Maintaining a discharge using a travelling electromagnetic wave results in a linear decrease in electron density along the plasma column. This distribution corresponds to the power dissipated by the wave to heat electrons in the gas

The experimentally recorded distribution of electron density along a plasma column supported by a travelling EM wave is linearly decreasing from start to finish; its slope depends strictly and solely on the gas pressure, the frequency of the wave and the internal radius of the discharge tube. There are two opposing descriptive models: a) an EM surface wave propagates along the three-constituent media of the tubular discharge, i.e. the plasma column, the dielectric tube and the outer wall of the latter. This model does not faithfully reproduce the linearity of the axial distribution of the electron density, at any rate always at the end of the column; b) an EM wave propagates in a vacuum (ambient air) guided by the outer wall of the discharge tube, its electric field heating the electrons present in the gas and thus ionising it. As each electron thus obtained draws its energy from the electric field of the wave, the axial distribution of the electron density can also be considered as a conservation relationship between the energy dissipated by the wave and the electron density produced. This model makes it possible in all circumstances to find a linear axial distribution of electron density from the beginning to the end of the column. The electron heating mechanism finally exhausts all the energy in the wave, so there is no more energy available for it to propagate otherwise, for example, along the dielectric tube or the plasma column. The origin of the linear behaviour of the electron density distribution lies in the stability condition of a discharge maintained by a travelling electromagnetic wave, which requires the electron density to decrease monotonically axially.