Space Dynamics Lab Involved In Historic Asteroid Debris Retrieval

October 22, 2020 |

On a clear fall evening in September 2016, NASA launched a spacecraft to a distant asteroid to help answer questions central to the human experience: Where did we come from, and what is our destiny? With aid from the Space Dynamics Laboratory at Utah State University, the agency is one step closer to answering those questions.

Under the leadership of the University of Arizona’s Lunar and Planetary Laboratory, NASA’s Origins, Spectral Interpretation, Resource Identification, Security-Regolith Explorer spacecraft (OSIRIS-REx) extended its articulated robotic arm on October 21 at approximately 6:12 pm EDT to collect debris, called regolith, from the surface of asteroid Bennu.

SDL built the camera electronics for a three-camera suite onboard OSIRIS-REx named OCAMS.

The onboard cameras SDL helped to build are known as PolyCam, MapCam, and SamCam. PolyCam enabled NASA to acquire images of Bennu from approximately 1.2 million miles away and assisted with the spacecraft’s navigation to the asteroid during approach.

OCAMS detector assemblies. Photos courtesy of Space Dynamics Laboratory.

MapCam was responsible for searching the asteroid for a suitable place to collect the sample. MapCam also mapped Bennu and searched for outgassing plumes and other debris ejected from the asteroid.

SamCam is a close-range camera that verified the sample acquisition and will image the sampling mechanism.

The Touch-And-Go Sample Acquisition Mechanism, TAGSAM, is the arm on the spacecraft responsible for collecting Bennu’s regolith sample and includes a round sampler head at the end. During the touch-and-go maneuver, the sampler head was extended toward Bennu.

The momentum of the spacecraft’s slow, downward trajectory pushed the sampler head against the asteroid’s surface for about ten seconds—just long enough to obtain a sample. At contact, the spacecraft fired nitrogen gas onto the surface to roil up dust and small pebbles, which were then captured.

Artistic rendition of OSIRIS-REx in space. Image is courtesy of NASA/GSFC/UA.

OSIRIS-REx fired its thruster to back away from Bennu’s surface, and now the mission team will measure the sample amount by spinning the spacecraft with the collection arm extended. The team will compare the change in the spacecraft’s inertia with a previous, empty TAGSAM spin to ensure that enough sample was collected. The TAGSAM head will then be placed in the Sample Return Capsule for return to Earth. After successful stowage, the spacecraft will slowly drift away from Bennu to a safe distance, where it will stay until its departure in 2021 for the Return Cruise Phase back to Earth.

This view of asteroid Bennu ejecting particles from its surface on January 19, 2019 was created by combining two images taken on board OSIRIS-REx spacecraft. Other image processing techniques were also applied, such as cropping and adjusting the brightness and contrast of each image. Image is courtesy of NASA/Goddard/University of Arizona/Lockheed Martin.

Why Bennu?

Currently about 207 million miles away from Earth, asteroid Bennu is a carbon-based asteroid whose regolith may contain evidence of our solar system’s primeval history. Contained within its regolith could be clues that Bennu may also have molecular precursors to the origin of life and Earth’s oceans, scientists believe.

With a polar diameter of approximately 510 meters—the Empire State Building is 443 meters tall—Bennu is also one of the most potentially hazardous asteroids and has a relatively high probability of impacting Earth late in the 22nd century. OSIRIS-REx will determine Bennu’s physical and chemical properties, which will be critical knowledge in the event of an impact mitigation mission.

According to NASA, asteroids such as Bennu contain natural resources such as water, organics, and precious metals. In the future, these asteroids may fuel solar system exploration by robotic and crewed spacecraft.

The OSIRIS-REx Sample Return Capsule will land in Utah’s West Desert in 2023. SDL has been solving the technical challenges faced by the military, science community, and industry for six decades and supports NASA’s mission to drive advances in science, technology, aeronautics, and space exploration to enhance knowledge, education, innovation, economic vitality and stewardship of Earth. As one of 14 University Affiliated Research Centers, SDL serves as a subject matter expert in its core research areas to the U.S. Government, ensuring that essential engineering and technology capabilities are maintained. SDL is a research laboratory headquartered in North Logan, Utah, and has offices in Albuquerque, New Mexico; Bedford, Massachusetts; Colorado Springs, Colorado; Dayton, Ohio; Huntsville, Alabama; Houston, Texas; Los Angeles, California; Stafford, Virginia; and Washington, DC. For more information, visit

Executive Comment

It is incredibly exciting to be involved with missions like OSIRIS-REx,” said Alan Thurgood, SDL’s Civil and Commercial Space division director. “Being a part of exciting science with historically significant missions and pushing human knowledge forward motivates our team at SDL to do great work.”

The successful collection of regolith from Bennu perfectly illustrates the ingenuity of the dedicated men and women from America’s storied space program, who routinely collaborate in order to provide valuable science,” said Jed Hancock, SDL’s Executive Director of programs and operations. “SDL is honored to be a part of this historic mission that builds upon our decades-long partnership with NASA and helps the agency achieve its vision to ‘reach for new heights and reveal the unknown for the benefit of humankind.’”

An illustration of what the OSIRIS-REx TAGSAM maneuver might look like as the spacecraft descends down to Bennu to collect a sample. Image is courtesy of NASA/GODDARD/UNIVERSITY OF ARIZONA.