Home > Research > Publications & Outputs > The interaction of a flowing plasma with a dipo...


Text available via DOI:


View graph of relations

The interaction of a flowing plasma with a dipole magnetic field: measurements and modelling of a diamagnetic cavity relevant to spacecraft protection

Research output: Contribution to journalJournal article

  • R. Bamford
  • K. J. Gibson
  • A. J. Thornton
  • J. Bradford
  • R. Bingham
  • L. Gargate
  • L. O. Silva
  • R. A. Fonseca
  • M. Hapgood
  • C. Norberg
  • T. Todd
  • R. Stamper
Article number124025
<mark>Journal publication date</mark>12/2008
<mark>Journal</mark>Plasma Physics and Controlled Fusion
Issue number12
Number of pages11
<mark>Original language</mark>English
Event35th European-Physical-Society Conference on Plasma Physics - Hersonissos, Greece


Conference35th European-Physical-Society Conference on Plasma Physics


Here we describe a new experiment to test the shielding concept of a dipole-like magnetic field and plasma, surrounding a spacecraft forming a 'mini magnetosphere'. Initial laboratory experiments have been conducted to determine the effectiveness of a magnetized plasma barrier to be able to expel an impacting, low beta, supersonic flowing energetic plasma representing the solar wind. Optical and Langmuir probe data of the plasma density, the plasma flow velocity and the intensity of the dipole field clearly show the creation of a narrow transport barrier region and diamagnetic cavity virtually devoid of energetic plasma particles. This demonstrates the potential viability of being able to create a small 'hole' in a solar wind plasma, of the order of the ion Larmor orbit width, in which an inhabited spacecraft could reside in relative safety. The experimental results have been quantitatively compared with a 3D particle-in-cell 'hybrid' code simulation that uses kinetic ions and fluid electrons, showing good qualitative agreement and excellent quantitative agreement. Together the results demonstrate the pivotal role of particle kinetics in determining generic plasma transport barriers.