We might live at the center of a vast 2 billion light-year cosmic void, astronomers suggest

Key takeaways:

  1. Evidence suggests our galaxy, the Milky Way, might be located in the center of a massive cosmic void called the KBC void, which is about 2 billion light-years wide and 20% less dense than surrounding space.
  2. This void could help explain the Hubble tension — the discrepancy in the Hubble constant — as stars and galaxies in this underdense region appear to be moving away from us faster than the expected rate.
  3. Banik and his team propose that the KBC void could cause local outflows of galaxies, which might account for the higher Hubble constant values observed in nearby regions compared to distant ones.
  4. The void theory suggests that gravity from denser regions outside the void could be pulling galaxies outward, accelerating their movement and challenging the cosmological principle of uniformity.
  5. While the void model offers a possible explanation for the Hubble tension, other theories, like early dark energy, are also being considered, though each has limitations and unresolved questions.

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A mysterious cosmic void around us may disrupt key laws of cosmology.

Void Design

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A Cosmic Void in Our Neighborhood?

Our Milky Way galaxy, while unremarkable among billions of galaxies, appears to occupy a unique region in the Universe—potentially the center of a massive cosmic void spanning 2 billion light-years. Known as the KBC void, it is named after scientists who first theorized its existence in 2013. Since then, evidence for this vast underdense region has accumulated, suggesting that our local cosmic neighborhood is less populated by matter than areas outside this void. The scale of this void, which could fit about 20,000 Milky Way-sized galaxies across, challenges the conventional understanding of how matter is distributed in the cosmos. If confirmed, its presence could reshape some foundational concepts in cosmology.

According to the cosmological principle—a core theory in cosmology—the universe should be uniform in mass and energy distribution over large scales. This principle allows scientists to apply the same physical laws universally. However, if this void does exist, it means that matter may not be evenly distributed after all. This unevenness could influence nearby cosmic phenomena and calls into question some widely accepted assumptions about the structure of the Universe.

A map of our local universe, in an oval shape.
A map of our local universe. Harvard-Smithsonian Center for Astrophysics

The Hubble Tension and the Void’s Potential Role

A critical point raised by this potential void is its influence on the Hubble constant, a key value that measures the Universe’s rate of expansion. Scientists expect the Hubble constant to be consistent across various regions of the cosmos, but local measurements often yield a higher rate of expansion than what’s observed over vast cosmic distances—a discrepancy called the Hubble tension. Dr. Indranil Banik and his colleagues at the University of St. Andrews, who recently published findings in Monthly Notices of the Royal Astronomical Society, suggest that the KBC void could be influencing this discrepancy. According to Banik’s research, the relatively empty void might explain why nearby stars and galaxies appear to be moving away from us at a faster rate than expected.

In their model, the gravitational pull from denser regions outside the void could cause stars and galaxies within the void to flow outward, resulting in higher local expansion rates. This hypothesis suggests that galaxies within this cosmic void experience a stronger outward pull, thus accelerating their movement in ways that may not apply outside the void.

A map of a section of the universe showing areas of high and low density.
The Dark Energy Spectroscopic Instrument made the largest 3D map of our universe to date. This sliver of the cosmos shows its high- and low-density regions. Claire Lamman/DESI collaboration; custom colormap package by cmastro

Alternative Theories and Next Steps

Not all scientists agree on the void hypothesis, and other explanations for the Hubble tension have emerged. One competing theory proposes the existence of “early dark energy,” a force that may have influenced the Universe’s expansion in its infancy, ultimately leading to the expansion discrepancies seen today. However, Banik argues that the early-dark-energy theory complicates other aspects of cosmology, such as the dating of ancient stars, which would need to be older than the Universe for this theory to hold. For now, Banik’s void hypothesis seems more consistent with current observations.

The Hubble Telescope above Earth
Observations from the Hubble Telescope conflict with standard cosmology predictions about the expansion of the universe. The KBC void could explain why. NASA

Banik and his team are investigating further by examining supernovae data. If the Hubble constant outside the KBC void aligns with standard cosmological predictions, then the void’s presence may indeed be a viable explanation for the Hubble tension. But until the findings are conclusive, questions about the void’s influence on the Universe remain open, leaving scientists to ponder how this cosmic peculiarity could redefine our understanding of space and matter.

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