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A Dark Dimension Could Link Two of the Universe’s Great Unknowns
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cosmology
A Dark Dimension Could Link Two of the Universe’s Great Unknowns
By
Steve Nadis
June 22, 2026
Recent observations suggest that dark energy is changing over time. Theorists wonder if dark matter is, too.
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Ada Zejun Shen/Quanta Magazine
Introduction
By Steve Nadis
Contributing Writer
June 22, 2026
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astrophysics
cosmology
dark energy
dark matter
fundamental physics
physics
string theory
theoretical physics
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For those who see the world as a dark place, the universe seems to offer little solace. According to current estimates, approximately 70% of the stuff that makes up the cosmos consists of dark energy, an unknown force that pushes space to expand. And another 25% consists of dark matter, a mysterious material that holds galaxies together.
But semantically speaking, dark energy and dark matter are not so much “dark” as they are invisible. They do not emit, reflect, nor absorb light, and they have so far proven impossible to observe directly.
Generally, dark energy and dark matter are regarded as separate entities, their elusiveness their primary link. But recent astronomical observations have spurred scientists to look further into a less popular idea — that the two are in fact physically intertwined.
In 2024, the research team known as DESI, for Dark Energy Spectroscopic Instrument, found evidence that the strength of dark energy, sometimes referred to as the “cosmological constant,” had lost its presumed constancy. A 2025 study based on more than twice as much data also concluded that dark energy was changing over time.
These results indicate that after attaining a maximum value about 2 billion years ago, dark energy may have begun to weaken. But the results also suggested that in an earlier era, dark energy could have grown stronger, in seeming defiance of the law of energy conservation.
Researchers describe this as dark energy entering the “phantom regime.” They liken the situation to a ball rolling uphill. It’s certainly possible, but only if the ball is under the influence of something other than gravity.
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A slice of a 3D map produced by the Dark Energy Spectroscopic Instrument team shows connected strands of galaxies forming the structure of our universe.
Claire Lamman/DESI collaboration; custom colormap package by cmastro
A growing number of theorists are looking into the possibility that what’s influencing dark energy are its ties to dark matter.
Even though scientists have assumed that dark energy and dark matter “don’t have anything to do with each other,” said Tim Tait, a particle physicist at the University of California, Irvine, “you can imagine a case where one influences the other. And it would not be surprising if [they] were manifestations of a kind of unified theory of the dark universe.”
Dark Interactions
The idea that dark energy and dark matter interact is not new. For example, Justin Khoury, a physicist at the University of Pennsylvania, investigated the prospect in 2005.
Khoury explained that in that study, he and two coauthors posed a hypothetical question: Could there be a form of dark energy whose energy density increased over time? He and his collaborators found that if dark energy and dark matter could affect one another, they could produce what looked like (but was not) phantom behavior. “It is the most natural, simplest way of achieving this,” Khoury said.
Two decades later came the DESI finding that dark energy might actually be changing over time. The result spurred Khoury and two Pennsylvania colleagues, Meng-Xiang Lin and Mark Trodden, to construct a model of dark interactions based on a dark-sector analogue of quantum chromodynamics, a cornerstone theory of particle physics. In the new model, both the energy density of dark energy and the mass of dark matter change in concert.
Another recent study imagines something similar. According to this model, which was published in January in the journal Physical Review D, dark matter could have transferred a small fraction of its energy to dark energy during a previous era of cosmic history. “Dark...