Optical oxygen sensor instrumentation based on the detection of luminescence lifetime.

Optical oxygen sensors are mainly based on the principle of luminescence quenching. In contrast to arready 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 fibres. A new family of oxygen-sensitive dyes, the porphyrin-ketones, has been introduced, which exhibits favorable spectral properties and decay times in the order of tens and hundreds of microseconds. This allows the use of simple optoelectronic 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 prototype 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. The 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. The overall measurement accuracy of < +/- 1 hPa has been obtained for periods of 24 h of continuous measurement in a thermostatted environment. The sensor response times t90 are typically < 1 s for gases and 0.5 to 5 min for liquid samples.

[1]  D. Lübbers,et al.  FLOX—an oxygen-flux-measuring system using a phase-modulation method to evaluate the oxygen-dependent fluorescence lifetime , 1995 .

[2]  P. Hartmann,et al.  Effects of polymer matrices on calibration functions of luminescent oxygen sensors based on porphyrin ketone complexes. , 1996, Analytical chemistry.

[3]  Mauro Bacci,et al.  A new kind of oxygen-sensitive transducer based on an immobilized metallo-organic compound , 1993 .

[4]  Erich Gnaiger,et al.  Polarographic Oxygen Sensors , 1983, Springer Berlin Heidelberg.

[5]  Govind Rao,et al.  Phase fluorometric sterilizable optical oxygen sensor , 1994, Biotechnology and bioengineering.

[6]  I Klimant,et al.  Optical triple sensor for measuring pH, oxygen and carbon dioxide. , 1994, Journal of biotechnology.

[7]  F. Duschinsky Eine allgemeine Theorie der zur Messung sehr kurzer Leuchtdauern dienenden Versuchsanordnungen (Fluorometer) , 1933 .

[8]  P. B. Arnoudse,et al.  Instrumentation for the breath-by-breath determination of oxygen and carbon dioxide based on nondispersive absorption measurements. , 1992, Analytical chemistry.

[9]  G. K. Rollefson,et al.  The Determination of the Fluorescence Lifetimes of Dissolved Substances by a Phase Shift Method , 1953 .

[10]  Max E. Lippitsch,et al.  Fibre-optic oxygen sensor with the fluorescence decay time as the information carrier , 1988 .

[11]  Ingo Klimant,et al.  Recent progress in optical oxygen sensor instrumentation , 1995 .

[12]  A. Schmillen Abklingzeitmessungen an flüssigen und festen Lösungen mit einem neuen Fluorometer , 1953 .

[13]  Otto S. Wolfbeis,et al.  Detection of fluorescence lifetime based on solid state technology and its application to optical oxygen sensing , 1995, Photonics West.

[14]  Dmitri B. Papkovsky,et al.  New oxygen sensors and their application to biosensing , 1995 .

[15]  Gelii V. Ponomarev,et al.  Phosphorescent Complexes of Porphyrin Ketones: Optical Properties and Application to Oxygen Sensing , 1995 .