Interferences in photolytic NO<sub>2</sub> measurements: explanation for an apparent missing oxidant?

Abstract: Abstract. Measurement of NO 2 at low concentrations (tens of ppts) is non-trivial. A variety of techniques exist, with the conversion of NO 2 into NO followed by chemiluminescent detection of NO being prevalent. Historically this conversion has used a catalytic approach (molybdenum); however, this has been plagued with interferences. More recently, photolytic conversion based on UV-LED irradiation of a reaction cell has been used. Although this appears to be robust there have been a range of observations in lo… Show more

“…As a result, thermal decomposition of reservoir species containing NO 2 can lead to erroneously enhanced NO 2 measurements. Reed et al (2016) showed that the PAN interference could be up to 8 and 25 % when using an actively cooled and a not actively cooled photolytic converter, respectively. In the laboratory, we found NO 2 enhancements of 30 % by mixing PAN with the sample flow (at 35 • C instrument temperature and pressure level of 250 hPa), which was quantitatively generated from a NO calibration gas by photolysis of acetone (100 ppbv) in a flow system (Pätz et al, 2002;Volz-Thomas et al, 2002).…”

“…However, previous studies identify an unexplained imbalance between the measured and calculated NO 2 in low-NO x regions, which was explained by interferences of NO 2 -containing species and the large uncertainty of the calculations (e.g., Crawford et al, 1996;Reed et al, 2016). Thus, the impact of interference from NO 2 -containing species on the IAGOS measurements requires further investigations, which will be performed once a larger data set is available.…”

“…CLD instruments have often been coupled to a photolytic or catalytic converter to measure NO 2 and NO x by using a xenon lamp, blue-light converter or catalytic conversion of NO 2 into NO, prior to the CLD unit Ryerson et al, 2000;Nakamura et al, 2003;Pollack et al, 2010;Villena et al, 2012;Reed et al, 2016). NO 2 measurements at low-NO x conditions (below 0.1 ppbv) are close to the limit of detection (Yang et al, 2004), and depending on the installed converter each instrument might show interferences with other nitrogen-oxide-containing species (e.g., Reed et al, 2016).…”

The IAGOS NO<sub><i>x</i></sub> instrument – design, operation and first results from deployment aboard passenger aircraft

“…As a result, thermal decomposition of reservoir species containing NO 2 can lead to erroneously enhanced NO 2 measurements. Reed et al (2016) showed that the PAN interference could be up to 8 and 25 % when using an actively cooled and a not actively cooled photolytic converter, respectively. In the laboratory, we found NO 2 enhancements of 30 % by mixing PAN with the sample flow (at 35 • C instrument temperature and pressure level of 250 hPa), which was quantitatively generated from a NO calibration gas by photolysis of acetone (100 ppbv) in a flow system (Pätz et al, 2002;Volz-Thomas et al, 2002).…”

“…However, previous studies identify an unexplained imbalance between the measured and calculated NO 2 in low-NO x regions, which was explained by interferences of NO 2 -containing species and the large uncertainty of the calculations (e.g., Crawford et al, 1996;Reed et al, 2016). Thus, the impact of interference from NO 2 -containing species on the IAGOS measurements requires further investigations, which will be performed once a larger data set is available.…”

“…CLD instruments have often been coupled to a photolytic or catalytic converter to measure NO 2 and NO x by using a xenon lamp, blue-light converter or catalytic conversion of NO 2 into NO, prior to the CLD unit Ryerson et al, 2000;Nakamura et al, 2003;Pollack et al, 2010;Villena et al, 2012;Reed et al, 2016). NO 2 measurements at low-NO x conditions (below 0.1 ppbv) are close to the limit of detection (Yang et al, 2004), and depending on the installed converter each instrument might show interferences with other nitrogen-oxide-containing species (e.g., Reed et al, 2016).…”

The IAGOS NO<sub><i>x</i></sub> instrument – design, operation and first results from deployment aboard passenger aircraft

“…Therefore the knowledge of the spatial distribution of NO x is important to identify the sources, sinks and its partitioning between NO and NO 2 in the atmosphere (Monks et al, 2009). 10 Most relevant natural sources of NO x are lightning (LNO x ), biomass burning, soil emissions, and anthropogenic sources, such as power generation, road transportation and aviation. The current knowledge of the global distribution of NO x and its emission estimates is based mostly on specific aircraft missions (Emmons et al, 1997;Rohrer et al, 1997;Schumann and Huntrieser, 2007;Ziereis et al, 2000;Gressent et al, 2016), on surface 15 monitoring stations (Aerosols, Clouds and Trace gases Research Infrastructure (ACTRIS); www.actris.eu), satellite measurements (Fishman et al, 2008;de Laat et al, 2014;Duncan et al, 2015) and model simulations (Ehhalt et al, 1992;Emmons et al, 1997).…”

The IAGOS NO<sub>x</sub> Instrument – Design, Operation and First Results from Deployment aboard Passenger Aircraft

“…However, in the case of NO 2 to NO conversion, a potential interference from NO z species cannot be fully excluded for the NO 2 measurement, e.g. (Villena et al, 2012;Reed et al, 2016). Therefore, a direct detection of NO 2 is advantageous.…”

Laser induced fluorescence based detection of atmospheric nitrogen dioxide and comparison of different techniques during the PARADE 2011 field campaign