission.

But it has mighty goals: Over the course of about 7 months, the mission will track the volatile physics around a class of extremely hot planets orbiting stars far away from Earth. It’s the first CubeSat mission funded by NASA to peer at these distant worlds—marking a major test of what small spacecraft may be capable of.

Rick Kohnert, project manager for TE, and Arika Egan pose with the small satellite at LASP.A team installs TE into its launch system in a clean lab

Top: Rick Kohnert, systems engineer for TE, and Arika Egan pose with the small satellite at LASP.Bottom: A team installs TE into its launch system. (Credits: Kevin France; NASA/WFF)

“It’s an experiment that NASA is conducting to see how much science can be done with a small satellite,” said France, professor in the Department of Astrophysical and Planetary Sciences. “That’s exciting but also a little daunting.”

The mission will blast off aboard a United Launch Alliance Atlas V rocket alongside the Landsat 9 satellite from Vandenberg Space Force Base in Lompoc, California.

Once TE enters into orbit around Earth, it will set its sights on a suite of exoplanets called “hot Jupiters.” As their names suggest, these gaseous planets are both large and scalding hot, reaching temperatures of thousands of degrees Fahrenheit. The satellite’s findings will help scientists to better understand how these planets, and many others, evolve and even shrink over billions of years.

In recent years, LASP has led the development of multiple CubeSat missions to explore everything from the sun’s activity to supernovae in distant galaxies. Unlike larger space missions, which often net a price tag in the hundreds of millions of dollars, engineers can produce CubeSats on the cheap.

“As little as a decade ago, many in the space community expressed the opinion that CubeSat missions were little more than ‘toys,’” said LASP Director Daniel Baker. “There was recognition that small spacecraft could be useful as teaching and training tools, but there was widespread skepticism that forefront science could be done with such small platforms. I am delighted that LASP and the University of Colorado have led the way in demonstrating that remarkable science can be done with small packages. TE and other CubeSat missions are changing the landscape for basic research.”

Scorching planets

TE, in particular, tackles a hot topic in astrophysics.

Hot Jupiters, and their even more chaotic cousins ultra-hot Jupiters, are an especially inhospitable class of gaseous worlds. Take KELT-9b: This planet, which sits in a stellar system about 670 light years from our own, has a mass nearly three times larger than Jupiter’s. But KELT-9b also orbits much closer to its home star—so close that temperatures on the planet hit a mind-boggling 7,800 degrees Fahrenheit.

“Because these planets are parked so close to their parent stars, they receive a tremendous amount of radiation,” France said.

Logo for the Colorado Ultraviolet Transit Experiment (TE) featuring a teddy bearArtist's depiction of  the planet KELT-9b next to its star

Top: TE logo.Bottom: Artist's depiction of the planet KELT-9b. (Credits: LASP;NASA/JPL-Caltech)

That radiation takes a toll on a planet over time. At those temperatures, the atmospheres of hot Jupiters begin to expand like a pufferfish and may even tear away and escape into space.

Which is where TE comes in: Throughout its mission, the spacecraft will measure how fast gases are escaping from a minimum of 10 hot Jupiters, including KELT-9b. It will achieve this feat using its unique, rectangular telescope design, which was pioneered at LASP.

“Ultimately TE has one major purpose, and that is to study the inflated atmospheres of these really hot, pretty gassy exoplanets,” said Arika Egan, a graduate student at LASP who has helped to develop the mission. “The inflation and escape these exoplanetary atmospheres undergo are on scales just not seen in our own solar system.”

France added that the team’s findings may tell scientists a lot not just about hot Jupiters but about the full range of planets that exist in the galaxy. That includes small and rocky worlds like Earth and its close neighbors. (Mars, for example, also lost much of its atmosphere over nearly 3 billion years, making the planet uninhabitable for humans).

“The more places we understand atmospheric escape, the better we understand atmospheric escape as a whole,” France said. “We can then apply these findings to different types of planets."

Bon voyage

He noted that TE is well-suited for probing the atmospheres of alien worlds. Unlike larger space missions, such as the Hubble Space Telescope, this satellite only has one job to do: To scan as many hot Jupiters as it can during its short lifespan.

France said that, after spending four years developing TE in Boulder, he and his team are feeling bittersweet about the mission’s upcoming launch. Egan, for her part, is eager for the little craft to make a small dent in questions about Earth’s place in the galaxy.

“When you look up at the sky and see thousands of stars, that is existential on its own,” she said. “But then you think about the planets we’ve discovered around those stars, thousands of planets. We’ve just barely scratched the surface of characterizing them, of understanding their diversity. How little we know is astounding, and joining the effort to learn more is fulfilling.”


Science team members on the TE mission include researchers from the University of Leiden and University of Amsterdam in the Netherlands, University of Arizona, Space Research Institute of the Austrian Academy of Sciences and the University of Toulouse in France.