NASA's PUNCH spacecraft see a cosmic rainbow in the zodiacal light

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NASA's newest spacecraft aimed at studying the sun have captured a colorful "rainbow" in the warm glow of zodiacal light observed above Earth.
The PUNCH (Polarimeter to Unify the Corona and Heliosphere) mission, which launched on March 11, consists of four small satellites working in unison in low Earth orbit to provide a comprehensive view of the sun's corona, or outer atmosphere, and study the constant stream of charged particles emitted by the sun known as solar wind.
The mission delivered its first set of images, including a vivid, rainbow-colored view of the sky, according to a statement from NASA that shared PUNCH's latest images.
These images feature zodiacal light — the faint, diffuse glow created by sunlight scattering off dust particles in space. In one view captured by the PUNCH mission's WFI-2 instrument on April 18, a hazy glow transitions from red on the left to green in the center and blue on the right, set against a backdrop of stars.
The coloration of light in this image does not depict a true optical rainbow as would be seen by the naked eye, but rather a colored representation of different wavelengths of light that highlight the instrument's capability to analyze various components of the solar atmosphere.
The mission measures the corona and solar wind in three dimensions by studying the polarization of light, which is the direction light travels after it has been scattered by particles. The four satellites include one Narrow Field Imager (NFI), which blocks out the bright light from the sun to better see details in the corona.
On April 27, the NFI instrument captured the new moon as it passed by the sun, using its occulter (an object that blocks a direct view of the sun) to hide the solar disk. These early images help the PUNCH mission team calibrate the instruments and ensure they are working as expected.
The PUNCH spacecraft also include three Wide Field Imagers (WFIs), which are designed to see the very faint, outermost portion of the corona and solar wind. The WFI-1 and WFI-3 instruments also captured the soft glow of zodiacal light on April 16, with the Hyades and Pleiades star clusters and Andromeda galaxy in view.
The Andromeda galaxy can be seen as a faint wispy spiral on the far right of the image below. The 'W' shape of the Cassiopeia constellation can be made out at the top. The familiar Pleiades can be seen at the left side of the image.
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PUNCH launched on March 12, 2025 atop a SpaceX Falcon 9 rocket from Vandenberg Space Force Base in California. Riding alongside the four PUNCH satellites was another new NASA spacecraft, called SPHEREx.
Like the James Webb Space Telescope, SPHEREx — which stands for Spectro-Photometer for the History of the Universe, Epoch of Reionization and Ices Explorer — peers into the cosmos with infrared eyes. Unlike the James Webb Space Telescope, however, SPHEREx is designed to take in a wide view of the universe in order to create a new map of the visible sky.
"We are literally mapping the entire celestial sky in 102 infrared colors for the first time in humanity's history," Nicky Fox, associate administrator for NASA's Science Mission Directorate, said during a conference about SPHEREx on Jan. 31.

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Every other domain on Earth, we maintain, we sustain, we grow. Not in space." In 2023, Arkisys secured a $1.6 million deal from the U.S. Space Force to test satellite assembly in orbit using the Port demo module — a basic building block of a scalable orbiting garage and gas station. The company wants to launch the first component of this orbital depot next year — a last-mile transportation device called the Cutter, which is designed to help satellites to dock with the garage. In 2027, the main Port module, a hexagonal structure about 9 feet (3 meters) wide, will join the Cutter in orbit to test how the mechanical interfaces of the two work together in space. The Port, in addition to serving as a fuel depot, will arrive with a supply of components and payloads that could be attached to worn-out satellites to give them a new lease on life. "Today, everything on a satellite is done on the ground, and the satellite is launched with an end date," Barnhart said. "We want to shift that to allow extensions of both — life and business — post-launch. We want to be able to add new revenue streams post-launch. You can do that if you can add something, change something in orbit, or even sell that satellite to somebody else who could make it part of a larger platform." Cameras or antennas could be replaced with more powerful ones once those get developed, worn-out batteries could be swapped for brand-new ones, and fuel tanks would get refilled. It all makes sense on paper, but Dafni Christodoulopoulou, space industry analyst at the consultancy company Analysis Mason, warns that whether satellite operators would be inclined to ditch their disposable ways will come down to the cost of the in-orbit maintenance services. LEO is currently dominated by small, relatively cheap satellites, she says, which can be replaced more cheaply than they can be serviced and maintained. 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The two missions, designed to test hardware developed by Orbit Fab, Astroscale and Northrop Grumman, are set to launch in 2026 and 2027, respectively. In addition, intensifying geopolitical tensions are increasing the need for quick deployment of new systems in space, which, Barnhart says, could be more speedily addressed with servicing systems such as the Port, than by building new spacecraft from scratch on Earth. "If there is a new threat that has been identified, you might need a new type of sensor or a new payload to observe it," Barnhart said. "If we can augment the satellites that the government has already put up and provide them with a new capability, a new sensor, we can address those threats much faster." Christodoulopoulou thinks that new regulations designed to protect the environment and curb the air pollution related to satellite reentries could further help move the needle toward a less throwaway culture in space utilization. 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