The Chemistry and Camera tool is known as ChemCam. ChemCam's laser, camera and spectrograph work together to identify the chemical and mineral composition of rocks and soils.

Tech Specs

Main Job
To analyze the chemical composition of rocks and soil.
The laser, telescope, and camera sit on Curiosity's mast (its "forehead"), while the spectrometer is located in its "body".
Components Telescope:
Focuses laser and camera

Remote Micro-Imager:
One of Curiosity's "eyes," captures detailed images of the area illuminated by the laser beam

Vaporizes rock surfaces, creating a plasma of their component gases

Three spectrographs divide the plasma light into wavelengths for chemical analysis

Chemistry & Camera (ChemCam)

Laser-Induced Remote Sensing
Laser-Induced Remote Sensing: The Laser-Induced Remote Sensing for Chemistry and Micro-Imaging instrument will identify atomic elements in martian rocks. Credit: NASA/JPL-Caltech/LANL/J.-L. Lacour, CEA
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Looking at rocks and soils from a distance, ChemCam fires a laser and analyzes the elemental composition of vaporized materials from areas smaller than 1 millimeter on the surface of Martian rocks and soils. An on-board spectrograph provides unprecedented detail about minerals and microstructures in rocks by measuring the composition of the resulting plasma -- an extremely hot gas made of free-floating ions and electrons.

ChemCam also uses the laser to clear away dust from Martian rocks and a remote camera to acquire extremely detailed images. The camera can resolve features 5 to 10 times smaller than those visible with cameras on NASA's two Mars Exploration Rovers that began exploring the red planet in January 2004. In the event the Mars Science Laboratory rover can't reach a rock or outcrop of interest, ChemCam has the capability to analyze it from a distance.

From 23 feet (7 meters) away, ChemCam is able to:

  • rapidly identify the kind of rock being studied (for example, whether it is volcanic or sedimentary);
  • determine the composition of soils and pebbles;
  • measure the abundance of all chemical elements, including trace elements and those that might be hazardous to humans;
  • recognize ice and minerals with water molecules in their crystal structures;
  • measure the depth and composition of weathering rinds on rocks; and,
  • provide visual assistance during drilling of rock cores.
First Laser-Zapped Rock on Mars
First Laser-Zapped Rock on Mars: This composite image, with magnified insets, depicts the first laser test by the Chemistry and Camera, or ChemCam, instrument aboard NASA's Curiosity Mars rover.
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The ChemCam instrument has two parts: a mast package and a body unit. On the mast is a telescope to focus the laser and the camera, a laser for vaporizing surfaces, and a remote micro-imager. The mast package can be tilted or rotated as needed for optimum viewing of the rock.

Light from the telescope travels along a fiber-optic link to a body unit inside the rover. The body unit carries three spectrographs for dividing the plasma light into its constituent wavelengths for chemical analysis. The body unit also has its own power supply and an electronic interface to the rover's central computer system.

Developing the ChemCam instruments for NASA were the Los Alamos National Laboratory (LANL) and the Centre d'Etude Spatiale des Rayonnements (CESR), with major contributions from JPL, Ocean Optics Inc., and the Commissariat a l'Energie Atomique (CEA).

Example of a Spectrum from Curiosity's ChemCam Instrument
Example of a Spectrum from Curiosity's ChemCam Instrument: This image provides an example of the type of data collected by the Chemistry and Camera (ChemCam) instrument on the Mars Science Laboratory mission's Curiosity rover. Credit: NASA/JPL-Caltech/LANL
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