Title :
Plasma kinetics in ultrashort pulse laser filament: Time resolved spectral measurement
Author :
Schmitt-Sody, Andreas ; White, William ; Shiffler, Donald ; Lucero, Adrian
Author_Institution :
Air Force Res. Lab., Kirtland AFB, NM, USA
Abstract :
Summary form only given. Filamentation of ultrafast laser pulses in air has been studied extensively. The very intense light channels, small in diameter for a long distance (widely believed to be an equilibrium of Kerr self-focusing, linear diffraction and plasma defocusing) leave a low density plasma in its wake [1]. Over the years, researchers have tried to characterize these plasma channels for applications. Such applications range from filament guided discharges to remote sensing. In order to use the filament plasma for applications, the plasma properties and dynamics need to be understood in great detail. In the air, the plasma densities are on the order of 1016 cm-3 [2] Until now, there are only few experimental reports that have measured the temperature of the plasma, yielding a temperature between 3000 and 5000 K [3,4]. One approach focused on the absorption and diffraction of a probe beam propagating perpendicularly to the filament [3], a second approach studied spectral line broadening and emission intensities [4]. The first approach is a pump probe experiment with good time resolution, but is not doable in single shot. Whereas the second approach integrates over the lifetime of the filament and therefore does not capture the time dynamics of the plasma. In our approach, we are looking at certain spectral lines of molecules to study the time dependent kinetics of the filament plasma produced by a 800nm, 1.5 mJ, 35 fs laser pulse by using a spectrometer coupled to a streak camera. The time resolution of the streak camera is 25 ps, and can capture a streak of more than 1 ns. Investigating the spectral lines in molecular nitrogen (337.1 nm, 357.6 nm and 353.6 nm) of the second positive system C3Πu-B3Πg, we observed the buildup of the light emission. The maximum of the emission is reached in the order of hundred picosecond. These results are expected since the excitation of thes- levels is driven by inelastic electron-molecule collisions and therefore closely correlated to the plasma kinetics. A computer model for the plasma kinetics is currently being developed to explain the observed experimental data and to extract the plasma temperature and density.
Keywords :
nitrogen; plasma collision processes; plasma density; plasma diagnostics; plasma kinetic theory; plasma light propagation; plasma temperature; spectral line broadening; wakes; Kerr self-focusing; N2; air; computer model; emission intensities; energy 1.5 mJ; filament guided discharges; filament lifetime; filament plasma; inelastic electron-molecule collisions; intense light channels; light emission; linear diffraction; low density plasma; molecular nitrogen; molecule spectral lines; plasma channels; plasma defocusing; plasma densities; plasma dynamics; plasma kinetics; plasma properties; plasma temperature; probe beam absorption; probe beam diffraction; pump probe experiment; remote sensing; second positive system C3Πu-B3Πg; spectral line broadening; spectrometer; streak camera; temperature 3000 K to 5000 K; time 25 ps; time 35 fs; time dependent kinetics; time dynamics; time resolution; time resolved spectral measurement; ultrafast laser pulse filamentation; ultrashort pulse laser filament; wake; wavelength 337.1 nm; wavelength 353.6 nm; wavelength 357.6 nm; wavelength 800 nm; Kinetic theory; Measurement by laser beam; Plasma measurements; Plasma temperature; Temperature measurement; Ultrafast optics;
Conference_Titel :
Plasma Sciences (ICOPS) held with 2014 IEEE International Conference on High-Power Particle Beams (BEAMS), 2014 IEEE 41st International Conference on
Conference_Location :
Washington, DC
Print_ISBN :
978-1-4799-2711-1
DOI :
10.1109/PLASMA.2014.7012474
