628 19 2108 2 11259 document 2108 dataset.zip application/x-zip ba7f0eca807248d6ab3c40426d9d64bf MD5 58830046 2018-08-15 15:29:17 https://researchdata.gla.ac.uk/628/1/dataset.zip 628 1 1 application/x-zip Mixed en public cc_by_4

dataset.zip

data 2109 2 11261 document 2109 readme.txt text/plain 8f60e979d788681978dcc2a9314ed4c1 MD5 442 2018-08-15 15:29:23 https://researchdata.gla.ac.uk/628/2/readme.txt 628 2 2 text/plain Text en public cc_by_4

readme.txt

readme 2110 1 11269 document 2110 indexcodes.txt text/plain 2026f18a0beda6f936a365831b283880 MD5 330 2018-08-15 15:49:25 https://researchdata.gla.ac.uk/628/3/indexcodes.txt 628 3 3 text/plain other Generate index codes conversion from Text to indexcodes en public

indexcodes.txt

http://eprints.org/relation/isVersionOf https://researchdata.gla.ac.uk/id/document/2109 http://eprints.org/relation/isVolatileVersionOf https://researchdata.gla.ac.uk/id/document/2109 http://eprints.org/relation/isIndexCodesVersionOf https://researchdata.gla.ac.uk/id/document/2109 archive 5 disk0/00/00/06/28 2018-08-15 15:33:11 2024-04-17 11:30:32 2018-08-15 15:33:11 data_collection show Toninelli Ermes 35232 Cox Mitchell A. Gibson Graham 5412 Brown Stuart D. Edgar Matthew 15561 Forbes Andrew 28557 Padgett Miles 10309 0000-0001-6643-0618 glaresearchdata:2018-08-15-628 pub 30600000 The two movie clips show the transfer of acoustic orbital angular momentum (OAM) to matter. More specifically, the acoustic spanner is used to set macroscopic objects into rotational motion. The first clip named 'peanut.mov' shows a polystyrene packing peanut spinning both clockwise and counter-clockwise as the handedness of the acoustic OAM is switched. As the sound field is switched to a uniform phase, the packing peanut stops moving. The second clip named 'floatingGraphite.mov' shows a considerable number of graphite flakes floating on the surface of water being set into rotation by the acoustic spanner. From a qualitative point of view, the rotating flakes and their distribution of velocities is indicative of the acoustic OAM field that they intercept. The camera that captured these videos was placed beneath the transparent Petri-dish sample-holder, pointed upward and looking up at the small end of the funnel-shaped acoustic concentrator (see Fig. 1 of the manuscript to locate the sample holder and the acoustic concentrator). The designs for the 3D printer of all of the printed parts of the acoustic spanner are found in the 3Dprinter folder. Both .STL and native Autodesk Fusion 360 .f3d files are provided. The .STL files are ready to be printed (we used Cura v. 2.3.1 to generate from these the .gcode files for the printer). The Arduino code is provided and can be found in the arduino folder (note the directions to fix the Arduino PWM frequency bug, as indicated in the commented lines at the beginning of the Arduino sketch file). A copy of all of the files is stored on GitHub at the following link: https://github.com/witseie/AcousticSpanner 2018-08-15 published University of Glasgow 10.5525/gla.researchdata.628 Text Video 63638 1 EPSRC Centre for Doctoral Training in Sensing and Measurement Andrew Harvey Engineering and Physical Sciences Research Council (EPSRC) EP/L016753/1 SCHOOL OF PHYSICS & ASTRONOMY 66723 19 UK Quantum Technology Hub in Enhanced Quantum Imaging Miles Padgett Engineering and Physical Sciences Research Council (EPSRC) EP/M01326X/1 S&E P&A - PHYSICS & ASTRONOMY 62450 1 TWISTS - Twists & more: the complex shape of light Miles Padgett European Research Council (ERC) 340507 S&E P&A - PHYSICS & ASTRONOMY FALSE EN https://github.com/witseie/AcousticSpanner software 2028-08-15 R FALSE FALSE https://eprints.gla.ac.uk/id/eprint/183852