A study of NASA’s TESS (Transiting Exoplanet Survey Satellite) data on stellar pairs undergoing mutual eclipses has uncovered more than two dozen candidate exoplanets, or worlds beyond our solar system. This method allows the mission to locate planets it couldn’t otherwise detect.
A gas giant planet looms in the foreground at right,
illuminated by a pair of stars, in this artist’s concept of a world in a binary
system. NASA’s TESS (Transiting Exoplanet Survey Satellite) has found planets
in two binary star systems by looking for stellar dimming as the planets cross
in front of one of the stars. Astronomers have now demonstrated a new method of
finding planets in these systems by focusing on the timing of the stars’ mutual
eclipses.
NASA's Goddard Space Flight Center/Chris Smith (USRA)
To date, TESS has discovered 885 confirmed exoplanets and identified
more than 7,900 candidates, nearly all found because the planets pass in front
of their stars from our perspective. These events, called transits, produce a
small, regular dip in the brightness of the planet’s host star. TESS also observes
tens of thousands of eclipsing binary stars — two orbiting stars that
alternately eclipse each other from our vantage point. Astronomers can detect
the gravitational tug of exoplanets in these systems by carefully measuring the
exact timing of many eclipses. Prior to the new study, discoveries by NASA’s
retired Kepler mission and other
facilities had recorded 16 transiting worlds around binary stars, while TESS had found an additional two.
“Identifying transits in binary systems
clearly is challenging, but we’d like to know more about the range of planets
that can form around two gravitationally bound stars,” said study lead Margo
Thornton, a doctoral candidate at UNSW (University of New South Wales)
in Sydney. “So we developed a survey to search for planets using stellar
eclipses that is not limited to the orientation of the planet’s orbit.”
A paper describing
the findings published May 4 in the journal Monthly Notices of the Royal
Astronomical Society.
For planets located in binary systems,
the orientation of the planet’s orbit can tell us about how that system formed.
Some models of planet formation in binary systems suggest planets mainly form
near the plane formed by the two orbiting stars, increasing the likelihood of
binaries hosting transiting worlds. But other models indicate a much more
disorderly formation process, with the stellar pair stirring its young planets
into wider and more tilted paths much less likely to undergo transits.
The timing of stellar eclipses can
gradually change through tidal and rotational interactions between the stars,
the effects of general relativity, and the presence of other unseen masses,
such as planets, in the system. All of these forces cause the entire orbital
plane of the binary to rotate, or precess, and this in turn alters the eclipse
timing.
“The key to calculating all of these
different influences is the long, rich set of observations available from
TESS,” said co-author Benjamin Montet, a Scientia associate professor at UNSW
Sydney. “After analyzing 1,590 binaries with at least two years of TESS data,
we found 27 with candidate planets that now await confirmation.”
Explore how observations of stellar eclipses can
expand the capabilities of NASA’s TESS, leading to the discovery of new
candidate planets it couldn’t otherwise detect.
NASA’s Goddard Space Flight Center/Francis Reddy
Since science operations began in 2018,
TESS has tiled the sky by observing large swaths, called sectors, for nearly a
month. Currently, the mission’s cameras capture a single image of the entire
sector, measuring 24 by 96 degrees, about every 3 minutes, with even faster
observations of selected targets.
The masses of the new candidates remain
uncertain, but the team estimates the smallest world may hold as little 12
Earth masses, with the largest topping out around 3,200 Earths, or about 10
times Jupiter's mass. Confirming these planets will require future ground-based
observations that precisely measure the velocities of the host stars, which
will reveal the slight gravitational tugs of any possible planets.
“The TESS mission was built to find
transiting planets, and it’s great to see how the same measurements are driving
discoveries far beyond its original mission,” said Allison Youngblood, the TESS
project scientist at NASA’s Goddard Space Flight Center in
Greenbelt, Maryland. “The mission’s continuing data collection is a treasure
trove that enables new findings across a wide range of astronomical topics,
from asteroids in the solar system to active galaxies powered by black holes in
the distant universe.”
You
could discover the next exoplanet! Join the Planet
Hunters TESS citizen science project, and you’ll learn how to read light curves
— plots of light data from distant stars — to find telltale signals from
orbiting exoplanets.
By Francis Reddy
NASA’s
Goddard Space Flight Center,
Greenbelt, Md.
Source: For NASA’s TESS, Stellar Eclipses Shed Light on Possible New Worlds - NASA Science
