Observation of Elastic Orbital Angular Momentum Transfer: Coupling Flexural Waves in Partially Submerged Pipes to Acoustic Waves in Fluids

TL;DR

This paper experimentally demonstrates the transfer of elastic orbital angular momentum from a partially submerged hollow elastic pipe to a fluid, generating Bessel-like acoustic beams, revealing new possibilities for elastic wave manipulation and acoustic tweezing.

Contribution

It provides the first experimental evidence of elastic orbital angular momentum transfer via coupling of flexural waves in pipes to acoustic waves in fluids, expanding the understanding of elastic wave angular momentum.

Findings

Elastic orbital angular momentum can be transferred from pipes to fluids.

Coupling flexural waves in pipes to acoustic fields generates Bessel-like beams.

This method enables new acoustic beam shaping techniques.

Abstract

Research into the orbital angular momentum carried by helical wave-fronts has been dominated by the fields of electromagnetism and acoustics, owing to its practical utility in sensing, communication and tweezing. Despite the huge research effort across the wave community, only recently has elastic orbital angular momentum been theoretically shown to exhibit similar properties. Here we experimentally observe the transfer of elastic orbital angular momentum from a hollow elastic pipe to a fluid in which the pipe is partially submerged, in an elastic analogue of Durnin's slit-ring experiment for optical beams. This transfer is achieved by coupling the dilatational component of guided flexural waves in the pipe with the pressure field in the fluid; the circumferential distribution of the normal stress in the pipe acts as a continuous phased pressure source in the fluid resulting in the generation of Bessel-like acoustic beams. This demonstration has implications for future research into a new regime of orbital angular momentum for elastic waves, as well providing a new method to excite acoustic beams that carry orbital angular momentum that could create a new paradigm shift for acoustic tweezing.