Oblique ion collection in the drift-approximation: how magnetized Mach-probes really work

Abstract

The anisotropic fluid equations governing a frictionless obliquely-flowing plasma around an essentially arbitrarily shaped three-dimensional ion-absorbing object in a strong magnetic field are solved analytically in the quasi-neutral drift-approximation, neglecting parallel temperature gradients. The effects of transverse displacements traversing the magnetic presheath are also quantified. It is shown that the parallel collection flux density dependence upon external Mach-number is n∞ cs [-1 -(M∞- Mθ)] where θ is the angle (in the plane of field and drift velocity) of the object-surface to the magnetic-field and M∞ is the external parallel flow. The perpendicular drift, , appearing here consists of the external drift plus a weighted sum of the ion and electron electron diamagnetic drifts that depends upon the total angle of the surface to the magnetic field. It is that somewhat counter-intuitive combination that an oblique (transverse) Mach probe experiment measures.