INVESTIGATION OF CONCENTRATION INFLUENCE ON ELECTRONIC COEFFICIENTS OF HE:NE PLASMA BY PREDICTING A MATHEMATICAL MODEL

In this work a comprehensive investigation of specific electron transport 
coefficients in plasma state He-Ne gas mixtures has been carried out. Theoretical 
calculations and estimated data are presented that enable us to measure the 
influence of He:Ne concentration on plasma electronic coefficients based on the 
variation in a plasma field resistance situated in a varied electric field and under 
a thermodynamic equilibrium. The 
Boltzmann equation was used to calculate 
several concentrations of energy mobility and momentum frequency and varied 
electric fields. Utilisation of the BOLSIG+ simulation verified the results that the 
Boltzmann distribution analysis revealed. By using a simulation process, 
appropriated equations which indicate the variation of plasma electronic 
coefficients according to the variation of mixture concentration and reduced 
electric field (E/N) have been obtained. The applied reduced electric field has 
been chosen to be in the limited range of (0-100) Td, and for several 
concentrations in the limited range of (0.1-0.7) mol. The between unique 
information (utilizing BOLSIG+) and our estimated data. The results show a stark 
resemblance involving original data (using BOLSIG+) and our estimated data, 
our simulation data, where root mean square of (νe-i /N,) = 4.2×10-7, root mean 
square of µƐN = 1.5×10-6 and root mean square of <> = 9.4×10-5. This 
improvement in electronic coefficients assume a significant part in the 
development of energy for He:Ne laser