Spatially resolved measurement of OH*, CH*, and C2* chemiluminescence in the reaction zone of laminar methane/air premixed flames

“…The sequence of the location of the calculated maximum intensities for the OH* and CH* excited radicals, is OH* followed by CH*, as one scans the flame from the reactants to the products. The calculated distance between them agrees well with the experimental results found in the literature [2,24,58].…”

“…The experimental uncertainty for the measurements presented in this work was less than ± 5%. Whenever natural gas was used as the fuel instead of pure methane, its composition was: 93.5% CH 4 , 3.5% C 2 H 6 , 0.7% C 3 H 8 , 0.22% C 4 H 10 , 0.065% C 5+ , 1.5% N 2 & 0.5% CO 2 . More details concerning the experiment can be found in [7,26].…”

“…It has been used for identification of the reaction zone [2], to compute Rayleigh index maps [3], as a marker of heat release rate [4][5][6], and to measure flame equivalence ratios [7][8][9][10][11][12]. By use of a Cassegrain optics-based Chemiluminescence Sensor (CS), similar to that used by Akamatsu et al [13] & Kojima et al [2], Hardalupas and Orain [7] demonstrated in their chemiluminescence study that the intensity ratio of the two excited radicals OH* and CH* is independent of strain rate in premixed counterflow flames at atmospheric pressure, in contrast to that of OH* and C 2 *, which is a function of strain rate.…”

Numerical evaluation of equivalence ratio measurement using OH∗ and CH∗ chemiluminescence in premixed and non-premixed methane–air flames

“…The sequence of the location of the calculated maximum intensities for the OH* and CH* excited radicals, is OH* followed by CH*, as one scans the flame from the reactants to the products. The calculated distance between them agrees well with the experimental results found in the literature [2,24,58].…”

“…The experimental uncertainty for the measurements presented in this work was less than ± 5%. Whenever natural gas was used as the fuel instead of pure methane, its composition was: 93.5% CH 4 , 3.5% C 2 H 6 , 0.7% C 3 H 8 , 0.22% C 4 H 10 , 0.065% C 5+ , 1.5% N 2 & 0.5% CO 2 . More details concerning the experiment can be found in [7,26].…”

“…It has been used for identification of the reaction zone [2], to compute Rayleigh index maps [3], as a marker of heat release rate [4][5][6], and to measure flame equivalence ratios [7][8][9][10][11][12]. By use of a Cassegrain optics-based Chemiluminescence Sensor (CS), similar to that used by Akamatsu et al [13] & Kojima et al [2], Hardalupas and Orain [7] demonstrated in their chemiluminescence study that the intensity ratio of the two excited radicals OH* and CH* is independent of strain rate in premixed counterflow flames at atmospheric pressure, in contrast to that of OH* and C 2 *, which is a function of strain rate.…”

Numerical evaluation of equivalence ratio measurement using OH∗ and CH∗ chemiluminescence in premixed and non-premixed methane–air flames

“…The equivalence ratio (in premixed laminar flames) is often estimated by means of the intensity ratio between OH* and CH* chemiluminescence. The CH*/OH* chemiluminescence ratio is found to proportionally increase with equivalence ratio at atmospheric pressures [18,19].…”

The influence of charge stratification on the spectral signature of partially premixed combustion in a light-duty optical engine

“…In the visible spectrum excited molecular radicals CH* (430 nm) and C2* (Swan system, dominant emissive band head at 473.71 nm and 516.52 nm) produce 'blue' light [9], the intensity of which has been demonstrated to vary with fuel composition, flow rate, and heat release rate [10][11][12]. The ratio of CH*/C2* can be used to determine the local equivalence ratio [13].…”

Investigation of ignition process from visible to infrared by a high speed colour camera