Experimental investigation of the angular symmetry of optical force in a solid dielectric

The textbook-accepted formulation of electromagnetic force was proposed by Lorentz in the 19th century, but its validity has been challenged due to incompatibility with the special relativity and momentum conservation. The Einstein-Laub formulation, which can reconcile those conflicts, was suggested as an alternative to the Lorentz formulation. However, intense debates on the exact force are still going on due to lack of experimental evidence. Here, we report the first experimental investigation of angular symmetry of optical force inside a solid dielectric, aiming to distinguish the two formulations. The experiments surprisingly show that the optical force exerted by a Gaussian beam has components with the angular mode numbers of both 2 and 0, which cannot be explained solely by the Lorentz or the Einstein-Laub formulation. Instead, we found that a modified Helmholtz theory by combining the Lorentz force with additional electrostrictive force can explain our experimental results. Our results represent a fundamental leap forward in determining the correct force formulation and will update the working principles of many applications involving electromagnetic forces. (C) 2021 Optical Society of America under the terms of the OSA Open Access Publishing Agreement.

Automated summary

The experimental investigation showed that the optical force exerted by a Gaussian beam inside a solid dielectric displays angular symmetry, with components having different angular mode numbers. This result cannot be solely explained by the Lorentz or Einstein-Laub formulations but requires a combination of Lorentz force with additional electrostrictive force for explanation.