A NASA spacecraft that will return a sample of a near-Earth asteroid named Bennu to Earth in 2023 made the first-ever close-up observations of particle plumes erupting from an asteroids surface. Bennu also revealed itself to be more rugged than expected, challenging the mission team to alter its flight and sample collection plans, due to the rough terrain.
Bennu is the target of NASAs Origins, Spectral Interpretation, Resource Identification, Security-Regolith Explorer (OSIRIS-REx) mission, which began orbiting the asteroid on Dec. 31. Bennu, which is only slightly wider than the height of the Empire State Building, may contain unaltered material from the very beginning of our solar system.
The discovery of plumes is one of the biggest surprises of my scientific career, said Dante Lauretta, OSIRIS-REx principal investigator at the University of Arizona, Tucson. And the rugged terrain went against all of our predictions. Bennu is already surprising us, and our exciting journey there is just getting started.
Shortly after the discovery of the particle plumes on Jan. 6, the mission science team increased the frequency of observations, and subsequently detected additional particle plumes during the following two months. Although many of the particles were ejected clear of Bennu, the team tracked some particles that orbited Bennu as satellites before returning to the asteroids surface.
The OSIRIS-REx team initially spotted the particle plumes in images while the spacecraft was orbiting Bennu at a distance of about one mile (1.61 kilometers). Following a safety assessment, the mission team concluded the particles did not pose a risk to the spacecraft. The team continues to analyze the particle plumes and their possible causes.
The first three months of OSIRIS-RExs up-close investigation of Bennu have reminded us what discovery is all about surprises, quick thinking, and flexibility, said Lori Glaze, acting director of the Planetary Science Division at NASA Headquarters in Washington. We study asteroids like Bennu to learn about the origin of the solar system. OSIRIS-RExs sample will help us answer some of the biggest questions about where we come from.
OSIRIS-REx launched in 2016 to explore Bennu,which is the smallest body ever orbited by spacecraft. Studying Bennu will allow researchers to learn more about the origins of our solar system, the sources of water and organic molecules on Earth, the resources in near-Earth space, as well asimprove our understanding of asteroids that could impact Earth.
The OSIRIS-REx team also didnt anticipate the number and size of boulders on Bennus surface. From Earth-based observations, the team expected a generally smooth surface with a few large boulders. Instead, it discovered Bennus entire surface is rough and dense with boulders.
The higher-than-expected density of boulders means that the missions plans for sample collection, also known as Touch-and-Go (TAG), need to be adjusted. The original mission design was based on a sample site that is hazard-free, with an 82-foot (25-meter) radius. However, because of the unexpectedly rugged terrain, the team hasnt been able to identify a site of that size on Bennu. Instead, it has begun to identify candidate sites that are much smaller in radius.
The smaller sample site footprint and the greater number of boulders will demand more accurate performance from the spacecraft during its descent to the surface than originally planned. The mission team is developing an updated approach, called Bullseye TAG, to accurately target smaller sample sites.
Throughout OSIRIS-RExs operations near Bennu, our spacecraft and operations team have demonstrated that we can achieve system performance that beats design requirements, said Rich Burns, the project manager of OSIRIS-REx at NASAs Goddard Space Flight Center in Greenbelt, Maryland. Bennu has issued us a challenge to deal with its rugged terrain, and we are confident that OSIRIS-REx is up to the task.
The original, low-boulder estimate was derived both from Earth-based observations of Bennus thermal inertia or its ability to conduct and store heat and from radar measurements of its surface roughness. Now that OSIRIS-REx has revealed Bennus surface up close, those expectations of a smoother surface have been proven wrong. This suggests the computer models used to interpret previous data do not adequately predict the nature of small, rocky, asteroid surfaces. The team is revising these models with the data from Bennu.
The OSIRIS-REx science team has made many other discoveries about Bennu in the three months since the spacecraft arrived at the asteroid, some of which were presented Tuesday at the 50th Lunar and Planetary Conference in Houston and in a special collection of papers issued by the journal Nature.
The team has directly observed a change in the spin rate of Bennu as a result of what is known as the Yarkovsky-O’Keefe-Radzievskii-Paddack (YORP) effect. The uneven heating and cooling of Bennu as it rotates in sunlight is causing the asteroid to increase its rotation speed. As a result, Bennu’s rotation period is decreasing by about one second every 100 years. Separately, two of the spacecrafts instruments, the MapCam color imager and the OSIRIS-REx Thermal Emission Spectrometer (OTES), have made detections of magnetite on Bennus surface, which bolsters earlier findings indicating the interaction of rock with liquid water on Bennus parent body.
Goddard provides overall mission management, systems engineering, and the safety and mission assurance for OSIRIS-REx. Dante Lauretta of the University of Arizona, Tucson, is the principal investigator, and the University of Arizona also leads the science team and the missions science observation planning and data processing. Lockheed Martin Space in Denver built the spacecraft and is providing flight operations. Goddard and KinetX Aerospace are responsible for navigating the OSIRIS-REx spacecraft. OSIRIS-REx is the third mission in NASAs New Frontiers Program, which is managed by NASAs Marshall Space Flight Center in Huntsville, Alabama, for the agencys Science Mission Directorate in Washington.
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