Thirty-four years after scientists first conceived it, the Fred Young Submillimeter Telescope (FYST) now rises above the Atacama Desert, near the summit of Cerro Chajnantor in Chile's Parque Astronómico Atacama.
FYST will help answer some of the most important questions in astronomy, including how the universe works, the nature of dark energy and dark matter, how galaxies form and evolve and what happened in those mysterious first moments after the Big Bang.
A celebration of the telescope took place April 9 on Cerro Chajnantor at the Atacama Large Millimeter/submillimeter Array Telescope facility, with more than 100 attendees, including international dignitaries, project supporters and scientists from the U.S., Germany, Canada and Chile, underscoring the global effort behind this milestone achievement.
FYST is a project of the Cornell-led CCAT Observatory, Inc., a collaboration that includes Germany's University of Cologne, University of Bonn and Max Planck Institute for Astrophysics in Garching, and a Canadian consortium of universities led by the University of Waterloo, in conjunction with Chilean astronomers through the University of Chile.
"When we first went there and realized what an exceptional site Cerro Chajnantor might be, submillimeter astronomy as a field wasn't advanced enough for us to be able to build the telescope and its instruments. But now it is, and we have FYST to show for our patience and determination," said Dr. Martha Haynes, president of the CCAT board and distinguished professor emeritus at Cornell.
The telescope features an innovative optical design that allows astronomers to observe over a wide field-of-view in each exposure, enabling them to rapidly and efficiently map wide areas of the sky. Operating in the submillimeter wavelength range of light, FYST will create movies of the sky - "celestial cinematography" - in a part of the electromagnetic spectrum where this has never before been done.
At a height of 5,640 meters above sea level, FYST lies above most of the atmospheric layers that block submillimeter waves from reaching the ground. The Atacama Desert's extremely dry air will provide exceptional views, without water vapor to obscure the signal.
Building a major new telescope at this elevation presented a significant challenge. Atmospheric pressure at the summit of Cerro Chanjantor is less than half what it is at ground level, which required construction workers, and all visitors to the site, to pass a strict physical examination and use supplemental oxygen at the summit.
The telescope's Prime-Cam instrument can hold up to seven changeable modules, giving FYST unmatched flexibility as a platform for new technologies. The instrument will provide unprecedented spectroscopic and broadband measurement capabilities to address fundamental questions in astrophysics and cosmology.
The CCAT Heterodyne Array Instrument (CHAI), developed by the University of Cologne, is a high resolution spectrometer used to study the cycle of interstellar matter in the Milky Way and nearby galaxies. The large number of pixels, high sensitivity and choice of spectral lines available with CHAI will, for the first time, trace the flows of interstellar gas to probe how the process of star formation may vary In different galactic environments
"FYST is the culmination of decades of engagement of the University of Cologne in submillimeter-wave astrophysics in Chile. Alongside our partners at Cornell, we are excited to present this milestone in technology development, which will revolutionize our view of the sky at this important, but underexplored wavelength regime - from a site whose observing conditions are rivaled only by the vacuum of space," said Dr. Dominik Riechers, professor of astrophysics at the University of Cologne and CCAT board member.
CPI Vertex Antennentechnik GmbH, in Duisburg, Germany designed and manufactured the telescope structure, including its drive and control systems. The company invested more than 250,000 hours in design, materials engineering, simulation, manufacturing, qualification and project coordination - contributing to the technological record-breaking achievements that make the system unique worldwide.
Because of the challenges of working at the extreme altitude, engineers first assembled the telescope in Germany. The team then disassembled it into large pieces and transported them by barge and then cargo ship to Chile, where workers trucked the pieces - the heaviest of which weighed 60 tons - up the mountain, a feat of careful coordination.
"The Canadian CCAT team, at over a dozen institutions across the country, is eagerly awaiting the wealth of fantastic data that will begin to flow from FYST in a few months," said Dr. Michel Fich, professor emeritus of physics at the University of Waterloo and Canadian CCAT project leader. "In addition to significant contributions to the construction of the telescope itself, the Canadian team is also creating software for both the Observatory and for data reduction, providing a central part of the telescope instrumentation, and leading key science projects."
"FYST will create a globally unique observatory that will set new standards in submillimeter astronomy," said Dr. Frank Bertoldi, professor of radioastronomy at the University of Bonn and CCAT board member. "We are proud that the University of Bonn is involved in this project, and we are excited to see the results of the planned deep sky surveys, which will tell us more about the formation of stars and galaxies, the evolution of cosmic structures and the origin of the universe."
