Ultrashort pulsed laser atmospheric filament properties and microwave radiation inferred from S-band guided wave interaction and self-emission
Abstract
The electrical conductivity σ of the plasma filament left behind by an ultrashort pulsed laser (USPL) optical pulse after it is geometrically then self-focused in air via the Kerr effect is measured by attenuation of a 3.2 GHz TE10 mode within an S-band waveguide through which the filament passes, taking into account the characteristic radius R of the filament, as determined by fast camera visible light imaging. Models of the major air constituents' ionization rate Wi vs. local laser intensity I, and of temperature T and mean axial electron momentum pz vs. peak laser intensity I0 are then used to infer a hypothetical steady state filament's I0, T, major species particle densities, and assumed axially invariant current time integral Q and current decay rate ν after pulse passage. Q is independently measured via the filament's self-emission signal in the waveguide for comparison. The theoretical far field microwave radiation pattern due to the actual axial variation in Q=Q( z) is compared favorably to published measurements. A much lower upper bound on ν is inferred once such radiation is taken into account. Results are presented along a 30 cm long filament at a broad range of atmospheric pressures.
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