We compare non-local magnetoresistance measurements in multi-terminal Ni nanostructures with corresponding local experiments. In both configurations, the measured voltages show the characteristic features of anisotropic magnetoresistance (AMR). However, the magnitude of the non-local AMR signal is up to one order of magnitude larger than its local counterpart. Moreover, the non-local AMR increases with increasing degree of non-locality, i.e., with the separation between the region of the main current flow and the voltage measurement region. All experimental observations can be consistently modeled in terms of current spreading in a non-isotropic conductor. Our results show that current spreading can significantly enhance the magnetoresistance signal in non-local experiments.

Topics
Hall effect, Nanomagnets, Ferromagnetic materials, Magnetic ordering, Electrical properties and parameters, Magnetic fields, Electric power, Semiconductor device fabrication, Thin films, Electron-beam lithography
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© 2011 American Institute of Physics.
2011
American Institute of Physics
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