New research doubles the age of the universe to 26.7 billion years

A new study suggests that the universe may be 26.7 billion years old, twice the widely accepted age of 13.7 billion years. The new model, which incorporates Zwicky’s theory of tired light and the evolving Dirac coupling constants, can explain the existence of young, mature galaxies formed only 300 million years after the Big Bang and propose a revised interpretation of the cosmological constant.

A new study suggests that the universe may be 26.7 billion years old, challenging the widely accepted estimate of 13.7 billion years based on the Lambda-CDM concordance model.

Our universe may be twice as old as current estimates, according to a new study that challenges the prevailing cosmological model and sheds new light on the so-called “impossible early galaxy problem.”

says author Rajendra Gupta, associate professor of physics in the University of Ottawa’s School of Science.

Rajendra Gupta

“Our newly devised model extends the galaxy’s formation time by several billion years, making the universe 26.7 billion years old, not 13.7 as previously estimated.” Rajendra Gupta – Associate Professor of Physics in the Faculty of Science, University of Ottawa. Credit: University of Ottawa

For years, astronomers and physicists have been calculating the age of our universe by measuring the time elapsed since[{” attribute=””>Big Bang and by studying the oldest stars based on the redshift of light coming from distant galaxies. In 2021, thanks to new techniques and advances in technology, the age of our universe was thus estimated at 13.797 billion years using the Lambda-CDM concordance model.

The Lambda-CDM (Lambda-Cold Dark Matter) concordance model, also known as the standard model of cosmology, is currently the simplest and most widely accepted model that describes the evolution of the universe from its earliest moments to the present day.

However, many scientists have been puzzled by the existence of stars like the Methuselah that appear to be older than the estimated age of our universe and by the discovery of early galaxies in an advanced state of evolution made possible by the James Webb Space Telescope. These galaxies, existing a mere 300 million years or so after the Big Bang, appear to have a level of maturity and mass typically associated with billions of years of cosmic evolution. Furthermore, they’re surprisingly small in size, adding another layer of mystery to the equation.

Zwicky’s tired light theory proposes that the redshift of light from distant galaxies is due to the gradual loss of energy by photons over vast cosmic distances. However, it was seen to conflict with observations. Yet Gupta found that “by allowing this theory to coexist with the expanding universe, it becomes possible to reinterpret the redshift as a hybrid phenomenon, rather than purely due to expansion.”

“Our newly-devised model stretches the galaxy formation time by several billion years, making the universe 26.7 billion years old, and not 13.7 as previously estimated.”

Rajendra Gupta, Adjunct professor of physics in the Faculty of Science at the University of Ottawa

In addition to Zwicky’s tired light theory, Gupta introduces the idea of evolving “coupling constants,” as hypothesized by Paul Dirac. Coupling constants are fundamental physical constants that govern the interactions between particles. According to Dirac, these constants might have varied over time. By allowing them to evolve, the timeframe for the formation of early galaxies observed by the Webb telescope at high redshifts can be extended from a few hundred million years to several billion years. This provides a more feasible explanation for the advanced level of development and mass observed in these ancient galaxies.

Moreover, Gupta suggests that the traditional interpretation of the “cosmological constant,” which represents dark energy responsible for the accelerating expansion of the universe, needs revision. Instead, he proposes a constant that accounts for the evolution of the coupling constants. This modification in the cosmological model helps address the puzzle of small galaxy sizes observed in the early universe, allowing for more accurate observations.

On July 7, 2023, the study, “JWST early Universe observations and 𝚲CDM cosmology,” was published in the Monthly Notices of the Royal Astronomical Society (MNRAS) by Oxford University Press.

Reference: “JWST early Universe observations and ΛCDM cosmology” by R Gupta, 7 July 2023, Monthly Notices of the Royal Astronomical Society.
DOI: 10.1093/mnras/stad2032

See also  NASA announces that a 110-foot asteroid is heading toward Earth at high speed

Leave a Reply

Your email address will not be published. Required fields are marked *