James Webb Space Telescope takes its first images and spectra of Mars
The European Space Agency (ESA) released the James Webb Space Telescope’s (JWST) first images and infrared spectrum of Mars. The Webb telescope captured its first images and spectra of the red planet on September 5, 2022.
Webb is situated approximately 1.5 million kilometres away from our planet at the second Sun-Earth Lagrange point (L2). From the telescope’s vantage point, it gets a view of Mars’ observable disk, which is the portion of the sunlit side facing the telescope. This allows JWST to capture images and spectra with the specific resolution needed to study short-term phenomena. These phenomena include dust storms, weather patterns, and seasonal changes.
While this may not sound impressive for a telescope that is designed to detect dant faint objects, it actually is. Mars is very close to the Earth and it is one of the brightest objects in the night sky, in both visible and infrared light. But since Webb’s instruments are so sensitive, the bright infrared light from Mars is almost blinding, causing something known as “detector saturation.”
Scients need to use special detection techniques in order to overcome this, including using very short exposures and measuring only some of the light that hits the detectors. They then used special data analysis techniques to arrive at the image.
JWST’s first images of Mars were captured the Near-Infrared Camera (NIRCam) and shows a part of the planet’s eastern hemisphere at two different wavelengths. The image above contains a surface reference map taken NASA’s Mars Global Surveyor on the left and two Webb NIRCam instrument fields overlaid on the right.
Spectrum data of Mars captured the James Webb Space Telescope. (Image credit: NASA, ESA, CSA, STScI, Mars JWST/GTO team)
The Webb images of Mars show differences in brightness over a large number of wavelengths from place to place across the planet at a particular date and time. But the spectrum illustrates the subtle variations in brightness between hundreds of different wavelengths that represent the planet as a whole. Astronomers will analyse features of the spectrum to gather additional information about the surface and atmosphere of the planet.