Not Big Bang, new theory uses ‘Gravity' and ‘Quantum Physics' to explain the universe's birth
A new theory by University of Barcelona physicists suggests the universe may have formed from De Sitter space using only gravity and quantum mechanics. Rather than rejecting the Big Bang, it offers a simpler, testable alternative to explain the cosmos's origin.
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How does this theory explain the birth of the Universe?
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What is De Sitter space?
Could the universe have formed without a Big Bang?
What could this mean for science?
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A new study by researchers from the University of Barcelona and the University of Padua challenges one of the core ideas of modern cosmology : that the Universe began with a rapid expansion called inflation. For decades, inflation has helped explain why the Universe looks the way it does, but it relies on speculative ideas like unknown particles and unobserved forces.This new theory removes those uncertainties. Instead, it suggests that the early Universe can be fully explained using only gravity and quantum mechanics, two well-established areas of physics. If proven correct, this would be a major shift in how scientists understand the cosmos.The researchers propose that the Universe began in a simple, uniform state known as De Sitter space , which aligns with what we observe today about dark energy . In this setting, tiny quantum fluctuations , essentially ripples in space and time, naturally occurred.Over time, these ripples evolved into gravitational waves that created the small differences indensity that allowed matter to clump together, eventually forming galaxies, stars, and planets.This process doesn't require the existence of hypothetical fields like the "inflaton" making the theory both cleaner and more testable.De Sitter space is a theoretical model of the Universe that describes a smooth, empty space that expands on its own due to the presence of a positive cosmological constant, something like dark energy.It doesn't include matter or light, just the energy of space itself stretching endlessly.Scientists use this idea to understand how the Universe behaves when dominated by dark energy, especially in its earliest or far-future stages.No, this new theory doesn't reject the Big Bang but offers a compelling alternative. It suggests that the universe may have emerged not from a fiery explosion, but from a stable, expanding state called De Sitter space, relying solely on gravity and quantum mechanics.Their model provides a minimalist and testable explanation rather than depending on speculative elements like inflaton fields. It reshapes our understanding of cosmic origins by showing how structure could arise from fundamental laws, inviting new ways to explore the universe's earliest moments.This theory stands out because it makes testable predictions using real, observable physics. Future research and observations could prove or disprove it, especially of gravitational waves and cosmic structure.Lead author Raúl Jiménez called the proposal 'simple, elegant, and powerful,' noting that it avoids adding 'things we have never seen' just to make the math work. If validated, it could represent a major scientific breakthrough, changing how we think about our cosmic origins.
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