Perseverance’s Arm at Work: NASA’s Perseverance Mars rover makes use of SHERLOC – one in every of a number of devices on the tip of its robotic arm – to check rocks in an space nicknamed “Skinner Ridge.” Credit: NASA/JPL-Caltech/ASU/MSSS
A cutting-edge instrument known as SHERLOC, which hunts for molecules doubtlessly associated to historic life, performed a key function in a current examine.
In its first 400 days on Mars, NASA’s Perseverance rover may have found a diverse collection of organics – carbon-based molecules considered the building blocks of life – thanks to SHERLOC, an innovative instrument on the rover’s robotic arm. Scientists with the mission, which is searching for evidence that the planet supported microbial life billions of years ago, aren’t sure whether biological or geological sources formed the molecules, but they’re intrigued.
Short for Scanning Habitable Environments with Raman & Luminescence for Organics & Chemicals, SHERLOC helps scientists decide whether a sample is worth collecting. This makes the instrument essential to the Mars Sample Return campaign. The Perseverance rover is the first step of the campaign, a joint effort by NASA and ESA (European Space Agency) that seeks to bring scientifically selected samples back from Mars to be studied on Earth with lab equipment far more complex than could be sent to the Red Planet. The samples would need to be brought back to confirm the presence of organics.
A Mineral Map Created by SHERLOC: Each color in this image represents a different mineral mapped across a rock’s surface. The mineral map was made by the SHERLOC instrument in
a test prior to NASA’s Perseverance rover launching to Mars. Credit: NASA/JPL-Caltech
SHERLOC’s capabilities center on a technique that looks at the chemical makeup of rocks by analyzing how they scatter light. The instrument directs an ultraviolet laser at its target. How that light is absorbed and then emitted – a phenomenon called the Raman effect – provides a distinctive spectral “fingerprint” of different molecules. This enables scientists to classify organics and minerals present in a rock and understand the environment in which the rock formed. Salty water, for example, can result in the formation of different minerals than fresh water.
After SHERLOC captures a rock’s textures with its WATSON (Wide Angle Topographic Sensor for Operations and eNgineering) camera, it adds data to those images to create spatial maps of chemicals on the rock’s surface. The results, detailed in a recent paper published in the journal Nature, have been as promising as the instrument’s science team had hoped.
SHERLOC’s Data: Within a rock target called “Garde,” different kinds of carbon-based molecules called organic compounds were viewed by SHERLOC, one of the instruments on the end of the robotic arm aboard NASA’s Perseverance Mars rover. Credit: NASA/JPL-Caltech/MSSS/LANL/PhotonSys
“These detections are an exciting example of what SHERLOC can find, and they’re helping us understand how to look for the best samples,” said lead author Sunanda Sharma of NASA’s Jet Propulsion Laboratory in Southern California. JPL built SHERLOC along with the Perseverance rover.
Close-up of SHERLOC: This close-up view of the SHERLOC instrument located at the end of the robotic arm on NASA’s Perseverance rover was captured prior to the rover’s launch to Mars. Credit: NASA/JPL-Caltech
NASA’s Curiosity rover, which landed on Mars in 2012, has confirmed the presence of organic molecules several times in Gale Crater, 2,300 miles (3,700 kilometers) away from Perseverance. Curiosity relies on SAM, or the Sample Analysis on Mars, an instrument in its belly that heats up powderized rock samples and performs a chemical analysis on the resulting vapor.
Because Perseverance’s scientists are looking for rocks that may have preserved signs of ancient microbial life, they want to leave the samples intact for closer study on Earth.
Getting to the Core
The new Nature paper looks at 10 rock targets SHERLOC studied, including one nicknamed “Quartier.”
“We see a set of signals that are consistent with organics in the data from Quartier,” Sharma said. “That grabbed everyone’s attention.”
NASA’s Perseverance Mars rover captured this image of a rock target nicknamed “Quartier” with the WATSON (Wide Angle Topographic Sensor for Operations and eNgineering) camera belonging to an instrument called SHERLOC (Scanning Habitable Environments with Raman & Luminescence for Organics & Chemicals). The rover uses a tool to abrade the surface of a rock (as with the circular portion in this image), removing dust, debris and other material that has settled on the rock’s outer surface. After that’s complete, instruments like SHERLOC can study the rock’s composition. The white squares show areas where SHERLOC performed multiple scans with its ultraviolet laser. Credit: NASA/JPL-Caltech/MSSS
When data that comes back from SHERLOC and other instruments looks promising, the science team then decides whether to use the rover’s drill to core a rock sample that’s about the size of a piece of classroom chalk. After analyzing Quartier, they took rock-core samples “Robine” and “Malay” from the same rock – two of the 20 core samples collected so far (learn more with the sample dashboard).
Picking out a good target to collect a sample from isn’t as simple as looking for the most organic molecules. Ultimately, Perseverance’s scientists want to collect a set of samples that’s representative of all the different areas that can be found within Jezero Crater. That breadth will provide context for future scientists studying these samples, who will wonder what changes occurred around any samples that might indicate signs of ancient life.
“The value comes from the sum rather than any individual sample,” Sharma said. “Pointillism is a good analogy for this. We’re eventually going to step back and see the big picture of how this area formed.”
Reference: “Diverse organic-mineral associations in Jezero crater, Mars” by Sunanda Sharma, Ryan D. Roppel, Ashley E. Murphy, Luther W. Beegle, Rohit Bhartia, Andrew Steele, Joseph Razzell Hollis, Sandra Siljeström, Francis M. McCubbin, Sanford A. Asher, William J. Abbey, Abigail C. Allwood, Eve L. Berger, Benjamin L. Bleefeld, Aaron S. Burton, Sergei V. Bykov, Emily L. Cardarelli, Pamela G. Conrad, Andrea Corpolongo, Andrew D. Czaja, Lauren P. DeFlores, Kenneth Edgett, Kenneth A. Farley, Teresa Fornaro, Allison C. Fox, Marc D. Fries, David Harker, Keyron Hickman-Lewis, Joshua Huggett, Samara Imbeah, Ryan S. Jakubek, Linda C. Kah, Carina Lee, Yang Liu, Angela Magee, Michelle Minitti, Kelsey R. Moore, Alyssa Pascuzzo, Carolina Rodriguez Sanchez-Vahamonde, Eva L. Scheller, Svetlana Shkolyar, Kathryn M. Stack, Kim Steadman, Michael Tuite, Kyle Uckert, Alyssa Werynski, Roger C. Wiens, Amy J. Williams, Katherine Winchell, Megan R. Kennedy and Anastasia Yanchilina, 12 July 2023, Nature.
DOI: 10.1038/s41586-023-06143-z
More About the Mission
A primary goal of Perseverance’s mission on Mars is astrobiology, including the search for signs of ancient microbial life. The rover will characterize the planet’s geology and past climate, setting the stage for human exploration of Mars, and be the first to collect and cache Martian rock and regolith.
Future NASA missions, in partnership with the ESA, plan to send spacecraft to Mars to retrieve these sealed samples and return them to Earth for comprehensive analysis. The Mars 2020 Perseverance mission is part of NASA’s broader Moon to Mars exploration approach, which includes Artemis missions to the Moon to prepare for human exploration of Mars. JPL, managed for NASA by Caltech in Pasadena, California, built and oversees operations of the Perseverance rover.
