Guwahati: Researchers from the Indian Institute of Technology-Guwahati (IIT-Guwahati) and South Africa’s University of Stellenbosch are delving into one of the most profound mysteries in physics – the quantum nature of gravity.
The research – led by Associate Professor of the Department of Physics at IIT-Guwahati Bibhas Ranjan Majhi and Partha Nandi of the University of Stellenbosch – focuses on gravity-induced entanglement (GIE).
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This phenomenon has the potential to bridge two of the biggest pillars of modern science – general relativity and quantum mechanics.
Their work aims to understand how gravity behaves at incredibly small scales such as those of atoms and subatomic particles where existing theories start to unravel.
Physics currently operates under two separate frameworks.
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Albert Einstein’s general relativity explains how gravity works for massive objects like planets and stars, describing gravity as the curvature of space and time around these objects.
On the other hand, quantum mechanics governs the behaviour of particles on the atomic and subatomic levels.
While both theories excel in their respective domains, they fail to align when it comes to explaining how gravity functions at the quantum level.
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This disconnect has left a significant gap in our understanding, one that researchers hope to address through the pursuit of quantum gravity.
The team’s research takes an innovative approach by studying how gravity might lead to entanglement, a phenomenon in quantum mechanics where two particles become linked, such that the state of one affects the other, regardless of the distance between them.
The concept of GIE proposes that under certain conditions, gravitational forces may create this quantum connection, revealing a quantum aspect of gravity.
“We have developed a theoretical framework that connects a two-dimensional quantum harmonic oscillator with gravitational waves – ripples in space-time caused by massive objects like black holes. This approach bypasses the limitations of classical communication methods and explores whether quantised gravitational waves can induce entanglement,” Majhi explained.
“Our findings show that while classical gravitational waves do not generate entanglement, the quantum version of these waves does at the second order of gravitational perturbation,” he added.
This research has far-reaching implications. If GIE can be detected using gravitational wave detectors, it could provide the first evidence that gravity operates at a quantum level.
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Such a discovery could unlock other cosmic mysteries, such as the nature of dark matter and dark energy – two enigmatic components that make up most of the universe but are still poorly understood.
Majhi and Nandi’s work represents a significant step forward in the quest to understand the quantum nature of gravity.
Their research not only advances the search for quantum gravity but also lays the foundation for future discoveries, potentially uniting our understanding of the universe’s largest and smallest elements.