Ultrafast ps--TALIF and streak camera diagnostics of atomic hydrogen in a helium microplasma jet

Abstract

Picosecond two-photon absorption laser induced fluorescence (ps--TALIF) is combined with a streak camera (1 ps highest temporal resolution) to probe the effective lifetime (τeffH(n=3)) and absolute density (NH) of atomic hydrogen in the effluent of a helium atmospheric-pressure microplasma jet (μAPPJ). This approach allows for improved temporal resolution compared to conventional nanosecond diagnostics, enabling measurements of τeffH(n=3) as small as 50 ps, the corresponding NH reaching down to 1014 cm-3. Atomic densities are calibrated by performing identical ps--TALIF measurements in krypton gas contained in a custom-built low-pressure cuvette. Physical mechanisms that may be involved in the TALIF scheme such as photoionisation and/or stimulated emission are also assessed, ensuring reliable studies. The determined τeffH(n=3) and NH increase with the helium flow rate (QHe) in the range QHe=0.3-1 slm. Both quantities are maximized near the exit nozzle of the μAPPJ, obtaining values below 400 ps and 6x1014 cm-3, respectively. As the axial distance increases, τeffH(n=3) declines with a rate of ≈65 ps/mm for QHe=1 slm which is about 3 times smaller than for QHe=0.3 slm. These findings reveal a strong correlation between the experimentally-measured τeffH(n=3) and the local air entrainment into the jet as indicated by their comparison with calculated effective lifetimes based on published quenching rates. Furthermore, operating the μAPPJ in the burst mode allows for the estimation of the residence time (tres) of ground state H--atoms in the helium gas channel, which is larger for QHe=0.3 slm (tres ≈ 1.2 ms) compared to QHe=1 slm (tres ≈ 0.5 ms). H-atoms consumption in the gas channel can be affected by diffusion and mechanisms involving neutral ground-state and metastable species among others. Furthermore, based on an error propagation analysis, density uncertainty as high as 64% (depending on the operating condition) is revealed. This mainly originates in the ratio of the two-photon absorption cross sections of Kr and H atoms ( σ(2)Kr / σ(2)H) which has not yet been measured in the picosecond regime. Nevertheless, the combined utilisation of ps--TALIF and streak camera diagnostics demonstrates high sensitivity and temporal resolution for directly probing key reactive species in atmospheric pressure microplasmas.