NASA's DART spacecraft hits target asteroid in first planetary defense
test
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 [September 27, 2022]
By Steve Gorman
(Reuters) - NASA's DART spacecraft
successfully slammed into a distant asteroid at hypersonic speed on
Monday in the world's first test of a planetary defense system, designed
to prevent a potential doomsday meteorite collision with Earth.
Humanity's first attempt to alter the motion of an asteroid or any
celestial body played out in a NASA webcast from the mission operations
center outside Washington, D.C., 10 months after DART was launched.
The livestream showed images taken by DART's camera as the cube-shaped "impactor"
vehicle, no bigger than a vending machine with two rectangular solar
arrays, streaked into the asteroid Dimorphos, about the size of a
football stadium, at 7:14 p.m. EDT (2314 GMT) some 6.8 million miles (11
million km) from Earth.
The $330 million mission, some seven years in development, was devised
to determine if a spacecraft is capable of changing the trajectory of an
asteroid through sheer kinetic force, nudging it off course just enough
to keep Earth out of harm's way.
Whether the experiment succeeded beyond accomplishing its intended
impact will not be known until further ground-based telescope
observations of the asteroid next month. But NASA officials hailed the
immediate outcome of Monday's test, saying the spacecraft achieved its
purpose.
"NASA works for the benefit of humanity, so for us it’s the ultimate
fulfillment of our mission to do something like this - a technology
demonstration that, who knows, some day could save our home," NASA
Deputy Administrator Pam Melroy, a retired astronaut, said minutes after
the impact.
DART, launched by a SpaceX rocket in November 2021, made most of its
voyage under the guidance of NASA's flight directors, with control
handed over to an autonomous on-board navigation system in the final
hours of the journey.
Monday evening's bullseye impact was monitored in near real time from
the mission operations center at the Johns Hopkins University Applied
Physics Laboratory in Laurel, Maryland.
Cheers erupted from the control room as second-by-second images of the
target asteroid, captured by DART's onboard camera, grew larger and
ultimately filled the TV screen of NASA's live webcast just before the
signal was lost, confirming the spacecraft had crashed into Dimorphos.
DART's celestial target was an oblong asteroid "moonlet" about 560 feet
(170 meters) in diameter that orbits a parent asteroid five times larger
called Didymos as part of a binary pair with the same name, the Greek
word for twin.
Neither object presents any actual threat to Earth, and NASA scientists
said their DART test could not create a new hazard by mistake.
Dimorphos and Didymos are both tiny compared with the cataclysmic
Chicxulub asteroid that struck Earth some 66 million years ago, wiping
out about three-quarters of the world's plant and animal species
including the dinosaurs.
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NASA's Double Asteroid Redirection Test
(DART) spacecraft prior to impact at the Didymos binary asteroid
system showed in this undated illustration handout. NASA/Johns
Hopkins/Handout via REUTERS
Smaller asteroids are far more common and present a greater
theoretical concern in the near term, making the Didymos pair
suitable test subjects for their size, according to NASA scientists
and planetary defense experts. A Dimorphos-sized asteroid, while not
capable of posing a planet-wide threat, could level a major city
with a direct hit.
Also, the two asteroids' relative proximity to Earth and dual
configuration make them ideal for the first proof-of-concept mission
of DART, short for Double Asteroid Redirection Test.
ROBOTIC SUICIDE MISSION
The mission represented a rare instance in which a NASA spacecraft
had to crash to succeed. DART flew directly into Dimorphos at 15,000
miles per hour (24,000 kph), creating the force scientists hope will
be enough to shift its orbital track closer to the parent asteroid.
APL engineers said the spacecraft was presumably smashed to bits and
left a small impact crater in the boulder-strewn surface of the
asteroid.
The DART team said it expects to shorten the orbital path of
Dimorphos by 10 minutes but would consider at least 73 seconds a
success, proving the exercise as a viable technique to deflect an
asteroid on a collision course with Earth - if one were ever
discovered.
A nudge to an asteroid millions of miles away years in advance could
be sufficient to safely reroute it.
Earlier calculations of the starting location and orbital period of
Dimorphos were made during a six-day observation period in July and
will be compared with post-impact measurements made in October to
determine whether the asteroid budged and by how much.
Monday's test also was observed by a camera mounted on a
briefcase-sized mini-spacecraft released from DART days in advance,
as well as by ground-based observatories and the Hubble and Webb
space telescopes, but images from those were not immediately
available.
DART is the latest of several NASA missions in recent years to
explore and interact with asteroids, primordial rocky remnants from
the solar system's formation more than 4.5 billion years ago.
Last year, NASA launched a probe on a voyage to the Trojan asteroid
clusters orbiting near Jupiter, while the grab-and-go spacecraft
OSIRIS-REx is on its way back to Earth with a sample collected in
October 2020 from the asteroid Bennu.
The Dimorphos moonlet is one of the smallest astronomical objects to
receive a permanent name and is one of 27,500 known near-Earth
asteroids of all sizes tracked by NASA. Although none are known to
pose a foreseeable hazard to humankind, NASA estimates that many
more asteroids remain undetected in the near-Earth vicinity.
(Reporting by Steve Gorman in Los Angeles; Additional reporting by
Joey Roulette in Los Angeles; Editing by Sandra Maler and Stephen
Coates)
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