New results from the collaboration of Digi (dark energy spectroscopy) reveal signs of time-varying dark energy.
Two “fans” corresponding to the two main areas were observed by Desi on top and bottom of the plane of the Milkyway Galaxy. Image credits: Desi Collaboration/DOE/KPNO/NOIRLAB/NSF/AURA/R. Proctor.
“The universe will never surprise us and will never surprise us,” said Dr Arjun Dei, a digiproject scientist at Noir Love and associate director of the Central Scale Observatory for Strategic Initiatives.
“By unprecedentedly revealing the evolving textures of our universe’s fabrics, Digi and Mayall telescopes are changing our understanding of the future of our universe and nature itself.”
The DESI data, which is employed alone, is consistent with the standard model of the universe. In Lambda CDM, CDM is cold dark matter, and Lambda represents the simplest case of dark energy that acts as a cosmological constant.
However, when combined with other measurements, the effect of dark energy may be weaker over time, increasing indications that other models may be more appropriate.
Other measurements of them include light leftovers from the dawn of space (cosmic microwave background, or CMB), distance measurements of supernovae, and observations of how light from distant galaxies are distorted by the effects of dark matter gravity (weak lenses).
So far, the evolving dark energy preference has not risen to 5 sigma. This is the gold standard in physics that represents a commonly accepted threshold of discovery.
However, the various combinations of DESI data and CMB, weak lenses, and supernova sets range from 2.8 to 4.2 sigma.
This analysis used techniques to hide results from scientists to the end to reduce unconscious biases about data.
This approach sets new criteria for how data is analyzed from large-scale spectroscopic studies.
The Desi is a cutting-edge instrument mounted on the NSF Nicholas U. Mayall 4-M telescope of the NSF Noirlab program, Kitt Peak National Observatory.
Light from 5,000 galaxies can be captured simultaneously, allowing you to carry out one of the most extensive research to date.
The experiment is currently investigating the fourth sky in five years, with plans to measure around 50 million galaxies and quasars (very far but bright objects with black holes in their cores) and more than 10 million stars by the time the project is finished.
The new analysis uses data from the first three years of observations and includes nearly 15 million best measured galaxies and quasars.
This is a major leap, with the one used in Desi’s initial analysis improving the accuracy of the experiment with more than twice as much data set, suggesting evolving dark energy.
Digi tracks the effects of dark energy by studying how matter spreads throughout the universe.
Very early cosmic events left subtle patterns in the way matter was distributed. This is a function called Barion Acoustic Vibration (BAO).
Its Bao pattern acts as a standard ruler, and its size is directly influenced by how the universe is expanding at different times.
Measuring rulers at different distances has shown the strength of dark energy throughout history by researchers.
DESI Collaboration begins work with additional analysis to extract more information from the current dataset, and Desi continues to collect the data.
Other experiments offered online over the next few years will also provide complementary data sets for future analysis.
“Our results are a fertile foundation for our theory colleagues looking at new and existing models, and we look forward to what they came up with,” says Dr. Michael Levi, Desi Director and Scientist.
“Whatever the nature of dark energy, it shapes the future of our universe. It is very noteworthy that we look up at the sky with a telescope and try to answer one of the biggest questions humanity has ever asked.”
“These are prominent results from very successful projects,” said Dr. Chris Davis, NSF Program Director at NSF Neil Love.
“The powerful combination of NSF Mayall Telescope and DOE’s dark energy spectroscopy instruments demonstrates the benefits of federal agencies collaborating with fundamental science to improve our understanding of the universe.”
Physicists shared their findings in a A series of papers It will be posted above arxiv.org.
Source: www.sci.news