By Brad Bergan
Quantum physicists have toiled to no avail for decades in their attempts to subsume gravity (the first cosmological force ever discovered) into quantum physics. A group of researchers recently proposed a new experiment that could redefine nature of gravity, and transform our understanding of the fundamental forces of the universe.
Quantum mechanics is a theory concerned with all fundamental particles and the forces they undergo, with the exception of gravitational attraction. In order to understand what happens inside a black hole, or what took place during The Big Bang, the theories of gravity and quantum mechanics must be combined. The problem is, whenever this union is attempted, both theories fall apart.
If gravity turns out to be a quantum mechanical force in hiding, then the entanglement we observe in photons could also apply to falling masses. In other words, if two objects (identical in every way besides horizontal position) were in free fall, then measuring the properties of one object could instantaneously affect the other. Sougato Bose of University College London and colleagues have outlined an experiment to test this very hypothesis.
Consider a neutrally charged particle weighing 10-14 kilograms. Inside this particle is a material with spin, which can go up or down. If you drop the particle through a continuously changing magnetic field, it’s path should be altered according to its inner-spin, almost as if the particle hits a cosmic fork in the magnetic road. Left for up spin and right for down.
As the particle falls, it’s in superposition, or simultaneous occupation, of both paths (think of Schrödinger’s cat, a thought experiment on superposition). Technically, from release, the particle could take both paths (we have to think outside of the confines of linear time for this). Combine all possible paths, and we witness the one state that represents the path where the particles take closest trajectories.
The distance between trajectories should approach no less than 200 micrometers, in order to avoid other, gravity-dominating interactions. A test should show us if their spin components are entangled once these masses are returned to their original states. Thus, such a test is intended to rule out other interfering forces, e.g., the Casimir force, or electromagnetic interactions.
However, Bose said it’s important to note that a lack of observed entanglement does not prove that all gravity is classical — unless the experiment can definitively show that no other interactions with the environment, like collisions with stray photons or molecules, have interfered.
Antoine Tilloy of the Max Planck Institute of Quantum Optics in Germany has voiced his approval, though with the caveat that a positive finding will falsify only someclasses of theories of classical gravity. “That said, the class is sufficiently large that I think the result would still be amazing,” he told New Scientist.
In the same article, Maaneli Derekhshani of Utrecht University in the Netherlands argued that a bona fide verified null finding would prove gravity does not have quantum roots. “This would then raise tough but interesting questions about how and when exactly gravity ‘turns on’ in the quantum-classical transition for ordinary matter,” Derekshani said. “A null result would be the most surprising and interesting outcome.”
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