James Webb Space Telescope completes final cryogenic testing

NASA's James Webb Space Telescope completes final cryogenic testing
NASA's James Webb Space Telescope sits inside Chamber A at NASA's Johnson Space Center in Houston after having completed its cryogenic testing on Nov. 18, 2017. This marked the telescope's final cryogenic testing, and it ensured the observatory is ready for the frigid, airless environment of space. Credit: NASA/Chris Gunn

The vault-like, 40-foot diameter, 40-ton door of Chamber A at NASA's Johnson Space Center in Houston was unsealed on November 18, signaling the end of cryogenic testing for NASA's James Webb Space Telescope.

The historic chamber's massive door opening brings to a close about 100 days of testing for Webb, a significant milestone in the 's journey to the launch pad. The cryogenic vacuum test began when the chamber was sealed shut on July 10, 2017. Scientists and engineers at Johnson put Webb's optical telescope and integrated science instrument module (OTIS) through a series of tests designed to ensure the telescope functioned as expected in an extremely cold, airless environment akin to that of space.

"After 15 years of planning, chamber refurbishment, hundreds of hours of risk-reduction testing, the dedication of more than 100 individuals through more than 90 days of testing, and surviving Hurricane Harvey, the OTIS cryogenic test has been an outstanding success," said Bill Ochs, project manager for the James Webb Space Telescope at NASA's Goddard Space Flight Center in Greenbelt, Maryland. "The completion of the test is one of the most significant steps in the march to launching Webb."

These tests included an important alignment check of Webb's 18 primary mirror segments, to make sure all of the gold-plated, hexagonal segments acted like a single, monolithic mirror. This was the first time the telescope's optics and its instruments were tested together, though the instruments had previously undergone in a smaller chamber at Goddard. Engineers from Harris Space and Intelligence Systems, headquartered in Melbourne, Florida, worked alongside NASA personnel for the test at Johnson.

"The Harris team integrated Webb's 18 mirror segments at Goddard and designed, built, and helped operate the advanced ground support and optical test equipment at Johnson," said Rob Mitrevski, vice president and general manager of intelligence, surveillance, and reconnaissance at Harris. "They were a key, enabling part of the successful Webb telescope testing team."

The Webb telescope team persisted with the testing even when Hurricane Harvey slammed into the coast of Texas on Aug. 25 as a category 4 hurricane before stalling over eastern Texas and weakening to a tropical storm, where it dropped as much as 50 inches of rain in and around Houston. Many Webb telescope team members at Johnson endured the historic storm, working tirelessly through overnight shifts to make sure Webb's cryogenic testing was not interrupted. In the wake of the storm, some Webb team members, including team members from Harris, volunteered their time to help clean up and repair homes around the city, and distribute food and water to those in need.

"The individuals and organizations that have led us to this most significant milestone represent the very best of the best. Their knowledge, dedication, and execution to successfully complete the testing as planned, even while enduring Hurricane Harvey, cannot be overstated," said Mark Voyton, James Webb Space Telescope optical telescope element and integrated science instrument manager at Goddard. "Every team member delivered critical knowledge and insight into the strategic and tactical planning and execution required to complete all of the test objectives, and I am honored to have experienced this phase of our testing with every one of them."

Before cooling the chamber, engineers removed the air from it, which took about a week. On July 20, engineers began to bring the chamber, the telescope, and the telescope's science instruments down to cryogenic temperatures—a process that took about 30 days. During cool down, Webb and its instruments transferred their heat to surrounding liquid nitrogen and cold gaseous helium shrouds in Chamber A. Webb remained at "cryo-stable" temperatures for about another 30 days, and on Sept. 27, the engineers began to warm the chamber back to ambient conditions (near room temperature), before pumping the air back into it and unsealing the door.

"With an integrated team from all corners of the country, we were able to create deep space in our chamber and confirm that Webb can perform flawlessly as it observes the coldest corners of the universe," said Jonathan Homan, project manager for Webb's cryogenic testing at Johnson. "I expect [Webb] to be successful, as it journeys to Lagrange point 2 [after launch] and explores the origins of solar systems, galaxies, and has the chance to change our understanding of our universe."

While Webb was inside the chamber, insulated from both outside visible and infrared light, engineers monitored it using thermal sensors and specialized camera systems. The thermal sensors kept tabs on the temperature of the telescope, while the camera systems tracked the physical position of Webb to see how its components very minutely moved during the cooldown process. Monitoring the telescope throughout the testing required the coordinated effort of every Webb team member at Johnson.

"This test team spanned nearly every engineering discipline we have on Webb," said Lee Feinberg, optical telescope element manager for the Webb telescope at Goddard. "In every area there was incredible attention to detail and great teamwork, to make sure we understand everything that happened during the and to make sure we can confidently say Webb will work as planned in space."

In space, the telescope must be kept extremely cold, in order to be able to detect the infrared light from very faint, distant objects. Webb and its instruments have an operating temperature of about 40 Kelvin (or about minus 387 Fahrenheit / minus 233 Celsius). Because the Webb telescope's mid-infrared instrument (MIRI) must be kept colder than the other research instruments, it relies on a cryocooler to lower its temperature to less than 7 Kelvin (minus 447 degrees Fahrenheit / minus 266 degrees Celsius).

To protect the telescope from external sources of light and heat (like the Sun, Earth and Moon), as well as from heat emitted by the observatory, a five-layer, tennis court-sized sunshield acts like a parasol that provides shade. The sunshield separates the observatory into a warm, sun-facing side (reaching temperatures close to 185 degrees Fahrenheit / 85 degrees Celsius) and a cold side (minus 400 degrees Fahrenheit / minus 240 degrees Celsius). The sunshield blocks sunlight from interfering with the sensitive telescope instruments.

Webb's combined science instruments and optics next journey to Northrop Grumman Aerospace Systems in Redondo Beach, California, where they will be integrated with the spacecraft element, which is the combined sunshield and spacecraft bus. Together, the pieces form the complete James Webb Space Telescope observatory. Once fully integrated, the entire observatory will undergo more tests during what is called "observatory-level testing." This testing is the last exposure to a simulated launch environment before flight and deployment testing on the whole observatory.

Webb is expected to launch from Kourou, French Guiana, in the spring of 2019.


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NASA closes Chamber A door to commence Webb telescope testing

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Nov 20, 2017
At least they tested the optics for alignment etc. With all the shipping and moving around, with a segmented primary, they should probably test it again just before launch. We don't need to launch any more defective telescopes to fix later. Even if the mistake is perfect or not. Does anyone know if the Webb can be serviced over time to keep it operational? Might take a special vehicle to do that, which we probably don't have. Maybe they could use the Orion for this purpose. Have not kept up on all these projects like I should. This thing is getting launched by ESA? Don' t we have a heavy lift rocket for this? Better ESA than the Russians......

Nov 20, 2017
Don't crash don't crash don't crash

Nov 20, 2017
No plans to fix Webb, it will be at L2, a million miles away. They've got to get a 100 on this test.

Nov 20, 2017
The US has the launchers but ESA is launching as part of their contribution (saving US tax dollars).

Nov 20, 2017
Oh yeah, it is going to be a long ways out. And easy to forget ESA when NASA has done so much of just about everything. They better have major redundancy built into this one. I suppose they learned a lot about that from Hubble. Still, would be nice to service. Maybe they have banks of extra gyros and redundant secondary optics etc to prevent a costly hunk of space junk. Should be built to last 10 years a least. It should image some very neat things that went on a long time ago...............

Nov 20, 2017
If there was no limit to lift capability NASA would put massive redundancy in. Since there is a limit to the satellite mass, there is a trade off of redundancy and mission capability (eg how many wavelength bands/instruments can be incorporated into the satellite). If it survives launch and deployment, satellites usually last much longer than design life. Let's hope, if so, expect a number of Nobel prize winning discoveries.

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