Conversion of CO2 in Ar plasmas EP2 Excitation and dissociation of CO2 heavily diluted in noble gas atmospheric pressure plasmas xlsx
Conversion of CO2 in He/Ar RF plasmas EP2 Excitation and dissociation of CO2 heavily diluted in noble gas atmospheric pressure plasmas xlsx
Figure 6 data: Temporal evolutions of Voltage (black), current (red) and emission (blue) EP2 Modular constructed metal-grid arrays - an alternative to silicon-based microplasma devices for catalytic applications zip
Figure 10 Data: Wave velocity pressure variation EP2 Modular constructed metal-grid arrays - an alternative to silicon-based microplasma devices for catalytic applications zip
Figure 4 data Phase angle voltage dependence COST-Jet Comparison of electron heating and energy loss mechanisms in an RF plasma jet operated in argon and helium ASCII tab separated
Figure 8 data: phase-resolved emission plots COST-Jet Comparison of electron heating and energy loss mechanisms in an RF plasma jet operated in argon and helium zip
Figure 8 Data: Expansion width; pressure variation EP2 Modular constructed metal-grid arrays - an alternative to silicon-based microplasma devices for catalytic applications zip
Figure 7 data: Bulk and sheath width as function of dissipated power COST-Jet Comparison of electron heating and energy loss mechanisms in an RF plasma jet operated in argon and helium txt
Figure 3 Data Power dissipation voltage dependence COST-Jet Comparison of electron heating and energy loss mechanisms in an RF plasma jet operated in argon and helium ASCII tab separated
Figure 9 data: tempoal development Development of the intensity integrated across the discharge gap at different power values COST-Jet Comparison of electron heating and energy loss mechanisms in an RF plasma jet operated in argon and helium ASCII tab separated