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A mathematical rate equation model using a Monte Carlo simulation has been used to analyze the laser optogalvanic signals of neon waveforms excited at 638.3 nm and 650.7 nm and arising from the $1s_{4}$ state transitioning to $2p_{7}$ and $2p_{8}$ states, respectively. The decay rates have been determined for the directly involved $1s_{4}$ state and also for the indirectly involved $1s_{2}$ and $1s_{5}$ states. There is good agreement among the decay rate constants found and they show a predominantly linear variation with increasing current.
}, issn = {2079-7346}, doi = {https://doi.org/10.4208/jams.051509.071209a}, url = {http://global-sci.org/intro/article_detail/jams/8072.html} }A mathematical rate equation model using a Monte Carlo simulation has been used to analyze the laser optogalvanic signals of neon waveforms excited at 638.3 nm and 650.7 nm and arising from the $1s_{4}$ state transitioning to $2p_{7}$ and $2p_{8}$ states, respectively. The decay rates have been determined for the directly involved $1s_{4}$ state and also for the indirectly involved $1s_{2}$ and $1s_{5}$ states. There is good agreement among the decay rate constants found and they show a predominantly linear variation with increasing current.