Corrected Pantheon+ analysis of supernovae challenges accelerating universe claim

Research led by the Tata Institute of Fundamental Research, Mumbai, along with Professor Subir Sarkar from the University of Oxford, questions the widely accepted argument that the expansion rate of the universe is accelerating and that this is driven by “dark energy” arising from the quantum vacuum. Their letter has been published in Monthly Notices of the Royal Astronomical Society.

In his work, Sarkar, of Oxford’s Rudolf Peierls Centre for Theoretical Physics, together with Animesh Sah and Mohamed Rameez of the Tata Institute of Fundamental Research in India, revisited one of cosmology’s most important observational data sets: the Pantheon+ compilation of more than 1,700 Type Ia supernovae. For more than 25 years, astronomers have used observations of these supernovae—exploding stars—to measure the expansion of the universe. Analysis of such observations led to the groundbreaking discovery that cosmic expansion appears to be accelerating, a finding that won the 2011 Nobel Prize in physics.

The team analyzed the supernovae from the Pantheon+ data set, one of the most comprehensive catalogs of its kind, and incorporated a recently proposed correction that takes into account the age of the stars that eventually produce these supernova explosions. They also checked whether the inferred acceleration of the expansion rate is indeed the same in every direction, as is assumed in the standard cosmological model.

“There is increasing evidence that the brightness of Type Ia supernovae depends on the age of the stars they come from,” said Sarkar, a co-author of the study. “If this effect is not accounted for, it can lead to the erroneous conclusion that the expansion rate is accelerating.”

After applying the correction, the researchers found that the data no longer support a picture of a uniformly accelerating universe. Instead, their analysis suggests that cosmic expansion is overall slowing down rather than speeding up.

Sarkar and his colleagues came to their conclusion by considering whether the inferred acceleration may in fact be anisotropic, meaning it exhibits different properties when measured in different directions and therefore deviates from the standard cosmological model. If that were true, they argue, dark energy couldn’t be responsible for driving the acceleration because the effect of the quantum vacuum cannot be anisotropic.

“We found that the inferred acceleration is directed mainly along the direction that we are moving locally, as indicated by the hotspot in the cosmic microwave background, and dies away with distance,” Sarkar said. “This is unaffected by the correction to the supernova brightness—so it rejects dark energy independently of whether the correction is applied or not. The correction turns the isotropic component into a deceleration—which again rules out dark energy.”

The findings divide opinion; in the same journal issue, a paper co-authored by Professor Maria Vincenzi, also from the University of Oxford, maintains that evidence does indeed point to the universe still accelerating.

She comments, “The lead authors of our study are world experts in understanding how the environments of Type Ia supernovae affect cosmological measurements with more than a decade of experience in both supernova astrophysics and galaxy evolution. Our recent findings provide further confidence in the cosmological framework that has emerged over the past three decades and allow the research community to focus on one of the biggest unanswered questions in physics: the nature of dark energy itself.”

Looking ahead, both schools of thought will be able to test their findings and explore further using data from the Rubin Observatory’s Legacy Survey of Space and Time (LSST), which will soon measure hundreds of thousands of supernovae.

Who’s behind this story?

Stephanie Baum

Master’s in TESOL from The New School. Passionate about language learning and editing science news on biology and space exploration.

Full profile →

Robert Egan

Bachelor’s in mathematical biology, Master’s in creative writing. Well-traveled with unique perspectives on science and language.

Full profile →