SPACE/COSMOS
Dark energy 'doesn’t exist' so can't be pushing 'lumpy' Universe apart – study
image:
This graphic offers a glimpse of the history of the Universe, as we currently understand it. The cosmos began expanding with the Big Bang but then around 10 billion years later it strangely began to accelerate thanks to a theoretical phenomenon termed dark energy.
view moreCredit: NASA
One of the biggest mysteries in science – dark energy – doesn't actually exist, according to researchers looking to solve the riddle of how the Universe is expanding.
For the past 100 years, physicists have generally assumed that the cosmos is growing equally in all directions. They employed the concept of dark energy as a placeholder to explain unknown physics they couldn't understand, but the contentious theory has always had its problems.
Now a team of physicists and astronomers at the University of Canterbury in Christchurch, New Zealand are challenging the status quo, using improved analysis of supernovae light curves to show that the Universe is expanding in a more varied, "lumpier" way.
The new evidence supports the "timescape" model of cosmic expansion, which doesn't have a need for dark energy because the differences in stretching light aren't the result of an accelerating Universe but instead a consequence of how we calibrate time and distance.
It takes into account that gravity slows time, so an ideal clock in empty space ticks faster than inside a galaxy.
The model suggests that a clock in the Milky Way would be about 35 per cent slower than the same one at an average position in large cosmic voids, meaning billions more years would have passed in voids. This would in turn allow more expansion of space, making it seem like the expansion is getting faster when such vast empty voids grow to dominate the Universe.
Professor David Wiltshire, who led the study, said: "Our findings show that we do not need dark energy to explain why the Universe appears to expand at an accelerating rate.
"Dark energy is a misidentification of variations in the kinetic energy of expansion, which is not uniform in a Universe as lumpy as the one we actually live in."
He added: "The research provides compelling evidence that may resolve some of the key questions around the quirks of our expanding cosmos.
"With new data, the Universe's biggest mystery could be settled by the end of the decade."
The new analysis has been published in the journal Monthly Notices of the Royal Astronomical Society Letters.
Dark energy is commonly thought to be a weak anti-gravity force which acts independently of matter and makes up around two thirds of the mass-energy density of the Universe.
The standard Lambda Cold Dark Matter (ΛCDM) model of the Universe requires dark energy to explain the observed acceleration in the rate at which the cosmos is expanding.
Scientists base this conclusion on measurements of the distances to supernova explosions in distant galaxies, which appear to be farther away than they should be if the Universe's expansion were not accelerating.
However, the present expansion rate of the Universe is increasingly being challenged by new observations.
Firstly, evidence from the afterglow of the Big Bang – known as the Cosmic Microwave Background (CMB) – shows the expansion of the early Universe is at odds with current expansion, an anomaly known as the "Hubble tension".
In addition, recent analysis of new high precision data by the Dark Energy Spectroscopic Instrument (DESI) has found that the ΛCDM model does not fit as well as models in which dark energy is "evolving" over time, rather than remaining constant.
Both the Hubble tension and the surprises revealed by DESI are difficult to resolve in models which use a simplified 100-year-old cosmic expansion law – Friedmann's equation.
This assumes that, on average, the Universe expands uniformly – as if all cosmic structures could be put through a blender to make a featureless soup, with no complicating structure. However, the present Universe actually contains a complex cosmic web of galaxy clusters in sheets and filaments that surround and thread vast empty voids.
Professor Wiltshire added: "We now have so much data that in the 21st century we can finally answer the question – how and why does a simple average expansion law emerge from complexity?
"A simple expansion law consistent with Einstein's general relativity does not have to obey Friedmann's equation."
The researchers say that the European Space Agency's Euclid satellite, which was launched in July 2023, has the power to test and distinguish the Friedmann equation from the timescape alternative. However, this will require at least 1,000 independent high quality supernovae observations.
When the proposed timescape model was last tested in 2017 the analysis suggested it was only a slightly better fit than the ΛCDM as an explanation for cosmic expansion, so the Christchurch team worked closely with the Pantheon+ collaboration team who had painstakingly produced a catalogue of 1,535 distinct supernovae.
They say the new data now provides "very strong evidence" for timescape. It may also point to a compelling resolution of the Hubble tension and other anomalies related to the expansion of the Universe.
Further observations from Euclid and the Nancy Grace Roman Space Telescope are needed to bolster support for the timescape model, the researchers say, with the race now on to use this wealth of new data to reveal the true nature of cosmic expansion and dark energy.
ENDS
Images and captions
Caption: This graphic offers a glimpse of the history of the Universe, as we currently understand it. The cosmos began expanding with the Big Bang but then around 10 billion years later it strangely began to accelerate thanks to a theoretical phenomenon termed dark energy.
Credit: NASA
Caption: This graphic shows the emergence of a cosmic web in a cosmological simulation using general relativity. From left, 300,000 years after the Big Bang to right, a Universe similar to ours today. The dark regions are void of matter, where an ideal clock would run faster and allow more time for the expansion of space. The lighter purple regions are denser so clocks would run slower, meaning under the "timescape" model of cosmology that acceleration of the Universe's expansion is not uniform.
Credit: Hayley Macpherson, Daniel Price, Paul Lasky / Physical Review D 99 (2019) 063522
Further information
The paper 'Supernovae evidence for foundational change to cosmological models' by Antonia Seifert, Zachary Lane, Marco Galoppo, Ryan Ridden-Harper and David L Wiltshire, has been published in Monthly Notices of the Royal Astronomical Society Letters. DOI: 10.1093/mnrasl/slae112. The paper 'Cosmological foundations revisited with Pantheon+' by Antonia Seifert, Zachary Lane, Ryan Ridden-Harper and David L Wiltshire, has been published in Monthly Notices of the Royal Astronomical Society. DOI: 10.1093/mnras/stae2437.
The timescape cosmology was proposed by David Wiltshire in 2007, using the mathematical formalism of Thomas Buchert in general relativity, as a viable alternative to dark energy. In the intervening 17 years, the timescape model has been further developed and tested against a variety of cosmological data by David Wiltshire and his students. Zachary Lane and Antonia Seifert jointly developed the codes used in the new analysis.
Notes for editors
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Journal
Monthly Notices of the Royal Astronomical Society Letters
Article Title
Dark energy 'doesn’t exist' so can't be pushing 'lumpy' Universe apart – study
Article Publication Date
19-Dec-2024
Texas A&M researchers illuminate the mysteries of icy ocean worlds
New research advances understanding of the habitability of icy moons
Texas A&M University
As NASA’s Europa Clipper embarks on its historic journey to Jupiter’s icy moon, Europa, Dr. Matt Powell-Palm, a faculty member at Texas A&M University’s J. Mike Walker ‘66 Department of Mechanical Engineering, has unveiled groundbreaking research that could transform our understanding of icy ocean worlds across the solar system. The study published in Nature Communications, co-authored with planetary scientist Dr. Baptiste Journaux of the University of Washington, introduces a novel thermodynamic concept called the “centotectic” and investigates the stability of liquids in extreme conditions - critical information for determining the habitability of icy moons like Europa.
Revolutionizing the Search for Habitability
The exploration of icy ocean worlds represents a new frontier in planetary science, focusing on understanding the potential for these environments to support life. Powell-Palm’s research addresses a fundamental question in this field: under what conditions can liquid water remain stable on these distant, frozen bodies? By defining and measuring the cenotectic, the absolute lowest temperature at which a liquid remains stable under varying pressures and concentrations, the team provides a critical framework for interpreting data from planetary exploration efforts.
This study combines Powell-Palm’s expertise in cryobiology - specifically the low-temperature thermodynamics of water - initially focused on medical applications like organ preservation for transplantation, with Journaux’s expertise in planetary science and high-pressure water-ice systems. Together, they developed a framework that bridges disciplines to tackle one of the most fascinating challenges in planetary science.
“With the launch of NASA Europa Clipper, the largest planetary exploration mission ever launched, we are entering a multi-decade era of exploration of cold and icy ocean worlds. Measurements from this and other missions will tell us how deep the ocean is and its composition,” said Journaux. “Laboratory measurements of liquid stability, and notably the lowest temperature possible (the newly-defined cenotectic), combined with mission results, will allow us to fully constrain how habitable the cold and deep oceans of our solar system are, and also what their final fate will be when the moons or planets have cooled down entirely.”
A Texas A&M Legacy of Innovation in Space Research
The research was conducted at Texas A&M and led by mechanical engineering graduate student Arian Zarriz. The work reflects Texas A&M’s deep expertise in water-ice systems and tradition of excellence in space research, which spans multiple disciplines. With the recent groundbreaking of the Texas A&M Space Institute, the university is poised to play an even larger role in space exploration, providing intellectual leadership for missions pushing the boundaries of human knowledge.
“The study of icy worlds is a particular priority for both NASA and the European Space Agency, as evidenced by the flurry of recent and upcoming spacecraft launches,” said Powell-Palm. “We hope that Texas A&M will help to provide intellectual leadership in this space.”
Looking Ahead
As planetary exploration missions, such as those targeting icy moons, continue to expand our understanding of the solar system, researchers at Texas A&M and beyond prepare to analyze the wealth of data they will provide. By combining experimental studies like those conducted by Powell-Palm and Journaux with the findings from these missions, scientists aim to unlock the secrets of cold, ocean-bearing worlds and evaluate their potential to harbor life.
By Maddi Busby, Texas A&M Engineering
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Journal
Nature Communications
Article Title
On the equilibrium limit of liquid stability in pressurized aqueous systems
Article Publication Date
18-Dec-2024
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