Photolysis system for fast-response no2 measurements and method therefor

Abstract

An efficient, lightweight, and relatively inexpensive photolysis system based on a short-arc Hg arc lamp provides a simple and accurate method for measurement of ambient NO . High time resolution is achieved by minimizing inlet and photolysis cell residence times and matching NO and NO sample paths, and data reduction is greatly simplified relative to conventional photolysis designs. The single-channel embodiment includes (a) a UV light source for emitting light capable of photolytically dissociating NO in the gas sample to NO; (b) a device for positioning the light source; (c) an ellipsoidal reflector for collecting and focusing the light from the light source; (d) an enclosure for enclosing the light source and the ellipsoidal reflector; (e) an optical filter assembly for receiving, filtering, and transmitting the focused light; (f) a shutter capable of blocking the transmission of the filtered light which is transmitted through the optical filter assembly; (g) a sample photolysis cell for containing a volume of the gas sample; (h) a device for controllably introducing the gas sample to the sample photolysis cell, and a device for controllably delivering the gas sample from the sample photolysis cell; (i) a detector capable of detecting an amount of the NO present in the gas sample delivered from the sample photolysis cell, and capable of emitting a signal representative of the amount of NO; and (j) a device for measuring the signal so as to quantify the amount of NO. The system is characterized by i) higher conversion efficiency at faster time response; ii) lower power consumption; iii) less heat output with consequently less sample heating; iv) optically filtered light output for NO -specific conversion, and v) simplified data reduction. The system can be used for measurement of gas-phase NO at concentrations ranging from parts per trillion to parts per million or higher. Present applications of the system include ambient atmospheric air measurements, while future medical applications might include the non-invasive monitoring of human breath for NO .