The Hubble space telescope has a primary mirror of 2.4 meters. The Nancy Grace Roman telescope has one at 2.4 meters and the James Webb Space Telescope has a whopping 6.5 meter primary mirror. These are all fine and well to get the job done that they were designed for, but what if… we could have even bigger mirrors?
The larger the mirror, the more light is collected. This means that we can see farther back in time with bigger mirrors to observe star and galaxy formation, image exoplanets directly, and to work out just what dark matter is.
But the process for creating a mirror is involved and takes time. There is casting the mirror blank to get the basic shape. Then you have to toughen the glass by heating and slow cooling. Grinding the glass down and polishing it into its perfect shape comes next followed by testing and coating the lens. This isn’t so bad for smaller lenses, but we want bigger. Much bigger.
Enter the idea for using fluids to create lenses in space that are 10x – 100x bigger. And the time it would take to make them would be significantly less than a glass-based lens.
Optical lens for the Large Synoptic Survey Telescope (LSST) Image credit: Farrin Abbott/SLAC National Accelerator LaboratoryFLUTE, or the Fluidic Telescope Experiment is run by principal investigator Edward Balaban at Ames Research Center in California’s Silicon Valley. The experiment is being collaborated on by researchers at Ames at the Goddard Space Flight Center in Greenbelt, Maryland along with researchers from Technion, the Israeli Institute of Technology.
Their goal is to make possible the fabrication of fluid lenses in space that are not only bigger than their glass counterparts, but also just as high quality or better optically as making an earth-based lens. And this can be done in a fraction of the time.
Water droplet with food dye added in. Image credit: CNNIn space, liquids eventually form a perfect spherical shape. In order to test the process out first though, they stayed closer to home and used water as a medium to create fluid lenses. They had to make sure the water had the same density as the liquid polymers they were using to make the lenses so that the effects of gravity were effectively canceled out. Leaving out any mechanical processes, the polymers were injected into circular frames submerged in water and then solidified, creating comparable or better lenses than using standard techniques.
Next the team took flight on two ZeroG parabolic flights to further test the process. Synthetic oils of varying viscosities were used to determine which would work better. These oils were pumped into circular frames about the size of a dollar coin while the plane was in freefall and again they were able to make free-standing liquid lenses, though once the plane started lifting up again and the effects of gravity were felt the liquids lost their shape.
This experiment will be performed on the ISS (International Space Station) next and is already onboard, waiting for the arrival of Axiom-1 with Mission Specialist Eytan Stibbe slated to perform the experiment. There they will add the step of using either UV light or temperature to harden the liquid so that the lenses can be examined and tested by the researchers back at Ames on Earth.
A successful experiment will be the first time an optical component is made in space. If it succeeds, this will be the start of a new way to build telescopes, out in space. This would be a revolution in space-based manufacturing and the time needed to build one will be greatly reduced. And oh the sights we will see.
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