How exactly did the universe start and how did these processes determine its formation and evolution? This is what a recent study published in Physical Review Research hopes to address as a team of researchers from Spain and Italy proposed a new model for the events that transpired immediately after the birth of the universe. This study has the potential to challenge longstanding theories regarding the exact processes that occurred at the beginning of the universe, along with how these processes have governed the formation and evolution of the universe.
For the study, the researchers used a series of computer models to simulate the beginning of the universe that challenge the longstanding theory that the universe began with a period of rapid expansion known as “inflation”, with scientists estimating this occurred within the first fraction of a second of the universe’s existence. However, this inflation theory postulates that several variables were all involved in making this theory possible.
In contrast, this new model suggests that a longstanding phenomenon of general relativity called gravitational waves are responsible for the universe and all its components, including galaxies, stars, planets, and life on Earth. The team proposes these gravitational waves are part of a longstanding mathematical model called De Sitter space, which is named after the Dutch mathematician Willem De Sitter, who worked with Albert Einstein regarding the universe’s structure throughout the 1920s.
“For decades, we have tried to understand the early moments of the Universe using models based on elements we have never observed”, said Dr. Raúl Jiménez, who studies experimental sciences & mathematics at ICREA in Spain and is a co-author on the study. “What makes this proposal exciting is its simplicity and verifiability. We are not adding speculative elements but rather demonstrating that gravity and quantum mechanics may be sufficient to explain how the structure of the cosmos came into being”.
First proposed in 1893 and 1905 by Oliver Heaviside and Henri Poincaré, respectively, gravitational waves received a huge boost in attention in 1916 when Albert Einstein proposed them to be ripples in the space-time continuum as part of his general theory or relativity. Despite myriads of sources, including supernovae, black holes, and neutron stars, gravitational waves are incredibly difficult to detect and require very sensitive instruments. This is potentially why gravitational waves were not detected until September 2015 by the Laser Interferometer Gravitational-Wave Observatory (LIGO) observatory, which have locations in Washington and Louisiana.
The origin of the universe remains one of the biggest mysteries in science, as the Big Bang has long been theorized to have been the catalyst for the origin of the universe. Despite ongoing scientific breakthroughs and advancements, scientists remain puzzled regarding the origins of the universe, and especially what might have happened before the Big Bang.
Carl Sagan famously said, “The cosmos is within us. We are made of star-stuff. We are a way for the universe to know itself.”
We may never know exactly how the universe began and the processes responsible for you reading this article right now. But like the simplicity this study presents, perhaps this study is simply a way for us to know the universe itself a little bit better.
What new discoveries about the origins of the universe will researchers make in the coming years and decades? Only time will tell, and this is why we science!
As always, keep doing science & keep looking up!
