The James Webb Space Telescope is the largest, most powerful and complex space telescope ever built. It is expected to launch from the European Spaceport located near Kourou, French Guiana, no earlier than Saturday, Dec. 25, at 5:20 a.m. Mountain Time on the Ariane 5 rocket. Its destination is an orbit around the Sun-Earth second Lagrange point.
Webb, which is led by NASA with its partners, the European Space Agency and the Canadian Space Agency, will serve as the premier deep space observatory for the next decade, exploring every phase of cosmic history — from within our solar system to the most distant observable galaxies in the early universe, and everything in between.
Arizona State University Regents Professor Rogier Windhorst of the School of Earth and Space Exploration is a co-investigator and interdisciplinary scientist for Webb. He is joined by Research Scientist Rolf Jansen and Assistant Research Scientist Seth Cohen, along with a team of ASU postdoctoral scholars, undergraduate students and graduate students working on this mission.
“Rarely in a lifetime does one get a chance to be part of a major scientific mission that has the potential to be a total game changer in science,” Windhorst said. “The Hubble Space Telescope has been such a mission rewriting all textbooks in astronomy, and it is now coming to the dusk of its lifetime after 31 years in low Earth orbit. We currently live in an era where we are lucky enough to be able to witness two such missions with the launch of Webb.”
To celebrate this historic launch and highlight ASU’s involvement in this mission, ASU will hold a live launch event via Zoom with Windhorst and his team. In addition to play by play narration of the launch, the event will feature interviews with the ASU Webb team, live NASA coverage of the event and a public Q&A with the ASU Webb scientists. The event is free and open to the public. Pre-registration is encouraged.
The greatest origin story of all unfolds with the James Webb Space Telescope. Credit: NASA's Goddard Space Flight Center
A mirror this large has never before been launched into space
The Webb telescope consists of 18 mirror segments, which when combined, are over 21 feet in diameter. A mirror this large has never before been launched into space. After launch, the telescope will begin a three-day deployment process a month-long million-mile journey to its orbit around the sun in the second Lagrange (L2) point, where it will be locked into perfect unison with the Earth’s yearly orbit.
This orbit allows one side of Webb’s sunshield to always face the sun, Earth and moon, blocking their heat and light from reaching the telescope’s heat-sensitive optics. L2 is one of five positions in space where the gravitational pull of the sun and Earth balances the centripetal force required for a spacecraft to move with them, which is useful for reducing the fuel required for a spacecraft to remain in position. This orbit enables continuous communications with Webb through the Deep Space Network, an international array of giant antennas managed by NASA’s Jet Propulsion Laboratory.
Engineers on the ground will remotely orchestrate a complex sequence of deployments in the hours and days immediately after the launch of the James Webb Space Telescope. Credit: NASA's Goddard Space Flight Center
Webb’s powerful instruments: A combination of sheer size and sensitivity
Webb is an infrared telescope with unprecedented scientific power due to the size of its primary mirror and the extreme sensitivity and precision of its four scientific instruments. There are three near-infrared instruments (NIRCam, NIRSpec and FGS/NIRISS) and one mid-infrared instrument (MIRI), which will receive the light collected by the telescope and use a variety of tools – cameras, spectrographs, coronagraphs and other specialized pieces – designed to maximize the scientific knowledge gained from every observation. Each instrument also has a field of view that is unique in area, shape and orientation.
The ASU team will be working with NIRCam, Webb's primary imager that will detect light from the earliest stars and galaxies in the process of formation, the population of stars in nearby galaxies, as well as young stars in the Milky Way and Kuiper Belt objects.
“What makes Webb and its instruments so powerful is the combination of sheer size and sensitivity to near- and mid-infrared wavelengths to which Hubble is blind,” said Jansen, who is the team lead for the Webb North Ecliptic Pole Time-Domain Field. “Webb's compound mirror collects 6.25 times more light than Hubble's, so it can detect fainter objects. And at the wavelengths where Webb and Hubble overlap, Webb's view is up to 2.7 times sharper.”
That capability is needed for the team to detect the very first clumps of stars or protogalaxies that lit up the universe.
“Those objects were much smaller and fainter than the galaxies we see in the local universe,” Jansen said. “So we need a very large telescope mirror and sharp vision to discern the shapes and nature of those first objects.”
For Cohen, his role on the team will be to process the data from NIRCam for detailed analysis and to catalog the galaxies detected by this instrument.
“More than a decade ago, our group did simulations of what we expect faint galaxies to look like with Webb, and I am excited to see how close we come to the predictions,” he said. “Beyond that, I look forward to the unknown and the surprises that a scientific instrument of this scale will undoubtedly deliver.”
And the wait for images will not be long after launch. Webb will begin gathering its first set of scientific observations after its commissioning process is complete, roughly six months after launch when all the mirrors have been aligned and all the instruments have been calibrated.
“We all have very high expectations of Webb,” Windhorst said. “In addition to revealing the secrets of the targets that we have planned for Webb to observe, perhaps most importantly, we hope that Webb will rewrite the science textbooks in ways that we could not have foreseen.''
ASU Webb researchers Windhorst and Jansen on what we can expect to learn from the James Webb Space Telescope. Credit: ASU/NASA
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