Abstract
A magnetic linear accelerator (or Gauss accelerator) is a device that uses the conversion of magnetic energy into kinetic energy to launch an object with high velocity. A simple experimental implementation consists of a line of steel spheres in which the first one is a permanent magnetic sphere. If another steel ball collides with the magnetic sphere from the left, the rightmost steel sphere is ejected at a much larger velocity than the impacting steel sphere. Several approaches have been published to determine the velocity of the ejected sphere, for example by using photogates [1, 2] or by measuring the impact position of the ejected sphere after falling from a table [3]. All of these approaches have in common that the measurement of the velocity is a static process. This article describes an approach in which video motion analysis on tablet computers [4, 5] is used to measure simultaneously the time course of the velocity of the impacting steel sphere as well as the ejected steel sphere, thus giving students insight into the dynamics of the processes that lead to a higher kinetic energy of the ejected sphere.
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Becker-Genschow, S., Thees, M., Kuhn, J. (2022). The Dynamics of the Magnetic Linear Accelerator Examined by Video Motion Analysis. In: Kuhn, J., Vogt, P. (eds) Smartphones as Mobile Minilabs in Physics. Springer, Cham. https://doi.org/10.1007/978-3-030-94044-7_11
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DOI: https://doi.org/10.1007/978-3-030-94044-7_11
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