Burst-mode spontaneous raman thermometry in a flat flame

A high-speed Raman thermometry diagnostic was evaluated in lean H2-air flames at a data acquisition rate of 5 kHz. Bursts of nanosecond pulses were generated at a 10 kHz burst rate with energy of E ≈ 13 J/burst at λ = 532 nm. The pulses had a duration of ≈ 200 ns and were used to interrogate a stabilized flat flame burner. Spectra were collected using an electron multiplying charge-coupled device (EMCCD) detector. Raman spectra were integrated over the full burst to map adiabatic flame temperature versus equivalence ratio. The measured spectra resolved vibrational band features to infer temperature. A detailed spectral fitting model was used in the burst-integrated and burst-mode spectra. Two pulses were used for each burst-mode measurement resulting in a 5 kHz rate up to flame temperatures of ≈ 2100 K. The measurement precision in burst mode was 23 K and 62 K at flame temperatures of 1160 K and 2080 K, respectively. The measurement accuracy was benchmarked against the spectrally fitted full-burst spectra, chemical equilibrium calculations and previous coherent anti-Stokes Raman scattering (CARS) measurements. In summary, the measurement precision and accuracy were within 3% of the measured and adiabatic equilibrium temperatures, respectively.