Beam balance designs could elucidate the origins of dark energy

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Scheme of the balanceprototype including the opticalread-out and the aluminumsuspended sample (in blue) and the brass counterweight (in orange). Credit: The European Physical Journal Plus (2024). DOI: 10.1140/epjp/s13360-024-04920-x

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Scheme of the balanceprototype including the opticalread-out and the aluminumsuspended sample (in blue) and the brass counterweight (in orange). Credit: The European Physical Journal Plus (2024). DOI: 10.1140/epjp/s13360-024-04920-x

One of the greatest problems in modern physics is to reconcile the enormous difference between the energy carried by random fluctuations in the vacuum of space, and the dark energy driving the universe’s expansion.

Through new research published in The European Physical Journal Plus, researchers led by Enrico Calloni at the University of Naples Federico II, Italy, have unveiled a prototype for an ultra-precise beam balance instrument, which they hope could be used to measure the interaction between these vacuum fluctuations and gravitational fields. With some further improvements, the instrument could eventually enable researchers to shed new light on the enigmatic origins of dark energy.

Inside a vacuum, electromagnetic waves are constantly emerging and disappearing through random fluctuations, so that even though the space doesn’t contain any matter, it still carries a certain amount of energy. Through their research, Calloni’s team aimed to measure the influence of these fluctuations using a state-of-the-art beam balance.

Designed to operate at temperatures of 90K (-183°C), the team’s instrument carries a small sample of a high-temperature superconductor at one end of the beam, initially balanced out by counterweights on the other end. Through quantum effects triggered by its interaction with random vacuum fluctuations, the team predicted that this sample should undergo minuscule changes in weight.

These changes in turn could be detected using interferometry. This would involve comparing the distances traveled by both parts of a split light beam as they bounce back from each end of beam—created due to the new difference in weight between the superconductor sample and the counterweight.

The team’s study details their initial tests for a prototype for their beam balance at a lab in Sardinia, which experiences extremely low levels of seismic noise. Based on their early results, Calloni and colleagues are now confident that when complete, their final experiment would be sensitive enough to pick up the interaction between vacuum fluctuations and gravitational fields.

More information:
Annalisa Allocca et al, Thermal noise-limited beam balance as prototype of the Archimedes vacuum weight experiment and B-L dark photon search, The European Physical Journal Plus (2024). DOI: 10.1140/epjp/s13360-024-04920-x

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