The three planets of the TOI 700 system orbit a small, cool M dwarf
star. TOI 700 d is the first Earth-size habitable-zone world discovered
by TESS. Credit: NASA's Goddard Space Flight Center.
NASA’s Transiting Exoplanet Survey Satellite (TESS) has
discovered its first Earth-size planet in its star’s habitable zone,
the range of distances where conditions may be just right to allow the
presence of liquid water on the surface. Scientists confirmed the find,
called TOI 700 d, using NASA’s Spitzer Space Telescope and have modeled the planet’s potential environments to help inform future observations.
TOI 700 d is one of only a few Earth-size planets discovered in a
star's habitable zone so far. Others include several planets in the TRAPPIST-1 system and other worlds discovered by NASA’s Kepler Space Telescope.
“TESS was designed and launched specifically to find Earth-sized
planets orbiting nearby stars,” said Paul Hertz, astrophysics division
director at NASA Headquarters in Washington. “Planets around nearby
stars are easiest to follow-up with larger telescopes in space and on
Earth. Discovering TOI 700 d is a key science finding for
TESS. Confirming the planet’s size and habitable zone status with
Spitzer is another win for Spitzer as it approaches the end of science
operations this January."
NASA's Transiting Exoplanet Survey Satellite (TESS)
has discovered its first Earth-size planet in its star's habitable
zone, the range of distances where conditions may be just right to allow
the presence of liquid water on the surface. Scientists confirmed the
find, called TOI 700 d, using NASA's Spitzer Space Telescope and have
modeled the planet's potential environments to help inform future
observations. Credits: NASA's Goddard Space Flight Center. Download this video in HD formats from NASA Goddard's Scientific Visualization Studio
TESS monitors large swaths of the sky, called sectors, for 27 days at
a time. This long stare allows the satellite to track changes in
stellar brightness caused by an orbiting planet crossing in front of its
star from our perspective, an event called a transit.
TOI 700 is a small, cool M dwarf star located just over 100 light-years away in the southern constellation Dorado.
It’s roughly 40% of the Sun’s mass and size and about half its surface
temperature. The star appears in 11 of the 13 sectors TESS observed
during the mission’s first year, and scientists caught multiple transits
by its three planets.
The star was originally misclassified in the TESS database as being
more similar to our Sun, which meant the planets appeared larger and
hotter than they really are. Several researchers, including Alton
Spencer, a high school student working with members of the TESS team,
identified the error.
“When we corrected the star’s parameters, the sizes of its planets
dropped, and we realized the outermost one was about the size of Earth
and in the habitable zone,” said Emily Gilbert, a graduate student at
the University of Chicago.
“Additionally, in 11 months of data we saw no flares from the star,
which improves the chances TOI 700 d is habitable and makes it easier to
model its atmospheric and surface conditions.”
Gilbert and other researchers presented the findings at the 235th meeting of the American Astronomical Society in Honolulu, and three papers — one of which Gilbert led — have been submitted to scientific journals.
The innermost planet, called TOI 700 b, is almost exactly Earth-size,
is probably rocky and completes an orbit every 10 days. The middle
planet, TOI 700 c, is 2.6 times larger than Earth — between the sizes of
Earth and Neptune — orbits every 16 days and is likely a gas-dominated
world. TOI 700 d, the outermost known planet in the system and the only
one in the habitable zone, measures 20% larger than Earth, orbits every
37 days and receives from its star 86% of the energy that the Sun
provides to Earth. All of the planets are thought to be tidally locked
to their star, which means they rotate once per orbit so that one side
is constantly bathed in daylight.
A team of scientists led by Joseph Rodriguez, an astronomer at the Center for Astrophysics | Harvard & Smithsonian in Cambridge, Massachusetts, requested follow-up observations with Spitzer to confirm TOI 700 d.
“Given the impact of this discovery — that it is TESS’s first
habitable-zone Earth-size planet — we really wanted our understanding of
this system to be as concrete as possible,” Rodriguez said. “Spitzer
saw TOI 700 d transit exactly when we expected it to. It’s a great
addition to the legacy of a mission that helped confirm two of the
TRAPPIST-1 planets and identify five more.”
The Spitzer data increased scientists’ confidence that TOI 700 d is a
real planet and sharpened their measurements of its orbital period by
56% and its size by 38%. It also ruled out other possible astrophysical causes of the transit signal, such as the presence of a smaller, dimmer
companion star in the system.
Rodriguez and his colleagues also used follow-up observations from a 1-meter ground-based telescope in the global Las Cumbres Observatory network to improve scientists’ confidence in the orbital period and size of TOI 700 c by 30% and 36%, respectively.
Because TOI 700 is bright, nearby, and shows no sign of stellar
flares, the system is a prime candidate for precise mass measurements by
current ground-based observatories. These measurements could confirm
scientists’ estimates that the inner and outer planets are rocky and the
middle planet is made of gas.
Future missions may be able to identify whether the planets have atmospheres and, if so, even determine their compositions.
While the exact conditions on TOI 700 d are unknown, scientists can
use current information, like the planet’s size and the type of star it
orbits, to generate computer models and make predictions. Researchers at
NASA’s Goddard Space Flight Center in Greenbelt, Maryland, modeled 20
potential environments of TOI 700 d to gauge if any version would result
in surface temperatures and pressures suitable for habitability.
Their 3D climate models examined a variety of surface types and
atmospheric compositions typically associated with what scientists
regard to be potentially habitable worlds. Because TOI 700 d is tidally
locked to its star, the planet’s cloud formations and wind patterns may
be strikingly different from Earth’s.
One simulation included an ocean-covered TOI 700 d with a dense,
carbon-dioxide-dominated atmosphere similar to what scientists suspect
surrounded Mars when it was young. The model atmosphere contains a deep
layer of clouds on the star-facing side. Another model depicts TOI 700 d
as a cloudless, all-land version of modern Earth, where winds flow away
from the night side of the planet and converge on the point directly
facing the star.
When starlight passes through a planet’s atmosphere, it interacts
with molecules like carbon dioxide and nitrogen to produce distinct
signals, called spectral lines. The modeling team, led by Gabrielle
Engelmann-Suissa, a Universities Space Research Association visiting research assistant at Goddard, produced simulated spectra for the 20 modeled versions of TOI 700 d.
“Someday, when we have real spectra from TOI 700 d, we can backtrack,
match them to the closest simulated spectrum, and then match that to a
model,” Engelmann-Suissa said. “It’s exciting because no matter what we
find out about the planet, it’s going to look completely different from
what we have here on Earth.”
TESS is a NASA Astrophysics Explorer mission led and operated by MIT
in Cambridge, Massachusetts, and managed by NASA's Goddard Space Flight
Center. Additional partners include Northrop Grumman, based in Falls
Church, Virginia; NASA’s Ames Research Center in California’s Silicon
Valley; the Harvard-Smithsonian Center for Astrophysics in Cambridge,
Massachusetts; MIT’s Lincoln Laboratory; and the Space Telescope Science
Institute in Baltimore. More than a dozen universities, research
institutes and observatories worldwide are participants in the mission.
The Jet Propulsion Laboratory in Pasadena, California, manages the
Spitzer Space Telescope mission for NASA's Science Mission Directorate
in Washington. Science operations are conducted at the Spitzer Science
Center at Caltech in Pasadena. Space operations are based at Lockheed
Martin Space in Littleton, Colorado. Data are archived at the Infrared
Science Archive housed at IPAC at Caltech. Caltech manages JPL for NASA.
The modeling work was funded through the Sellers Exoplanet
Environments Collaboration at Goddard, a multidisciplinary collaboration
that brings together experts to build comprehensive and sophisticated
computer models to better analyze current and future exoplanet
observations.
By Jeanette Kazmierczak
NASA’s Goddard Space Flight Center, Greenbelt, Md.
By Jeanette Kazmierczak
NASA’s Goddard Space Flight Center, Greenbelt, Md.
Editor: Rob Garner
Source: NASA/TESS