Flame speed of a low pressure CS2O2 flame

A one-dimensional thermal theory is applied to a low-pressure, laminar, premixed, CS2/O 2 flame. The spatial distribution of the species concentrations and rate of production of carbon monoxide are calculated. The flame speed is calculated as a function of the initial O2/CS 2 ratio at a pressure of

New spectroscopic and vibroruc population data support the essentiai correctness of BaOz as the nascent poIyatomlc emitter and as the precursor to BaO (A 'x+-c X 1 23 and (A' 'II -c X'Z') visible chenukmnescence from metal-rich Ba&) \* 02 (+ Ar) dlffunon flames at Z-350 mTorr\_ Absolute vuible photo

The use of a ribbon burner resulted in 3 100 fold laser power enhancement from a CT'&-02 free burning '&me. ?Z'he $eect of He, SFB, X20, CO, COz, N,, SO?, and NO2 on laser power was examined. The hi&e% power. 0.6 W, was achieved from 3 mixture of CS1, 02, and I&O at flow rates of 3.9;7 10, tid 7.6 m

Quenching of electronically excited CH and NO radicals in methane/air flames between 30 and 70 Tot-r has been studied using the time decay of laser-induced fluorescence. Rates of 0.3 and 1 lo' Torr-' were determined for A2A CH and A\*E+ NO respectively at a temperature near 1700 K. These are compare