Kinematic dynamo action in spherical Couette flow |
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| Authors: | Xing Wei Andrew Jackson Rainer Hollerbach |
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| Institution: | 1. Institut für Geophysik, ETH , Zürich 8092 , Switzerland xing.wei@erdw.ethz.ch;3. Institut für Geophysik, ETH , Zürich 8092 , Switzerland;4. Institut für Geophysik, ETH , Zürich 8092 , Switzerland;5. Department of Applied Mathematics , University of Leeds , Leeds LS2 9JT , UK |
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| Abstract: | We investigate numerically kinematic dynamos driven by flow of electrically conducting fluid in the shell between two concentric differentially rotating spheres, a configuration normally referred to as spherical Couette flow. We compare between axisymmetric (2D) and fully 3D flows, between low and high global rotation rates, between prograde and retrograde differential rotations, between weak and strong nonlinear inertial forces, between insulating and conducting boundaries and between two aspect ratios. The main results are as follows. Azimuthally drifting Rossby waves arising from the destabilisation of the Stewartson shear layer are crucial to dynamo action. Differential rotation and helical Rossby waves combine to contribute to the spherical Couette dynamo. At a slow global rotation rate, the direction of differential rotation plays an important role in the dynamo because of different patterns of Rossby waves in prograde and retrograde flows. At a rapid global rotation rate, stronger flow supercriticality (namely the difference between the differential rotation rate of the flow and its critical value for the onset of nonaxisymmetric instability) facilitates the onset of dynamo action. A conducting magnetic boundary condition and a larger aspect ratio both favour dynamo action. |
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| Keywords: | Kinematic dynamo Spherical Couette flow |
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