Although the chance of an asteroid
impacting Earth is small, even a relatively small asteroid of about 500
feet (about 150 meters) across carries enough energy to cause widespread damage
around the impact site. NASA leads efforts in the U.S. and worldwide both to
detect and track potentially hazardous asteroids and to study technologies to
mitigate or avoid impacts on Earth. If an asteroid were discovered and
determined to be on a collision course with Earth, one response could be to
launch a “kinetic impactor” – a high-velocity spacecraft that would deflect the
asteroid by ramming into it, altering the asteroid’s orbit slightly so that it
misses Earth. NASA’s Double
Asteroid Redirection Test (DART) will be the first mission to demonstrate asteroid
deflection using a kinetic impactor.
DART will test kinetic impactor technology by targeting a double asteroid
that is not on a path to collide with Earth and therefore poses no actual
threat to the planet. The system is composed of two asteroids: the larger
asteroid Didymos (diameter: 780 meters, 0.48 miles), and the smaller moonlet
asteroid, Dimorphos (diameter: 160 meters, 525 feet), which orbits the larger
asteroid. DART, which launched Wednesday,
Nov. 24 at 1:21 a.m. EST on a SpaceX Falcon 9 rocket from
Space Launch Complex 4 East at Vandenberg Space Force Base in California, will
slam into Dimorphos nearly head-on, shortening the time it takes the small
asteroid moonlet to orbit Didymos by several minutes. The mission is led by
the Johns Hopkins Applied
Physics Laboratory (APL) in Laurel, Maryland for NASA’s
Planetary Defense Coordination Office and has support from several NASA
centers.
Scientists and engineers at NASA’s Goddard Space Flight Center in Greenbelt,
Maryland, are checking the flight path of the mission and running computer
simulations that predict how the impact might change Dimorphos’ orbit. The team
will also make telescopic observations to determine the amount and composition
of dust and volatiles (easily vaporized material) released during the impact.
“We are an independent check on the mission's trajectory calculations,”
said Brent Barbee, dynamics verification and validation lead and DART flight
dynamics support lead at Goddard. Goddard used its in-house-developed
Evolutionary Mission Trajectory Generator (EMTG) to provide independent
verification and validation of the DART mission trajectories at various stages
of the mission’s development and evaluate the ability of the mission to adapt
to missed thrust and other contingencies.
“We also used the EMTG to support independent trajectory optimization
studies for DART. These studies assessed the best flight paths for the
spacecraft given its goals, capabilities, and limitations,” said Bruno Sarli of
Goddard and Heliospace Corporation, Berkeley, California, a member of the DART
trajectory optimization team.
Goddard scientists are also helping to calculate how the impact will change
the orbit of Dimorphos, using a specialized binary (double) asteroid dynamics
simulation code developed by the mission's investigation team to model the
orbital and rotational motion of the Didymos system. The Goddard group curated
a version of the tool for the DART mission, adding features and functionality.
“Our simulation results shed light on how DART's impact will change the
dynamics of the system in ways that are detectable via remote observations,”
said Barbee.
“Prior to launch, these simulations helped verify that the DART impact
would meet mission requirements even in impact circumstances that are not
ideal,” adds Joshua Lyzhoft of Goddard, who performs dynamics simulation
development, modeling, and analysis for DART. “We will also be updating the
simulations during the mission using observations to help ascertain how much
DART's impact changed the momentum of Dimorphos, which is an important goal of
the mission.”
The double asteroid dynamics algorithms and code are very complex and
computationally intensive, according to the team. “One of the important
features Goddard added to the code is the ability to execute it using parallel
distributed computing so that the simulations complete in reasonable amounts of
time,” said Barbee. “When the system is observed post-impact that will be the
first time such impact effects are observed and the first time such
observations will be compared to and used to calibrate dynamics simulations for
a double asteroid.”
The spacecraft will intercept Didymos’ moonlet in late September 2022,
when the Didymos system is within about 6.8 million miles (11 million
kilometers) of Earth, enabling observations by ground-based telescopes and
planetary radar to measure the change in momentum imparted to the moonlet.
Goddard scientists will be performing additional observations to add to the
mission’s scientific return. “We’ll determine the amount of dust released
during impact, as well as the amount and nature of any potential volatiles,
through high-resolution radio-telescope observations with the Atacama Large Millimeter Array (ALMA) as well as
other radio (millimeter/submillimeter) facilities,” said Stefanie Milam of
Goddard, who is part of the DART supporting observations working group and
co-investigator on the ALMA program. “Additionally, there will be observations
with the James Webb Space Telescope of Didymos during
and after impact to also monitor dust released during the event.” Milam also
supports the Webb Guaranteed Time Observations team (PI: Thomas/NAU).
“The dust and volatile observations from Webb (near-infrared wavelengths)
and ALMA (submillimeter wavelengths) will help us to understand the composition
of the asteroid as well as the speed, direction, and nature of the material
ejected by the impact,” said Nathan Roth of Goddard, also a member of the DART
supporting observations working group and principal investigator of the ALMA
program. “Based on the brightness of the asteroid at each wavelength, we’ll be
able to understand the size distribution of dust particles in the ejecta. With
high-resolution imaging from Webb, we’ll be able to understand jets or other
structures in the ejecta. With molecular spectroscopy (analysis of light
released by molecules) from ALMA, we’ll be able to measure the content of any
trace ices present beneath the surface of Dimorphos as well as any gas-phase
molecules produced by the impact.”
More about the mission and partners:
The binary asteroid simulation dynamics code was developed jointly by
DART's Dynamics Working Group, which is led by Prof. Derek Richardson of the
University of Maryland, College Park. The core code was originally developed
by Alex B. Davis and Daniel J. Scheeres at the University of Colorado,
Boulder, who are also members of the Dynamics Working Group. DART’s
Observations Working Group is chaired by Prof. Cristina Thomas of Northern
Arizona University.
Johns Hopkins APL manages the DART mission for NASA's Planetary Defense Coordination Office as a project of the agency’s Planetary Missions Program Office. NASA provides support for the mission from several centers, including the Jet Propulsion Laboratory in Southern California, Goddard Space Flight Center in Greenbelt, Maryland, Johnson Space Center in Houston, Glenn Research Center in Cleveland, and Langley Research Center in Hampton, Virginia. The launch is managed by NASA’s Launch Services Program, based at the agency’s Kennedy Space Center in Florida. SpaceX is the launch services provider for the DART mission.
Bill Steigerwald
NASA Goddard Space
Flight Center, Greenbelt, Maryland
Source: https://www.nasa.gov/feature/goddard/2021/dart-goddard
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