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For years, astronomers and physicists have been intrigued by calculating the age of the universe. One of the primary methods used is measuring the time elapsed since the Big Bang, the event believed to have set the universe in motion. Another approach involves studying the oldest stars and galaxies, which can provide valuable clues about the universe’s age and evolution.
In 2021, it was made to new techniques and technological advances. Using the Lambda-CDM concordance model, which describes the universe’s evolution based on the existence of dark energy and cold dark matter, scientists could refine their estimates of the universe’s age. The model takes into account the expansion rate of the universe, as well as the distribution of matter and energy within it.
The recent release of new data on the cosmic microwave background (CMB) highlighted the transformative role of digital technology in cosmological research. The upgraded South Pole Telescope (SPT), equipped with the new SPT-3G camera boasting 16,000 detectors, has been instrumental in capturing remnant light from the universe’s early formation at the National Science Foundation’s Amundsen-Scott South Pole Station.
The SPT has been observing the sky for over five years, gathering data that offers a glimpse into the universe’s infancy. This data, analysed and published in Physical Review D, provides promising insights into the nature of the universe, setting the stage for more profound discoveries in the future.
Zhaodi Pan, lead author of the paper and a Maria Goeppert Mayer fellow at Argonne National Laboratory, describes the CMB as a “treasure map for cosmologists.” The CMB’s temperature and polarisation variations offer a unique window into the universe’s early stages, providing crucial information about its evolution.
One of the significant findings from the SPT-3G is the measurement of CMB gravitational lensing. Gravitational lensing occurs when the universe’s matter distorts the CMB as it travels through space, akin to placing a curved glass base on a book page that warps the words behind it. This distortion holds clues about the early universe and enigmatic components like dark matter, which can only be observed through gravitational interactions.
Despite using only a few months of data from 2018, the SPT-3G’s gravitational lensing measurement is already competitive in the field. Amy Bender, a physicist at Argonne and the University of Chicago and a paper co-author, highlighted the potential of five more years of data analysis, hinting at further discoveries.
The SPT’s remote location and stable atmosphere at the South Pole minimise interference when studying CMB patterns. However, the highly sensitive SPT-3G camera still encounters contamination from the atmosphere, the galaxy, and extragalactic sources, making data analysis a meticulous process involving data validation, noise filtering, and measurement interpretation.
The results from the SPT-3G not only strengthen the understanding of gravity on large scales but also support the current understanding of how structures of matter are formed in the universe. Additionally, lensing maps from additional years of data will aid in probing cosmic inflation, providing insights into the early universe’s fast exponential expansion and potentially revealing direct evidence of this theory.
Bender noted that as more data is added, more questions arise, underscoring the complexity of the universe. This ongoing exploration is crucial in understanding dark matter and its role in shaping the universe.
The upgraded SPT-3G and its observations represent a significant advancement in the quest to unravel the mysteries of the universe, showcasing the transformative power of digital technology in cosmological research.
In the future, advancements in cosmological research will likely continue to refine the understanding of the universe’s age. As the understanding deepens, people may also uncover new insights into the nature of dark energy and dark matter. These two enigmatic components are thought to play a crucial role in the universe’s evolution. These discoveries could lead to revisions of existing models and a more comprehensive understanding of the forces shaping the cosmos.