A compact acoustic spanner to rotate macroscopic objects. Toninelli, E., Cox, M. A., Gibson, G. M., Brown, S. D., Edgar, M. P., Forbes, A., & Padgett, M. J. Scientific Reports, 9(1):6757, Nature Publishing Group, dec, 2019. ![A compact acoustic spanner to rotate macroscopic objects [link]](https://bibbase.org/img/filetypes/link.svg "link")
Paper doi abstract bibtex Waves can carry both linear and angular momentum. When the wave is transverse (e.g. light), the angular momentum can be characterised by the “spin” angular momentum associated with circular polarisation, and the “orbital” angular momentum (OAM) arising from the phase cross-section of the beam. When the wave is longitudinal (e.g. sound) there is no polarization and hence no spin angular momentum. However, a suitably phase-structured sound beam can still carry OAM. Observing the transfer of OAM from sound to a macroscopic object provides an excellent opportunity to study the exchange of energy between waves and matter. In this paper we show how to build a compact free-space acoustic spanner based on a 3D-printed sound-guiding structure and common electronic components. We first characterise the sound fields by measuring both phase and amplitude maps, and then show a video of our free-space acoustic spanner in action, in which macroscopic objects spin in a circular motion and change direction of rotation according to the handedness of the OAM acoustic field.
@article{Toninelli2019a,
abstract = {Waves can carry both linear and angular momentum. When the wave is transverse (e.g. light), the angular momentum can be characterised by the “spin” angular momentum associated with circular polarisation, and the “orbital” angular momentum (OAM) arising from the phase cross-section of the beam. When the wave is longitudinal (e.g. sound) there is no polarization and hence no spin angular momentum. However, a suitably phase-structured sound beam can still carry OAM. Observing the transfer of OAM from sound to a macroscopic object provides an excellent opportunity to study the exchange of energy between waves and matter. In this paper we show how to build a compact free-space acoustic spanner based on a 3D-printed sound-guiding structure and common electronic components. We first characterise the sound fields by measuring both phase and amplitude maps, and then show a video of our free-space acoustic spanner in action, in which macroscopic objects spin in a circular motion and change direction of rotation according to the handedness of the OAM acoustic field.},
author = {Toninelli, Ermes and Cox, Mitchell A. and Gibson, Graham M. and Brown, Stuart D. and Edgar, Matthew P. and Forbes, Andrew and Padgett, Miles J.},
doi = {10.1038/s41598-019-43046-4},
issn = {2045-2322},
journal = {Scientific Reports},
keywords = {Acoustics,Electrical and electronic engineering},
month = {dec},
number = {1},
pages = {6757},
publisher = {Nature Publishing Group},
title = {{A compact acoustic spanner to rotate macroscopic objects}},
url = {http://www.nature.com/articles/s41598-019-43046-4},
volume = {9},
year = {2019}
}
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