Spectra also tell us an immense amount about galaxies, including very distant galaxies as they existed in the early universe. In the graphs below, we’ve plotted the light gathered from three spiral galaxies. The large black arrows at the left of each spectrum emphasize how far the light from each galaxy has redshifted, or stretched into longer, redder wavelengths due to the expansion of the universe, before reaching the telescope.
The first sample spiral galaxy at the top is the closest to Earth. Its light existed a mere 480 million years after the big bang, which happened more than 13.8 billion years ago. The light observed in the second shows it as it existed only 420 million years after the big bang. The third is the most distant. Its light reflects this spiral galaxy as it existed only 370 million years after the big bang. Although the light from each galaxy was redshifted, we still observe the galaxies as they were when that light was emitted—when the galaxies were young. By comparing galaxies that existed at various times in the universe we can understand how they change over time.
Webb’s microshutter array is not only designed to capture these longer wavelengths of light, known as infrared, but will also be able to accurately sample the light from each galaxy simultaneously to help researchers identify their type (spiral, elliptical, or irregular), their distances from Earth, their ages, and their redshifts.
Learn firsthand how scientists use spectra to learn about the universe by visiting the Be the Scientist: Microshutters Interactive page.
Credits
Image
NASA, ESA, CSA, Andi James (STScI)