Abstract
In this paper, a detailed investigation of the spatio-temporal dynamics of a pulsed microwave plasma is presented. The plasma is ignited inside a dielectric tube in a repetitively pulsed regime at pressures ranging from 1 up to 100 mbar with pulse repetition frequencies from 200 Hz up to 500 kHz. Various diagnostic techniques are employed to obtain the main plasma parameters both spatially and with high temporal resolution. Thomson scattering is used to obtain the electron density and mean electron energy at fixed positions in the dielectric tube. The temporal evolution of the two resonant and two metastable argon 4s states are measured by laser diode absorption spectroscopy. Nanosecond time-resolved imaging of the discharge allows us to follow the spatio-temporal evolution of the discharge with high temporal and spatial resolution. Finally, the temporal evolution of argon 4p and higher states is measured by optical emission spectroscopy. The combination of these various diagnostics techniques gives deeper insight on the plasma dynamics during pulsed microwave plasma operation from low to high pressure regimes. The effects of the pulse repetition frequency on the plasma ignition dynamics are discussed and the plasma-off time is found to be the relevant parameter for the observed ignition modes. Depending on the delay between two plasma pulses, the dynamics of the ionization front are found to be changing dramatically. This is also reflected in the dynamics of the electron density and temperature and argon line emission from the plasma. On the other hand, the (quasi) steady state properties of the plasma are found to depend only weakly on the pulse repetition frequency and the afterglow kinetics present an uniform spatio-temporal behavior. However, compared to continuous operation, the time-averaged metastable and resonant state 4s densities are found to be significantly larger around a few kHz pulsing frequency.
Highlights
The temporal evolution of the two resonant and two metastable argon 4s states are measured by laser diode absorption spectroscopy
Midha et al [5] showed for instance that pulsing an inductively coupled plasma (ICP) in chlorine allow the increase of the time-averaged chlorine negative ion Cl− density because of electron attachment in the temporal afterglow
Numerical modeling by Lieberman et al [7] of low pressure ICP discharges predicted that pulsed operation can allow one to obtain higher plasma densities than in continuous wave (CW) operation mode
Summary
An easy way to study the evolution of a pulsed plasma is to monitor the light emission from the plasma In this case, good knowledge of the excitation kinetics populating high-lying states is needed in order to deduce which temporally varying internal parameters are responsible for the observed changes in the density of particles in these specific states [15]. As microwave plasmas are often compared in terms of behavior to dc glow discharges [22,23,24], it is interesting to see whether applying a temporal modulation of the power can modify the time averaged properties of the plasma in a similar way as in an ac or pulsed dc field [25, 26]. The combination of the different diagnostic methods allows us to obtain a thorough insight in the mechanisms at play for the discharge generation and afterglow dynamics
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