【 摘 要 】

Part I:

A TM₀₁₁ microwave cavity was used to measure the radially averaged electron density n^¯_e and the electron-neutral collision frequency ν_en in d.c. glow discharge positive columns of pure rare gases and their binary mixtures. Electric field E was measured by measuring the floating potential across pairs of probes in the plasma. The pure gases studied were He, Ne and Ar at pressures of 1-8 torr and discharge currents I of 5-20 mA. The calculated values of the electron drift velocity v_d in He and Ne are substantially lower than the Bradbury and Nielson drift tube values, indicating substantial ionization via metastables in the range of p and I investigated. Discharges in He-Ar and He-Ne mixtures at p = 2-5 torr and I = 15 mA exhibit time and space dependent values of n^¯_e, ν_en due to the effect of cataphoresis. The results indicate that the Shair and Remer model is a reasonable description of the phenomenon of cataphoresis in these mixtures where the impurity (Ar or Ne) content is in the range of 2-20%.

Part II:

By employing a positive column flow reactor with low residence times (< 100 msec) in d.c. discharges with low currents (< 5 mA), it is possible to convert up to 5% of the feed methane into ethane, ethylene and hydrogen with negligible formation of solid and liquid products. The percent methane in the argon or helium feed C_o affects the product distribution, with good selectivity for C_o > 5%. Average steady-state electron densities in the discharge were simultaneously measured by perturbation of the resonance of a TM₀₁₀ microwave cavity.A pulsed d.c. discharge enabled the residence time to be effectively reduced even further. The pulsed discharge experiments were conducted at 3-9 torr with pulse durations ~ 1 msec and pulse intervals of 20-50 msec. Pulse current was measured as a function of time with a current probe. The TM₀₁₀ cavity was used to obtain transient electron densities in the discharge, which varied between 10⁹ and 10¹⁰ electrons/cm³.

The kinetic results are consistent with a free radical mechanism with electron-impact dissociation as the initiating step. Derived values of the integrated cross-section for CH₄ + e →^α CH₃ + H + e and CH₄ + e → ^β CH₂ + H₂ + e are in the range 3.6 - 15.5 x 10^-11cm³sec^-1, and that for C₂H₄ + e →^γ C₂H₂ + H₂ + e is ~ 9 x 10^-10cm³sec^-1. α andβ fall with C_o in the range 4.0 - 12.6%, indicating a shift of the electron energy distribution function f_e(ε) to lower values of ε. Calculations are presented for the case of H₂ dissociation to illustrate the strong effect of the tail end of f_e(ε) on the rate of chemical reaction.

【 预 览 】

附件列表

Files	Size	Format	View
I. Experimental tests on the positive column in pure rare gases and their binary mixtures. II. Kinetics of hydrocarbon reactions in the positive column of D.C. and pulsed D.C. discharges	74104KB	PDF	download