In the present work, surface thermometry using a method based on the spectroscopy of inorganic luminescent

material was applied in the afterburner of a full-size aircraft jet engine. The technique uses laser-induced emission

from thermographic phosphors for nonintrusive remote temperature diagnostics in combustion applications with

high sensitivity and accuracy. A phosphor material having suitable temperature sensitivity in the expected

temperature range was applied to the surface of interest in the engine afterburner. Phosphorescence radiation was

generated using the forth harmonic (266 nm) from a pulsed Nd:YAG laser. The resulting signal was detected with a

photomultiplier tube and phosphorescence lifetime decay curves were recorded for various engine loads, including

operation of the afterburner. By analyzing the phosphorescence decay, temperature data were acquired through

implementation of a regression equation extracted from well-defined calibration measurements on the phosphor

used. Quantitative temperature data recorded with a repetition rate of 10 Hz are presented. The laser-induced

phosphorescence technique for surface thermometry has proven its applicability in the extremely harsh environment

prevailing inside and next to a jet engine operating at full load.