New Journal of Physics (Jan 2014)

Helioseismology in a bottle: modal acoustic velocimetry

  • Santiago Andrés Triana,
  • Daniel S Zimmerman,
  • Henri-Claude Nataf,
  • Aurélien Thorette,
  • Vedran Lekic,
  • Daniel P Lathrop

DOI
https://doi.org/10.1088/1367-2630/16/11/113005
Journal volume & issue
Vol. 16, no. 11
p. 113005

Abstract

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Measurement of the differential rotation of the Sunʼs interior is one of the great achievements of helioseismology, providing important constraints for stellar physics. The technique relies on observing and analyzing rotationally-induced splittings of p -modes in the star. Here, we demonstrate the first use of the technique in a laboratory setting. We apply it in a spherical cavity with a spinning central core (spherical-Couette flow) to determine the mean azimuthal velocity of the air filling the cavity. We excite a number of acoustic resonances (analogous to p -modes in the Sun) using a speaker and record the response with an array of small microphones on the outer sphere. Many observed acoustic modes show rotationally-induced splittings, which allow us to perform an inversion to determine the airʼs azimuthal velocity as a function of both radius and latitude. We validate the method by comparing the velocity field obtained through inversion against the velocity profile measured with a calibrated hot film anemometer. This modal acoustic velocimetry technique has great potential for laboratory setups involving rotating fluids in axisymmetric cavities. It will be useful especially in liquid metals where direct optical methods are unsuitable and ultrasonic techniques very challenging at best.

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