Does antimatter fall up or down?

A TRIUMF physicist makes an adjustment to the Radial Time Projection Chamber, a position- sensitive particle detector that surrounds the antihydrogen trap.
Credit: TRIUMF

Physicists observe the first gravitational free-fall of antimatter.

First measurement of the force of the earth’s gravity on antimatter published in prestigious Nature journal.

The physics behind antimatter is one of the world’s greatest mysteries. Looking as far back as The Big Bang, physics has predicted that when we create matter, we also create antimatter. The world around us is made of matter, but physicists have yet to find an explanation for the absence of antimatter.

Now, physicists at the University of Calgary, Simon Fraser University, TRIUMF, the University of British Columbia, York University and the British Columbia Institute of Technology and research institutions from around the world have just answered a long-standing question that will lead to a deeper understanding of this mystery: does antimatter fall up or down?

Title: Dr. Thompson and Dr. Friesen

Dr. Rob Thompson (ALPHA-g principal investigator) and Dr. Timothy Friesen (major contributor to the Nature paper) from the University of Calgary stand in the university’s science workshop, where parts for the ALPHA-g experiment were fabricated. Credit: University of Calgary

The Antihydrogen Laser Physics Apparatus (ALPHA) collaboration at CERN, the European Organization for Nuclear Research, completed the first direct measurement of gravity’s effect on the motion of antimatter using its new ALPHA-g apparatus. As expected by much of the scientific community, antimatter falls downwards. This is a tremendous scientific and technical achievement that marks a leap forward in the world of antimatter research. The collaboration’s findings are published in Nature today. 

UCalgary’s involvement with ALPHA is led by Dr. Robert Thompson and Dr. Timothy Friesen from the department of physics and astronomy. Physicists used antihydrogen, the simplest atom in antimatter, to perform the experiment.

“Right now, we don’t have an explanation about where all the antimatter in the universe is. To find a solution for this conundrum, what we do is test the elements of physics of antimatter to see if we can find an inconsistency. In this case, we tested to see if the gravitational characteristics of antihydrogen mirror those of hydrogen, which is significant because it’s never been done before.,” said Dr. Robert Thompson, PhD, professor of physics and Associate Vice-President (Research) at UCalgary, and Principal Investigator of the ALPHA-g Canada Foundation for Innovation Project.

The antimatter gravity measurement was carried out in the new ALPHA-g apparatus, now in operation at CERN. After creating antimatter, trapping the neutral antihydrogen atoms in a magnetic bottle, making the environment as cold as possible, physicists then released the antihydrogen within the vertical apparatus to witness and measure its gravitational behaviour.

ALPHA has previously carried out precision measurements of the charge and colour spectrum of antihydrogen, which to-date remain all consistent with current physical models. The ALPHA collaboration recognizes this milestone as the first step in taking more precise measurements of the gravitational properties of antimatter to determine whether antimatter falls in the exact same way as matter. This could help physicists understand the lack of antimatter observed in the universe.

“We know there’s a problem somewhere in quantum mechanics and gravity. We just don’t know what it is. There has been a lot of speculation on what happens if you drop antimatter, though it’s never been tested before now because it’s so hard to produce and gravity is very weak,” said Dr. Timothy Friesen, PhD, Assistant Professor, Physics and Astronomy, UCalgary and major contributor to Nature paper .

ALPHA-g was designed, constructed and commissioned through an international partnership of research institutions including, on the Canadian side, the University of Calgary, Simon Fraser University, TRIUMF, the University of British Columbia, and York University, as well as post-secondary institutions and research institutes in Europe, the United Kingdom and the United States. Building the ALPHA-g apparatus was only the first step. Observing the free-fall of antimatter involved the entire ALPHA collaboration, including researchers from the above institutions and countries, as well as from the British Columbia Institute of Technology and researchers from Israel and Brazil.

“This milestone is a culmination of nearly 20 years of dedication and teamwork. The contributions of the members of ALPHA-Canada were critical to our success,” said Dr. Makoto C. Fujiwara, Senior Scientist, TRIUMF, and ALPHA-Canada spokesperson. “ALPHA-Canada is a pan-Canadian collaboration made up of a diverse group of students, postdoctoral scholars, academics and staff members, each who played a vital role in this project.”

 

About ALPHA  

ALPHA is an international collaboration based at CERN, which studies antihydrogen atoms, the antimatter counterpart of the simplest atom, hydrogen. By comparisons of hydrogen and antihydrogen, the experiment hopes to understand fundamental symmetries between matter and antimatter. 

ALPHA-Canada is a significant group in ALPHA, constituting more than one third of the international collaboration. ALPHA-Canada consists of approximately 20 researchers and students from six Canadian institutions: The University of Calgary, Simon Fraser University, TRIUMF, the University of British Columbia, British Columbia Institute of Technology, and York University. ALPHA-Canada’s research is supported in part by the Natural Sciences and Engineering Research Council of Canada. 

This is the first major result from the ALPHA-g apparatus, which was funded through the Canada Foundation for Innovation. Major contributing partners include the Government of Alberta, the British Columbia Knowledge Development Fund, the Ontario Research Fund, Carlsberg Foundation (Denmark), and UK Government funding through the University of Manchester and Swansea University. 

Media Inquiries

Nadine Sander-Green
Senior External Communications, Faculty of Science, UCalgary
587-575-9873
nadine.sandergreen@ucalgary.ca

Local media contacts also available in Vancouver (BCIT, SFU, TRIUMF, and UBC) and Toronto (York).

 

About the University of Calgary  

UCalgary is Canada’s entrepreneurial university, located in Canada’s most enterprising city. It is a top research university and one of the highest-ranked universities of its age. Founded in 1966, its 35,000 students experience an innovative learning environment, made rich by research, hands-on experiences and entrepreneurial thinking. It is Canada’s leader in the creation of start-ups. Start something today at the University of Calgary.  

For more information, visit ucalgary.ca. Stay up to date with UCalgary news headlines on Twitter @UCalgary. For access to UCalgary news releases, images and b-roll, and details on faculties and how to reach experts, check out our newsroom at ucalgary.ca/newsroom.  

Journal: Nature
DOI: 10.1038/s41586-023-06527-1
Method of Research: Experimental study
Subject of Research: Not applicable
Article Title: Observation of the effect of gravity on the motion of antimatter
Article Publication Date: 27-Sep-2023

Media Contact

Nadine Sander-Green
University of Calgary
nadine.sandergreen@ucalgary.ca

www.ucalgary.ca

Media Contact

Nadine Sander-Green
University of Calgary

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