Credit: CC0 Public Domain
The geometry of space, where physical laws unfold, may also hold answers to some of the deepest questions in fundamental physics. The very structure of spacetime might underlie every interaction in nature.
A paper published in Nuclear Physics B, led by Richard Pincak, explores the idea that all fundamental forces and particle properties could emerge from the geometry of hidden extra dimensions.
According to the study, the universe may contain invisible dimensions folded into intricate seven-dimensional shapes known as G₂-manifolds. Traditionally, these structures have been studied as static. But Pincak and colleagues consider them as dynamic: evolving under a process called the G₂–Ricci flow, where the internal geometry changes with time.
“As in organic systems, such as the twisting of DNA or the handedness of amino acids, these extra-dimensional structures can possess torsion, a kind of intrinsic twist,” explains Pincak.
“When we let them evolve in time, we find that they can settle into stable configurations called solitons. These solitons could provide a purely geometric explanation of phenomena such as spontaneous symmetry breaking.”
In the Standard Model of particle physics, the Higgs field gives mass to the W and Z bosons. But the authors suggest that mass could instead arise from geometric torsion in extra dimensions, without introducing an additional Higgs field. “In our picture,” Pincak says, “matter emerges from the resistance of geometry itself, not from an external field.”
The theory also links torsion to the curvature of spacetime, offering a possible explanation of the positive cosmological constant that drives cosmic expansion. The authors even speculate about a new particle, the “Torstone,” that might be observable in future experiments.
The ultimate goal is to extend Einstein’s vision: if gravity is geometry, perhaps all interactions are geometry. As Pincak notes, “Nature often prefers simple solutions. Perhaps the masses of the W and Z bosons come not from the famous Higgs field, but directly from the geometry of seven-dimensional space.”
More information:
Richard Pinčák et al, Introduction of the G2-Ricci flow: Geometric implications for spontaneous symmetry breaking and gauge boson masses, Nuclear Physics B (2025). DOI: 10.1016/j.nuclphysb.2025.116959
Provided by
Institute of Experimental Physics SAS
Citation:
Could mass arise without the Higgs boson? (2025, November 10)
retrieved 10 November 2025
from https://phys.org/news/2025-11-mass-higgs-boson.html
This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no
part may be reproduced without the written permission. The content is provided for information purposes only.