Miniaturized luminescence lifetime-based oxygen sensor instrumentation utilizing a phase modulation technique

Optical oxygen sensors are mainly based on the principle of luminescence quenching. In contrast to already existing intensity-based systems, the measurement of the luminescence lifetime provides certain advantages, such as insensitivity to photobleaching or leaching of the dye or changes in the intensity of excitation light. This facilitates the use of simple optical systems or optical fibers. Phase measurement techniques have shown to be a powerful tool for indirect measurement of luminescence lifetimes. Here, dyes with luminescence decay times in the order of tens or hundreds of microseconds allow the use of simple opto-electronic circuitry and low-cost processing electronics. An optical oxygen sensor module has been developed with the dimensions of only 120 X 60 X 30 mm. The instrument is based on the measurement of the decay time of the luminophore by measuring the phase shift between the square-wave excitation and the detected square-wave of the emission coming from the sensor. The instrument is based on semiconductor devices (light-emitting diodes, photodiodes) and may be used for the detection of oxygen in gaseous or liquid samples. Platinum(II) octaethylporphyrin-ketone, which is incorporated in an oxygen-permeable polymer and which has an unquenched lifetime of approximately 60 μs, is used as the oxygen-sensitive dye. The typical measurement range of the device is from 0 to 200 hPa oxygen partial pressure with a resolution of <1 hPa over the whole measurement range. Measurement accuracy of <±1 hPa has been obtained for periods of 24 h of continuous measurement. The sensor response times t90 are typically <1 s for gases and 1-5 min for liquid samples.