New Canadian telescope will map largest volume of space ever surveyed

A Canadian effort to build one of the most innovative radio telescopes in the world will open the universe to a new dimension of scientific study. The Honourable Kirsty Duncan, Minister of Science, today installed the final piece of this new radio telescope, which will act as a time machine allowing scientists to create a three-dimensional map of the universe extending deep into space and time.

The Canadian Hydrogen Intensity Mapping Experiment, known as CHIME, is an extraordinarily powerful new telescope. The unique “half-pipe” telescope design and advanced computing power will help scientists better understand the three frontiers of modern astronomy: the history of the universe, the nature of distant stars and the detection of gravitational waves.

By measuring the composition of dark energy, scientists will better understand the shape, structure and fate of the universe. In addition, CHIME will be a key instrument to study gravitational waves, the ripples in space-time that were only recently discovered, confirming the final piece of Einstein’s theory of general relativity.

CHIME is a collaboration among 50 Canadian scientists from the University of British Columbia, the University of Toronto, McGill University, and the National Research Council of Canada (NRC). The $16-million investment for CHIME was provided by the Canada Foundation for Innovation and the governments of British Columbia, Ontario, and Quebec, with additional funding from the Natural Sciences and Engineering Research Council and the Canadian Institute for Advanced Research. The telescope is located in the mountains of British Columbia’s Okanagan Valley at the NRC’s Dominion Radio Astrophysical Observatory near Penticton.

Quotes

“CHIME is an extraordinary example showcasing Canada’s leadership in space science and engineering. The new telescope will be a destination for astronomers from around the world who will work with their Canadian counterparts to answer some of the most profound questions about space. Our government believes in providing scientists with the opportunities and tools they need to pursue the answers to questions that keep them up at night.” – The Honourable Kirsty Duncan, Minister of Science

“The National Research Council works hand-in-hand with academia for the advancement of knowledge in Canada. CHIME is a shining example of what outcomes we can achieve, working in collaboration, for today and tomorrow, for Canada and beyond.” – Mr. Iain Stewart, President of the National Research Council of Canada

“With the CHIME telescope we will measure the expansion history of the universe and we expect to further our understanding of the mysterious dark energy that drives that expansion ever faster. This is a fundamental part of physics that we don’t understand and it’s a deep mystery. This is about better understanding how the universe began and what lies ahead.” – Dr. Mark Halpern, University of British Columbia

“CHIME’s unique design will enable us to tackle one of the most puzzling new areas of astrophysics today – Fast Radio Bursts. The origin of these bizarre extragalactic events is presently a mystery, with only two dozen reported since their discovery a decade ago. CHIME is likely to detect many of these objects every day, providing a massive treasure trove of data that will put Canada at the forefront of this research.” – Dr. Victoria Kaspi, McGill University

“CHIME ‘sees’ in a fundamentally different way from other telescopes. A massive supercomputer is used to process incoming radio light and digitally piece together an image of the radio sky. All that computing power also lets us do things that were previously impossible: we can look in many directions at once, run several experiments in parallel, and leverage the power of this new instrument in unprecedented ways.” – Dr. Keith Vanderlinde, University of Toronto

Quick facts

• The CHIME telescope incorporates four 100-metre long U-shaped cylinders of metal mesh that resemble snowboard half-pipes. Its overall footprint is the size of five NHL hockey rinks.
• CHIME collects radio waves with wavelengths between 37 and 75 centimetres, similar to the wavelength used by cell phones.
• Most of the signals collected by CHIME come from our Milky Way galaxy, but a tiny fraction of these signals started on their way when the universe was between 6 and 11 billion years old.
• The radio signal from the universe is very weak and extreme sensitivity is needed to detect it. The amount of energy collected by CHIME in one year is equivalent to the amount of energy gained by a paper clip falling off a desk to the floor.
• The data rate passing through CHIME is comparable to all the data in the world’s mobile networks. There is so much data that it cannot all be saved to disk. It must first be processed and compressed by a factor of 100,000.
• Seven quadrillion computer operations occur every second on CHIME. This rate is equivalent to every person on Earth performing one million multiplication problems every second.

Related products

• Backgrounder: Canadian Hydrogen Intensity Mapping Experiment

• Game-changing technology

• Video: Timelapse of the construction of the CHIME telescope

• Video: Footage of the CHIME telescope

• Video: Fast Radio Bursts (from McGill University)

• Video: How CHIME works (animated video from McGill University)

• Video: CHIME and dark energy (from University of British Columbia)

Associated links

• The Canadian Hydrogen Intensity Mapping Experiment

• The NRC’s Dominion Radio Astrophysical Observatory

Contacts

Ann Marie Paquet Press Secretary
Office of the Honourable Kirsty Duncan
613-404-2733
ann-marie.paquet [at] canada.ca

Media Relations Team
National Research Council of Canada 613-991-1431 or 1-855-282-1637 (24/7)
media [at] nrc-cnrc.gc.ca Twitter: @nrc_cnrc

Heather Amos
University of British Columbia Public Affairs
604-828-3867
heather.amos [at] ubc.ca

Chris Chipello
McGill Media Relations Office
514-398-4201
chris.chipello [at] mcgill.ca

Chris Sasaki
Communications Co-ordinator
Dunlap Institute for Astronomy & Astrophysics University of Toronto
416-978-6613
csasaki [at] dunlap.utoronto.ca