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Astronomers Confirm Orbital Details of TRAPPIST-1h
Jet Propulsion Laboratory
May 22, 2017

Scientists using NASA's Kepler space telescope identified a regular pattern
in the orbits of the planets in the TRAPPIST-1 system that confirmed suspected details about the orbit of its outermost and least understood planet, TRAPPIST-1h.

TRAPPIST-1 is only eight percent the mass of our sun, making it a cooler
and less luminous star. It's home to seven Earth-size planets, three of
which orbit in their star's habitable zone -- the range of distances from
a star where liquid water could pool on the surface of a rocky planet.
The system is located about 40 light-years away in the constellation of Aquarius. The star is estimated to be between 3 billion and 8 billion
years old.

Scientists announced that the system has seven Earth-sized planets at
a NASA press conference on Feb. 22. NASA's Spitzer Space Telescope, the TRAPPIST (Transiting Planets and Planetesimals Small Telescope) in Chile
and other ground-based telescopes were used to detect and characterize
the planets. But the collaboration only had an estimate for the period
of TRAPPIST-1h.

Astronomers from the University of Washington have used data from the
Kepler spacecraft to confirm that TRAPPIST-1h orbits its star every 19
days. At six million miles from its cool dwarf star, TRAPPIST-1h is located beyond the outer edge of the habitable zone, and is likely too cold for
life as we know it. The amount of energy (per unit area) planet h receives from its star is comparable to what the dwarf planet Ceres, located in
the asteroid belt between Mars and Jupiter, gets from our sun.

"It's incredibly exciting that we're learning more about this planetary
system elsewhere, especially about planet h, which we barely had information on until now," said Thomas Zurbuchen, associate administrator of NASA's Science Mission Directorate at Headquarters in Washington. "This finding
is a great example of how the scientific community is unleashing the power
of complementary data from our different missions to make such fascinating discoveries."

"It really pleased me that TRAPPIST-1h was exactly where our team predicted
it to be. It had me worried for a while that we were seeing what we wanted
to see -- after all, things are almost never exactly what you expect them
to be in this field," said Rodrigo Luger, doctoral student at UW in Seattle, and lead author of the study published in the journal Nature Astronomy. "Nature usually surprises us at every turn, but, in this case, theory
and observation matched perfectly."

Orbital Resonance - Harmony Among Celestial Bodies

Using the prior Spitzer data, the team recognized a mathematical pattern
in the frequency at which each of the six innermost planets orbits their
star. This complex but predictable pattern, called an orbital resonance, occurs when planets exert a regular, periodic gravitational tug on each
other as they orbit their star.

To understand the concept of resonance, consider Jupiter's moons Io, Europa and Ganymede, which is the farthest out of the three. For every time Ganymede orbits Jupiter, Europa orbits twice and Io makes four trips around the
planet. This 1:2:4 resonance is considered stable and if one moon were
nudged off course, it would self-correct and lock back into a stable orbit.
It is this harmonious influence between the seven TRAPPIST-1 siblings
that keeps the system stable.

These relationships, said Luger, suggested that by studying the orbital velocities of its neighboring planets, scientists could predict the exact orbital velocity, and hence also orbital period, of planet h, even before
the Kepler observations. The team calculated six possible resonant periods
for planet h that would not disrupt the stability of the system, but only
one was not ruled out by additional data. The other five possibilities
could have been observed in the Spitzer and ground-based data collected
by the TRAPPIST team.

"All of this", Luger said, "indicates that these orbital relationships
were forged early in the life of the TRAPPIST-1 system, during the planet formation process."

"The resonant structure is no coincidence, and points to an interesting dynamical history in which the planets likely migrated inward in lock-step," said Luger. "This makes the system a great laboratory for planet formation
and migration theories."

Worldwide Real-time Collaboration

The Kepler spacecraft stared at the patch of sky home to the TRAPPIST-1
system from Dec. 15, 2016, to March 4, 2017. collecting data on the star's minuscule changes in brightness due to transiting planets as part of its second mission, K2. On March 8, the raw, uncalibrated data was released
to the scientific community to begin follow-up studies.

The work to confirm TRAPPIST-1h's orbital period immediately began, and scientists from around the world took to social media to share in real-time the new information gleaned about the star's behavior and its brood of planets. Within two hours of the data release, the team confirmed its prediction of a 19-day orbital period.

"Pulling results out of data is always stimulating, but it was a rare
treat to watch scientists across the world collaborate and share their progress in near-real time on social media as they analyzed the data and identified the transits of TRAPPIST-1h," said Jessie Dotson, project scientist for the K2 mission at NASA's Ames Research Center in California's Silicon Valley. "The creativity and expediency by which the data has been put
to use has been a particularly thrilling aspect of K2's community-focused approach."

TRAPPIST-1's seven-planet chain of resonances established a record among
known planetary systems, the previous holders being the systems Kepler-80
and Kepler-223, each with four resonant planets.

The TRAPPIST-1 system was first discovered in 2016 by the TRAPPIST collaboration,
and was thought to have just three planets at that time. Additional planets were found with Spitzer and ground-based telescopes. NASA's Hubble Space Telescope is following up with atmospheric observations, and the James
Webb Space Telescope will be able to probe potential atmospheres in further detail.

Ames manages the Kepler and K2 missions for NASA's Science Mission Directorate.

NASA's Jet Propulsion Laboratory in Pasadena, California, managed Kepler mission development. Ball Aerospace & Technologies Corp. operates the
flight system with support from the Laboratory for Atmospheric and Space Physics at the University of Colorado in Boulder.

For more information about the Kepler and K2 missions, visit:

https://www.nasa.gov/kepler

For more information about the TRAPPIST-1 system, visit:

http://exoplanets.nasa.gov/trappist1

News Media Contact
Elizabeth Landau
Jet Propulsion Laboratory, Pasadena, Calif.
818-354-6425
elizabeth.landau@jpl.nasa.gov

Michele Johnson
Ames Research Center, Moffett Field, Calif.
650-604-6982
michele.johnson@nasa.gov

Written by Michele Johnson

2017-147

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