Earth and our entire Milky Way galaxy may sit inside a mysterious giant hole which makes the cosmos expand faster here than in neighbouring regions of the universe, astronomers say.
Their theory is a potential solution to the 'Hubble tension' and could help confirm the true age of our universe, which is estimated to be around 13.8 billion years old.
The latest research shared at the Royal Astronomical Society's National Astronomy Meeting (NAM) in Durham and led by Dr Indranil Banik from the University of Portsmouth's Institute of Cosmology and Gravitation shows that sound waves from the early universe, "essentially the sound of the Big Bang", support this idea.
The Hubble constant was first proposed by Edwin Hubble in 1929 to express the rate of the universe's expansion. It can be measured by observing the distance of celestial objects and how fast they are moving away from us.
The stumbling block, however, is that extrapolating measurements of the distant, early universe to today using the standard cosmological model predicts a slower rate of expansion than measurements of the nearby, more recent universe. This is the Hubble tension.
"A potential solution to this inconsistency is that our galaxy is close to the centre of a large, local void," explained Dr Indranil Banik , a Research Fellow from the University of Portsmouth's Faculty of Technology .
"It would cause matter to be pulled by gravity towards the higher density exterior of the void, leading to the void becoming emptier with time.
"As the void is emptying out, the velocity of objects away from us would be larger than if the void were not there. This therefore gives the appearance of a faster local expansion rate."
He added: "The Hubble tension is largely a local phenomenon, with little evidence that the expansion rate disagrees with expectations in the standard cosmology further back in time.
"So, a local solution like a local void is a promising way to go about solving the problem."
For the idea to stand up, Earth and our solar system would need to be near the centre of a void about a billion light-years in radius and with a density about 20 per cent below the average for the universe as a whole.
Directly counting galaxies does support the theory, because the number density in our local universe is lower than in neighbouring regions.
However, the existence of such a large and deep void is controversial because it doesn't mesh particularly well with the standard model of cosmology, which suggests matter today should be more uniformly spread out on such large scales.
Despite this, new data presented by Dr Banik at NAM 2025 shows that baryon acoustic oscillations (BAOs) - the "sound of the Big Bang" - support the idea of a local void.
"These sound waves travelled for only a short while before becoming frozen in place once the universe cooled enough for neutral atoms to form," he explained.
"They act as a standard ruler, whose angular size we can use to chart the cosmic expansion history.
"A local void slightly distorts the relation between the BAO angular scale and the redshift, because the velocities induced by a local void and its gravitational effect slightly increase the redshift on top of that due to cosmic expansion alone.
"By considering all available BAO measurements over the last 20 years, we showed that a void model is about one hundred million times more likely than a void-free model with parameters designed to fit the CMB observations taken by the Planck satellite, the so-called homogeneous Planck cosmology."
The next step for researchers is to compare their local void model with other methods to estimate the history of the universe's expansion, such as cosmic chronometers.
This involves looking at galaxies that are no longer forming stars. By observing their spectra, or light, it is possible to find what kinds of stars they have and in what proportion. Since more massive stars have shorter lives, they are absent in older galaxies, providing a way to establish a galaxy's age.
Astronomers can then combine this age with the galaxy's redshift - how much the wavelength of its light has been stretched - which tells us how much the universe has expanded while light from the galaxy was travelling towards us. This sheds light on the universe's expansion history.
As a recognised international centre of research excellence, the University of Portsmouth's Institute of Cosmology and Gravitation (ICG) brings together more than 70 researchers - faculty, postdoctoral fellows and PhD students - tackling some of the Universe's most profound mysteries, from the earliest moments after the Big Bang to the large-scale structure of galaxies, dark energy and gravitational waves.
Its world-class impact was confirmed in REF 2021, where 100 per cent of ICG research was rated world-leading or internationally excellent.
The institute's contributions include roles in major international projects such as Euclid , LISA (Laser Interferometer Space Antenna) , the LIGO gravitational wave detectors , and the Dark Energy Spectroscopic Instrument (DESI) .
