Detailed Modeling of the Pyrolysis of Trichloroethene: Formation of Chlorinated Aromatic Species

Abstract

Comprehensive product yield determinations from the high-temperature, gas-phase pyrolysis of trichloroethene (C₂HCl₃) using two fused silica tubular flow reactors coupled to in-line gas chromatographic-mass spectrometry analyses are reported. Initial decomposition was observed at 1000 K with formation of HCl and C₂Cl₂. Pronounced molecular growth was observed at higher temperatures as evidenced by the formation of C₂Cl₂, C₄Cl₄, and C₆Cl₆ (cy) as major (≥5mole%) products and C₄Cl₂, C₄Cl₆, C₆HCl₅ (cy), C₈Cl₆ (cy), C₈Cl₈ (cy), C₁₀Cl₈ (cy), and C₁₂Cl₈ (cy) as minor (≤5mole%) products.

The effects of reactor surface area to volume (S/V) ratio were evaluated by conducting detailed product analyses with 0.1 cm i.d. and 1.0cm i.d. reactors. Under the higher S/V ratio, C₂HCl₃ decomposition was increased by an order of magnitude and product distributions suggested that radical-radical and radical-atom recombination rates were enhanced. Product yields under reduced S/V ratio indicated that yields of perchlorinated aromatic and perchlorinated PAH species were a factor of 10 larger than observed for higher S/V ratios. A detailed reaction mechanism is presented for the 1 cm i.d. reactor data describing molecular growth up to the formation of C₈Cl₆ (cy) and C₈Cl₈ (cy). Comparison of predicted versus experimental major and minor species profiles are presented, with generally good agreement. Important radical-molecule addition reactions leading to molecular growth are identified using sensitivity analysis and production rate calculations.