How scientists colorize photos of space

Vox

1 Aug 201905:48

Summary

TLDRThis video explores the fascinating world of color in space photography, focusing on how the Hubble Space Telescope captures and colorizes images. It explains how light, both visible and invisible, is filtered and processed to reveal details about distant celestial objects. Through broadband and narrowband filtering techniques, scientists create images that map out the chemical makeup of stars, gases, and galaxies. While these colors may not be what we would see with our own eyes, they represent real data that helps us understand the universe's structure and formation, showcasing the power of color in space exploration.

Takeaways

😀 Visible light is just a small fraction of all the light in the universe. Most light frequencies are invisible to the human eye.
😀 Our eyes have three types of cones that detect long, medium, and short wavelengths of light, corresponding to red, green, and blue, respectively.
😀 These three primary colors of light (red, green, and blue) form the basis for creating all other visible colors.
😀 Colorizing black and white images is done by combining separate photos taken through different colored filters, as demonstrated by Sergei Prokudin-Gorskii in 1911.
😀 The Hubble Space Telescope captures images of distant space objects using black-and-white images, which are later colorized based on light wavelength data.
😀 Filters on the Hubble telescope separate light into three basic ranges: long, medium, and short wavelengths, and assign them colors for a 'true color' image.
😀 The combination of red, green, and blue wavelengths creates various colors, such as yellow, cyan, and magenta, as seen in Hubble's images of planets like Saturn and Jupiter.
😀 Narrowband filtering is a technique used to map the presence of specific gases, like hydrogen, sulfur, and oxygen, in space, with each element assigned a color.
😀 Images like the Pillars of Creation are colorized to visualize the distribution of gases, helping scientists track the process of star formation.
😀 Colors in space images often represent real data about chemical composition or physical properties of objects, even if they aren't how our eyes would perceive the colors.
😀 The Hubble Space Telescope can also capture light outside the visible spectrum, such as ultraviolet and infrared, providing deeper insights into cosmic phenomena hidden from the naked eye.

Q & A

What is the visible spectrum of light?
-The visible spectrum of light refers to the range of light frequencies that humans can see, which spans from red at the lowest frequencies to violet at the highest frequencies.
How do the cones in our eyes contribute to color vision?
-The cones in our eyes interpret light reflecting off objects. There are three types of cones sensitive to long, medium, and short wavelengths of light, roughly corresponding to red, green, and blue, which are the primary colors of light.
What is the process behind colorizing black-and-white images?
-To colorize black-and-white images, scientists use a process similar to early photographic techniques. They take multiple black-and-white photos using filters for specific colors of light and then combine them to create a full-color image.
How were early color photographs created, such as the one taken by Sergei Prokudin-Gorskii in 1911?
-Sergei Prokudin-Gorskii used three black-and-white photographs taken with filters that allowed only specific colors of light (red, green, and blue) to pass through. The images were then combined to create a colorized version of the original scene.
Why does the Hubble Space Telescope take black-and-white images initially?
-The Hubble Space Telescope captures black-and-white images because its main function is to measure the brightness of light reflecting off objects in space, which is most clear in black and white. The color is added afterward through processing.
What is broadband filtering in the context of space imaging?
-Broadband filtering involves separating light into long, medium, and short wavelengths to capture general ranges of light. These images are then assigned colors based on their position in the visible spectrum to create 'true color' images.
What is the difference between true color imaging and narrowband filtering in space photography?
-True color imaging uses broadband filtering and combines black-and-white images to represent what an object would look like to the human eye. Narrowband filtering, on the other hand, isolates specific wavelengths from gases like hydrogen, sulfur, and oxygen, mapping their presence using colors that help scientists understand the chemical makeup of space objects.
How does narrowband filtering help scientists study star formation?
-Narrowband filtering allows scientists to track the presence of specific elements, such as hydrogen, sulfur, and oxygen, in space. By colorizing these elements differently, scientists can visualize and study processes like star formation in nebulae, such as the famous Pillars of Creation.
What role does infrared imaging play in space exploration?
-Infrared imaging captures light in the near-infrared spectrum, which can penetrate clouds of gas and dust that block visible light. This reveals structures such as star clusters that are hidden from view in the visible spectrum.
Are the colors used in space images always how we would perceive them?
-No, the colors used in space images are not always how we would perceive them with our eyes. While the colors represent real data and help scientists visualize chemical compositions and interactions, they are often colorized to enhance scientific understanding, not to reflect true visual appearances.