U of T experimental physicists dip their toes into the quantum ocean

January 11, 2023 by Chris Sasaki - A&S News

"Suppose you knew everything there was to know about a water molecule — the chemical formula, the bond angle, etc.,” says experimental physicist Joseph Thywissen.

“You might know everything about the molecule, but still not know there are waves on the ocean, much less how to surf them,” he says. “That’s because when you put a bunch of molecules together, they behave in a way you probably cannot anticipate.”

Thywissen is a professor in the Faculty of Arts & Science’s Department of Physics and a member of the Centre for Quantum Information & Quantum Control. He is describing the concept in physics known as emergence: the relationship between the behaviour and characteristics of individual particles and large numbers of those particles.

Thywissen and his collaborators have taken a first step in understanding this transition from “one-to-many" particles by studying not one, not many, but two isolated, interacting particles, in this case potassium atoms.

Robyn Learn, Frank Corapi and Joseph Thywissen standing in a lab with a sign on the door visible reading "ultracold atoms"
Gradutate students Robyn Learn and Frank Corapi with Joseph Thywissen in Thywissen’s lab. 

A collaborative team including experimental physicists from the University of Toronto and theoretical physicists from the University of Colorado (UC) has measured the strength of a type of interaction — known as “p-wave interactions” — between two potassium atoms and found the result confirms a longstanding prediction.

P-wave interactions are weak in naturally occurring systems but researchers predicted that they have a much higher maximum theoretical limit. The team is the first to confirm that the p-wave force between particles reached this maximum.

The result is described in a paper published today in the journal Nature. Co-authors from U of T include co-lead authors Vijin Venu and Peihang Xu, both of whom earned their doctorate last year, as well as Cora Fujiwara, a postdoctoral researcher, and Frank Corapi, currently a PhD candidate. 

Their collaborators include researchers from UC Boulder, led by Professor Ana Maria Rey, who is a fellow of JILA and NIST and an adjoint professor in the physics department at UC. The theory team includes PhD candidate Michael Mamaev, Thomas Bilitewski who was a postdoc in Rey’s group (and is currently an assistant professor in the Department of Physics, Oklahoma State University), and Jose D’Incao, a UC associate research professor.

“In our lab, we were able to isolate two atoms at a time,” says Venu. “This approach avoids the complexity of many-atom systems and allows full control and study of interactions between atoms in a pair.”

The team isolated pairs of atoms within a 3D optical lattice — a “crystal of light” as Fujiwara describes it — created at the intersection of three laser beams at 90 degrees to each other. The intersecting beams generated stationary nodes of high intensity which trapped pairs of particles. With pairs isolated in this way, the researchers were able to measure the strength of their mutual interaction.

The result has ramifications in many different technologies including the study of superfluids, superconductivity and quantum simulations.

Quantum simulations are models designed to understand quantum systems like atoms, molecules or chemical reactions — systems ruled by quantum mechanics. These simulations can help understand how properties of materials emerge from particle-particle interactions.

A man making adjustments to a technical device
Physics graduate student Frank Corapi adjusting the alignment of a laser beam in the Ultracold Atoms Lab at the University of Toronto.

“In fact, the interactions between spin-polarized fermions that we have observed are predicted to give rise to new forms of unconventional robust superfluids, which are believed to be a potential resource for quantum calculations,” explains Rey.

The challenge of solving quantum models with existing computers is daunting; the task has been described as teaching quantum mechanics to a computer. A promising alternative is to use existing quantum systems — in other words, actual atoms and molecules.

“What's hard for us, is easy for nature,” says Thywissen. “And so, we can harness the computational power of nature just ‘doing its thing’ to solve problems that are otherwise intractable to us.”

The team’s insight into how two particles interact is a first, small step toward understanding natural quantum systems and how they can lead to more powerful and effective quantum simulations.

“What we saw in our experiment was remarkable,” says Fujiwara. “It's a perfect little system. And now that we have this understanding of this two-particle system, we can start to create these sorts of exotic systems which involve many, many more particles.”