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Subj: TESS: A behind-the-scenes look at NASA's latest planet hunt
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TESS: A behind-the-scenes look at NASA's latest planet hunter
TESS is revolutionizing our understanding of planets in the solar neighborhood.
But finding new worlds is only the beginning.
In 1995, astronomers discovered the first extrasolar planet orbiting a Sun-like
star.
Ten years later, exoplanet research remained in its infancy.
Researchers still weren't sure whether planets circling other stars were
plentiful or rare.
So, members of my small satellite research group at MIT's Kavli Institute
for Astrophysics and Space Research opened discussions with our neighbors at
the Harvard-Smithsonian Center for Astrophysics (CfA).
We pondered how we might repurpose the High Energy Transient Explorer-2
(HETE-2), which we had launched in 2000, to search for signals from extrasolar
planets as they passed in front of their host stars.
We knew that our MIT-built star trackers were capable of detecting changes of
as little as 0.1 percent in a star's brightness.
This level of precision would allow us to spot transits of close-in
Jupiter-sized planets - so-called hot Jupiters - orbiting solar-type stars.
So, in 2005, we proposed to NASA that HETE-2 be assigned a new task and a
new name.
Rechristened the Hot Exoplanet Transit Experiment-Survey (HETE-S), it would
carry out a nearly all-sky survey for transiting hot Jupiters at low cost
(approximately $2 million per year) for five years.
Unfortunately, NASA declined our proposal, noting that the considerably
more capable Kepler Space Telescope - a much larger, $600 million mission
dedicated to finding exoplanets by watching them transit their host stars -
would soon launch.
So, HETE-S never came to be. But from its conception was born the Transiting
Exoplanet Survey Satellite (TESS).
This mission is the result of more than a decade-long effort, with the
primary goal of discovering transiting exoplanets in our solar neighborhood
that are ripe for follow-up with the next generation of telescopes.
TESS is born
Although NASA rejected our proposal for HETE-S, we realized that a small
satellite based upon HETE-2 and equipped with newer cameras could come in at
a low enough cost for private funding.
This new satellite, which we referred to as TESS-P (P for private), could
carry out a shallow wide-field survey of the entire sky, complementing
Kepler's 100-square-degree deep narrow-field search by covering a field 400
times greater.
During 2006 and 2007, the Kavli Foundation, the Smithsonian Astrophysical
Observatory, Google, and a group of MIT departmental and private donors
sought funding for TESS. Unfortunately, the Great Recession intervened and
the majority of our prospective donors could no longer fund our plan.
Thus, when NASA announced an Astrophysics Small Explorer (SMEX) mission
solicitation in 2008, we commenced work on our concept as a SMEX mission
with only two months to go before the December proposal deadline.
TESS survived as one of three mission proposals selected for a detailed Phase
A study; unfortunately, it was not selected for flight following Phase A
completion in 2009.
We immediately began planning for the next NASA solicitation, for which
proposals were due in 2011.
Yet again, NASA selected TESS for a year-long Phase A study, this time as a
Medium-Class Explorer (MIDEX) mission.
We were met with success: TESS was selected and funded as the MIDEX winner
in April 2013!
During the next five years, we assembled a highly skilled and dedicated team
to design, build, fly, and extract scientific data from TESS.
That team, which ultimately devoted more than a million hours to the effort,
included members from MIT's Kavli Institute for Astrophysics and Space
Research, MIT's Lincoln Laboratory, the Harvard-Smithsonian CfA, NASA's
Goddard Space Flight Center and Ames Research Center, Orbital ATK (
now part of Northrop Grumman), The Aerospace Corporation, Space Telescope
Science Institute, and SpaceX. In addition, a science team comprising
astronomers from more than a dozen universities worldwide collaborated to
assemble the TESS observation program.
Getting a good view
TESS entered development in 2014 with the primary science goal of searching
the entire sky for the best 1,000 small exoplanets within 200 light-years -
i.e., the solar neighborhood. "Best" in this case means exoplanets with measurable masses, as well as atmospheres that can be studied with the upcoming James Webb Space Telescope (JWST). Essentially, TESS would be a finder scope for Webb, scouting for Earth-sized exoplanets orbiting the brightest Sun-like and smaller M-dwarf stars within about 200 light-years of our solar system. TESS would also serve as a bridge from the (now-defunct) Kepler mission to Webb, as well as other large exoplanet imaging space missions with launch dates in the 2030s and beyond.
The most critical bit of mission planning was selecting an orbit for TESS
that would provide a view free of obstacles - namely, Earth. TESS needed to
continuously monitor a huge field of view (more than 2,000 square degrees)
for weeks at a time.
In order to find planets, it would need to see at least two or three
transits - and a transit of a small planet might only last one or two hours
every couple of weeks. Based on this data collection rate,
TESS would also need to downlink enormous numbers of images for ground-based
observers to search.
Orbits very distant from Earth - like Kepler's 6.2 million-mile
(10 million kilometers) heliocentric orbit or JWST's planned 900,000-mile
(1.5 million km) orbit around the Earth-Sun Lagrange 2 point - seemed
desirable.
But communicating from those distances would exceed any reasonable budget of
antenna time a small mission could expect from NASA's Deep Space Network.
The solution turned out to be a new kind of elliptical orbit, in which the
satellite spends part of its time close to Earth for data downlink but most
of its time at a distance comparable to the Moon's distance from Earth.
Generally, such orbits are notoriously unstable and can result in a spacecraft
crashing into either the Moon or Earth within a couple of years.
Our unique solution turned out to be an almost magical orbit in a favorable
2:1 resonance with the Moon's orbit around Earth. Since this specific
so-called P/2 orbit had never been used previously in a space mission, our
team spent an enormous amount of time analyzing how to establish and maintain it.
To be sure of our results, we had two different groups - one at The Aerospace
Corporation and one at NASA Goddard - work independently on the calculations.
In the end, our P/2 orbit was both elegant and practical.
It even offered several major advantages, some of which surprised us -
especially the excellent thermal stability of our cameras and the low
radiation levels experienced by the spacecraft. Other advantages included high
downlink rates and low stray background light.
Primary mission success
On April 18, 2018, a SpaceX Falcon 9 rocket carrying TESS roared into space.
TESS arrived in its final P/2 orbit 42 days later, and our primary mission's
first survey observation began July 8. Over the next two years, TESS's four
wide-field CCD cameras systematically stepped across the sky.
During the first year, TESS observed 13 Southern Hemisphere "sectors" 24ø
by 96ø in size for 27.4 days each. In its second year, TESS switched to
observing 13 equally sized sectors in the northern sky.
The firehose of data from TESS's first three years has yielded thousands of
new planet candidates spread over the entire sky.
And the task of identifying the host stars for these candidates has fallen
largely upon a small, dedicated group of analysts.
Comprising primarily students and postdocs at MIT and the Harvard-Smithsonian
CfA, this group - the TESS Objects of Interest (TOI) team - has been working
for the past three years, examining light curves for more than 10 million
stars brighter than 13th magnitude.
Their thousands of hours of effort have yielded approximately 3,000 new
exoplanet candidates. We estimate that by the middle of this decade, this
massive detective effort - which will be assisted by novel artificial
intelligence methods currently under development - will have turned up as
many as 10,000 new planet candidates.
This immense collection should comprise essentially all of the best exoplanet
candidates in the solar neighborhood for detailed follow-up and atmospheric
characterization.
The TESS Follow-up Observing Program (TFOP), coordinated by our colleagues
at the Smithsonian Astrophysical Observatory, is a worldwide effort of more
than 550 astronomers at 100 institutions.
These researchers sort through and follow up on this rich trove of TOIs
using roughly 250 telescopes.
TFOP astronomers have whittled down the 3,000 or so TOIs to about 100
so-called Level 1 confirmed TESS exoplanets.
These Level 1 planets are all small, with radii less than four times that
of Earth.
Combined with the masses measured by the TFOP teams, we have confirmed that
these small planets are indeed super-Earths and their slightly larger cousins
with thicker atmospheres, sub-Neptunes. Furthermore, an important subgroup
of these Level 1 planets is Earth-like in both size and mass.
sizes among the TESS planet candidates. And about 25 percent of TOIs are
not planets at all, but distant eclipsing binary stars, whose eclipses
can mimic exoplanet transits.
Ongoing observations with higher-angular resolution telescopes, such as
the Gaia space mission, will allow astronomers to separate these systems
from real transiting planets.
TESS is also revolutionizing the study of multiplanet systems, especially those
with six or more worlds co-orbiting their host star.
Such systems were initially discovered by Kepler and the TRAnsiting Planets
and PlanetesImals Small Telescope-South (TRAPPIST) survey telescopes.
Unfortunately, these early discoveries orbit relatively faint stars -
typically 14th magnitude - making them difficult to study.
As of early 2021, TESS has found more than 80 new multiplanet systems.
Four recent discoveries, each with four or more planets, are much closer to
Earth than the Kepler and TRAPPIST systems and thus have stellar hosts that
appear 30 to 50 times brighter.
These are much easier for follow-up observers to study. Brighter host stars
also make it easier for JWST and the next generation of giant 30-meter class
ground-based telescopes to investigate these planetary atmospheres via
spectroscopy.
This is because brighter stars mean shorter observations can still detect
any potentially biologically interesting signatures in a planet's atmosphere
as light from the host star filters through it.
Extended mission
After completing its initial planned two-year survey in July 2020, TESS
embarked on a 26-month extended mission.
Approved by NASA, this extension allows TESS to search for planets around
even more distant stars, as well as follow up on some of the most exciting
discoveries from the primary mission.
This first extended mission consists of three major initiatives: First, TESS
will survey the sky a second time, covering the Southern Hemisphere again in
the first year and the Northern Hemisphere in the second year.
Additionally, TESS will spend 135 days exploring a 12ø-wide band along the
Ecliptic Plane, which was not probed during the primary mission because we
were focused on fully covering the continuous viewing zones for JWST that
surround the north and south ecliptic poles.
The Kepler Space Telescope's K2 mission surveyed the ecliptic plane from
2014 to 2018.
But measurement uncertainties in transit times mean that some K2 planets
could effectively be lost as their real transit periods drift away from the
measured (uncertain) periods over the half decade since their discovery,
like two clocks ticking out of sync.
TESS should recover a large fraction of these more than 400 confirmed K2 planets.
Second, TESS now takes full-frame images every 10 minutes, down from the
primary mission's 30-minute exposures.
More frequent exposures should help catch short-duration exoplanet transits
as brief as 40 minutes.
This will reveal more Earth-sized planets in the habitable zone of
M-dwarf stars, which comprise approximately 75 percent of the stars in our survey.
Overall, this improvement could triple the number of planets we expect to find
from 50 to 150 - or more.
Additionally, a new 20-second exposure capability has been introduced,
which improves TESS's ability to detect and accurately measure stellar flares.
It will also help TESS search for exoplanets orbiting white dwarf stars.
Such transits had long been predicted when our extended mission was written,
but were not confirmed until TESS discovered the first one in 2020: a
Jupiter-sized planet orbiting the white dwarf WD 1856.
Finally, guest investigators will get to choose at least 80 percent of the
extended mission's two-minute cadence mode targets.
This mode downloads a small "postage stamp" of pixels around a single star
in TESS's field of view every two minutes.
This faster-paced observing can catch the beginning or end phases of
bright planet transits.
The remaining 20 percent of the extended mission's two-minute cadence
targets will consist of the most promising TOIs from the primary mission.
Not all planets
TESS was designed, funded, and built to identify transiting planets.
But the very nature of its survey means it also catches plenty of so-called
transient events that are not planetary transits.
From eclipsing binary stars and supernovae to outbursts from nearby comets
and far-flung supermassive black holes, TESS has seen it all.
Although these events don't add to the catalog of known extrasolar planets,
they still provide vital data for astronomers studying many other aspects of
our universe.
TYC 7037-89-1: Located about 1,900 light-years away in the constellation
Eridanus, TYC 7037-89-1 (also known as TIC 168789840) is a multiple-star
system discovered within the TESS data.
This unique six-star system is composed of three eclipsing binaries,
meaning every star in the system undergoes eclipses as seen from Earth.
Nu (?) Indi: TESS asteroseismology observations of this bright, naked-eye
star have enabled astronomers to date the past merger of a satellite galaxy
with the Milky Way to 11 billion years ago.
ASASSN-14ko: The galaxy ESO 253-3 contains an active supermassive black hole
that belches out flares every 114 days (pictured at top in an artist's concept).
TESS has been instrumental in helping researchers study these outbursts, which
astronomers now believe occur as the black hole slowly nibbles away at an
orbiting star during every closest approach.
Comet 46P/Wirtanen: When Comet 46P/Wirtanen swung near the Sun in late 2018,
TESS was there to watch.
The satellite observed an outburst of ice, dust, and gas from the comet as
it was heated by the Sun - the most comprehensive picture of this type of event
to date.
Supernovae: Within its first month of observation in 2018, TESS spotted six
distant supernovae in other galaxies.
That's the same number of supernovae the Kepler Space Telescope observed in
four years - and it was only the start.
Since then, TESS has caught nearly 200 such events popping off all over
the sky. - A.K.
A revolutionary impact
Thanks to our open policy and high data quality, the number and volume of
TESS images and light curves downloaded from the Barbara A.
Mikulski Archive for Space Telescopes (MAST) has been extraordinary.
During 2020, users downloaded a total of 680 terabytes of data - about
seven times the amount downloaded from either the Hubble or Kepler missions
during that same period.
In December 2020 alone, there were nearly 5 million requests for a total of
about 50 TB of data.
During its 2019 review, NASA commended the TESS mission for "having a
revolutionary impact on the fields of exoplanets and stellar astrophysics,"
as well as for "providing a model of how to build and serve a broad user base
to maximize science return."
As of March 2021, TESS had observed a total of 34 sectors and identified
2,597 TOIs.
Of those, 755 have radii less than four times that of Earth and 120 are
confirmed - thus far - as planets. Dozens more are underway.
The mission's first planet, Pi Mensae c, is a super-Earth four times more
massive and twice as large as Earth, circling the naked-eye Southern Hemisphere
star Pi (p) Mensae every six days.
But TESS has also discovered TOI-700 d - an Earth-sized planet orbiting in
its red dwarf host star's habitable zone, where conditions are right for a
planet to maintain liquid water on its surface.
And there's also LHS 3844 b, a super-Earth so close to its star that one year
lasts just 11 hours and daytime temperatures soar to 989 degrees Fahrenheit
(531 degrees Celsius).
TESS's data has provided observations for more than 300 scientific papers
written in 2020 alone.
And while most of those papers focus on new exoplanet discoveries, others
are studies of the way stars vary, oscillate, spin, and produce flares.
Citizen scientists can easily engage with TESS data through the Planet Hunters
TESS Zooniverse project.
This has led to the discovery of numerous planets, including TOI 1338 b -
TESS's first circumbinary planet with not one, but two suns at the center of
its orbit.
Now engaged in its second complete survey of the full sky, this small but
powerful satellite will continue to reveal the wide diversity of worlds -
like and unlike our own - that share our solar neighborhood. Next, it will
be up to missions like NASA's JWST and Nancy Grace Roman Space Telescope,
and the European Space Agency's Atmospheric Remote-sensing Infrared Exoplanet
Large-survey (ARIEL) satellite, to delve into this long list of nearby worlds
in greater detail, studying their atmospheres and compositions to learn
more about how exoplanets form and evolve.
Perhaps one of these observatories will even hit the jackpot: discovering
potential signs of life on a planet first identified by TESS.
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