November 22, 2024

Down the Quantum Rabbit Hole: “Alice Ring” Discovery Offers Glimpse Into Other-Worldly Realm

Artistic illustration of an Alice ring, which researchers have simply observed for the very first time in nature. Credit: Heikka Valja/Aalto University
Experiments promote a curious flipside of decaying monopoles: a truth where particle physics is quite actually switched on its head.
The field of quantum physics is rife with paths resulting in tantalizing brand-new locations of research study, however one rabbit hole offers a distinct vantage point into a world where particles behave in a different way– through the proverbial looking glass.
Dubbed the “Alice ring” after Lewis Carrolls world-renowned stories on Alices Adventures in Wonderland, the appearance of this item validates a decades-old theory on how monopoles decay. Particularly, that they decay into a ring-like vortex, where any other monopoles travelling through its center are flipped into their opposite magnetic charges.

Published recently in the journal Nature Communications, these findings mark the current discovery in a string of work that has actually spanned the collective careers of Aalto University Professor Mikko Möttönen and Amherst College Professor David Hall.
A Quantum Leap in Collaboration
” This was the very first time our cooperation was able to produce Alice rings in nature, which was a huge achievement,” Möttönen stated.
” This essential research study opens new doors into comprehending how these structures and their analogs in particle physics function in deep space,” Hall included.
The long-standing relationship, titled the Monopole Collaboration, at first showed the existence of a quantum analog of the magnetic monopole in 2014, isolated quantum monopoles in 2015, and eventually observed one decay into the other in 2017.
Comprehending Monopoles
Monopoles stay an evasive idea in the arena of quantum physics. As the name suggests, monopoles are the singular counterpart of dipoles, which carry a positive charge at their north pole and a negative charge at the south. On the other hand, a monopole brings only either a unfavorable or favorable charge.
While the idea sounds basic, recognizing a true monopole has shown to be a career-defining job. Heres how the Monopole Collaboration has actually done it: they controlled a gas of rubidium atoms prepared in a nonmagnetic state near absolute zero temperature. Under these extreme conditions, they were then able to develop a monopole by steering a no point of a three-dimensional magnetic field into the quantum gas.
The Emergence of Alice Rings
These quantum monopoles are ephemeral by nature, decaying a couple of milliseconds after their creation. It is within this instability that the Alice ring takes shape.
” Think of the monopole as an egg teetering at the top of a hill,” Möttönen stated. “The tiniest perturbations can send it crashing down. In the very same method, monopoles are subject to sound that activates their decay into Alice rings.”
While monopoles are temporary, the research study group simulated stable Alice rings for as long as 84 milliseconds– over 20 times longer than the monopole life-span. This leads scientists to be positive that future experiments will expose a lot more strange residential or commercial properties of Alice rings.
” From a range, the Alice ring just looks like a monopole, but the world takes a various shape when peering through the center of the ring,” Hall stated.
” It is from this perspective that whatever appears to be mirrored, as if the ring were an entrance into a world of antimatter rather of matter,” Möttönen included.
In theory, a monopole going through the center of an Alice ring would be changed into an anti-monopole of opposite charge. Similarly, the Alice rings charge would change as well. While this phenomenon has not yet been experimentally observed, Möttönen stated the topological structure of Alice rings requires this habits.
Collaborative Research Efforts
The speculative work was conducted at Amherst College primarily by PhD candidate Alina Blinova and Hall, while Möttönen and his group was accountable for running matching simulations. By doing this, the two teams were able to confirm the analysis of the experimental observations.
” It is just fantastic to have such a major discovery as the ending of my PhD work,” Blinova stated.
Referral: “Observation of an Alice ring in a Bose– Einstein condensate” by Alina Blinova, Roberto Zamora-Zamora, Tuomas Ollikainen, Markus Kivioja, Mikko Möttönen and David S. Hall, 29 August 2023, Nature Communications.DOI: 10.1038/ s41467-023-40710-2.
The simulations conducted at Aalto University were enabled by assistance from the CSC– IT Center for Science and the Research Council of Finland through its Centre of Excellence in Quantum Technology, and the experiments in the US by the monetary support of the National Science Foundation.

Monopoles stay an elusive principle in the arena of quantum physics. Under these severe conditions, they were then able to create a monopole by steering a zero point of a three-dimensional magnetic field into the quantum gas.
” Think of the monopole as an egg teetering at the top of a hill,” Möttönen said. In the very same method, monopoles are subject to sound that activates their decay into Alice rings.”
In theory, a monopole passing through the center of an Alice ring would be changed into an anti-monopole of opposite charge.