A micrometeoroid that hit the Webb Space Ttelescope in late May caused permanent damage to the spacecraft, according to a Space Telescope Science Institute report.
The report was published last week by NASA and the European and Canadian space agencies. It described the telescope’s science performance up to July 12, 2022, the day the telescope’s first images were publicly released, and included an exciting first look of the planet Jupiter as seen by Webb.
According to the analysis, the impact “exceeded prelaunch expectations of damage for a single micrometeoroid.” The Webb team is now studying how to predict and mitigate future impacts.
Micrometeoroids are bits of rockk flying through space. When orbiting Earth, these rocks can reach sfeet of up to 22,000 miles per hour and are a regular hazard for astronauts, satellites, and spacecraft.
In early Junea NASA release stated that a micrometeoroid impacted one of the Webb telescope’s hexagonal mirrors between May 23 and May 25; the new report estimates the impact actually occurred between May 22 and May 24.
“We always knew that Webb would have to weather the space environment, which includes harsh ultraviolet light and charged particles from the Sun, cosmic rays from exotic sources in the galaxy, and occasional strikes by micrometeoroids within our solar system,” said Paul Geithner, a technical deputy project manager at NASA’s Goddard Space Flight Center, in a June release.
The Webb telescope’s mirrors were meticulously aligned in order to produce high-resolution images of very faint light sources in the distant universe. The recent report compared ground measurements of the mirror segments’ optical quality to the telescope’s current quality; they found significant error in the C3 segment.
Because the C3 segment is just one of 18 hexagonal mirrors making up the telescope’s primary mirror, the micrometeoroid damage is relatively small on the full telescope level, the report stated.
Despite the damage, the team’s initial assessment indicates that Webb “should meet its optical performance requirements for many years.” Thanks to the telescope’s precise launch, it’s expected to be operational for 20 years and will spend the entirety of its tenure at L2, a point in space about a million miles from Earth.
The big unknown, the team stated, is the rate of mirror degradation from micrometeoroids; in other words, how many more-harmful-than-expected space particles will hit the $10 billion observatory. At the time of the June statement about the May impact event, the team detected four micrometeoroid strikes that fell within their expectations for such events, but the larger event is cause for concern. If Webb is more susceptible to micrometeoroid impacts than scientists anticipatedits mirrors will degrade earlier than expected.
It’s possible that the team will turn Webb’s optics away from micrometeoroid strikes to protect its mirrors down the line, but for that to happen, the strikes need to be anticipated. Webb was severely delayed here on Earth, but for an observatory that was launched and commissioned without issue, it was only a matter of time before space threw the Webb scientists a curveball.
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