Supplementary material to "Isotopic characterization of nitrogen oxides (NOx), nitrous acid (HONO), and nitrate (NO3−(p)) from laboratory biomass burning during FIREX"

Abstract. New techniques have recently been developed and applied to capture reactive nitrogen species, including nitrogen oxides (NOx=NO+NO2), nitrous acid (HONO), nitric acid (HNO3), and particulate nitrate (pNO3-), for accurate measurement of their isotopic composition. Here, we report – for the first time – the isotopic composition of HONO from biomass burning (BB) emissions collected during the Fire Influence on Regional to Global Environments Experiment (FIREX, later evolved into FIREX-AQ) at the Missoula Fire Science Laboratory in the fall of 2016. We used our newly developed annular denuder system (ADS), which was verified to completely capture HONO associated with BB in comparison with four other high-time-resolution concentration measurement techniques, including mist chamber–ion chromatography (MC–IC), open-path Fourier transform infrared spectroscopy (OP-FTIR), cavity-enhanced spectroscopy (CES), and proton-transfer-reaction time-of-flight mass spectrometry (PTR-ToF). In 20 “stack” fires (direct emission within ∼5 s of production by the fire) that burned various biomass materials from the western US, δ15N–NOx ranges from −4.3 ‰ to +7.0 ‰, falling near the middle of the range reported in previous work. The first measurements of δ15N–HONO and δ18O–HONO in biomass burning smoke reveal a range of −5.3 ‰ to +5.8 ‰ and +5.2 ‰ to +15.2 ‰, respectively. Both HONO and NOx are sourced from N in the biomass fuel, and δ15N–HONO and δ15N–NOx are strongly correlated (R2=0.89, p<0.001), suggesting HONO is directly formed via subsequent chain reactions of NOx emitted from biomass combustion. Only 5 of 20 pNO3- samples had a sufficient amount for isotopic analysis and showed δ15N and δ18O of pNO3- ranging from −10.6 ‰ to −7.4 ‰ and +11.5 ‰ to +14.8 ‰, respectively. Our δ15N of NOx, HONO, and pNO3- ranges can serve as important biomass burning source signatures, useful for constraining emissions of these species in environmental applications. The δ18O of HONO and NO3- obtained here verify that our method is capable of determining the oxygen isotopic composition in BB plumes. The δ18O values for both of these species reflect laboratory conditions (i.e., a lack of photochemistry) and would be expected to track with the influence of different oxidation pathways in real environments. The methods used in this study will be further applied in future field studies to quantitatively track reactive nitrogen cycling in fresh and aged western US wildfire plumes.

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Isotopic characterization of nitrogen oxides (NOx), nitrous acid (HONO), and nitrate (NO3−(p)) from laboratory biomass burning during FIREX

10.5194/amt-2019-229 ◽

2019 ◽

Author(s):

Jiajue Chai ◽

David J. Miller ◽

Eric Scheuer ◽

Jack Dibb ◽

Vanessa Selimovic ◽

...

Keyword(s):

Nitrogen Oxides ◽

Isotopic Composition ◽

Biomass Burning ◽

Nitrous Acid ◽

Reactive Nitrogen Species ◽

Reactive Nitrogen ◽

Composition Analysis ◽

High Time Resolution ◽

Nitrogen Species ◽

Isotopic Characterization

Abstract. New techniques have recently been developed to capture reactive nitrogen species for accurate measurement of their isotopic composition. Reactive nitrogen species play important roles in atmospheric oxidation capacity (hydroxyl radical and ozone formation) and may have impacts on air quality and climate. Tracking reactive nitrogen species and their chemistry in the atmosphere based upon concentration alone is challenging. Isotopic analysis provides a potential tool for tracking the sources and chemistry of species such as nitrogen oxides (NOx = NO + NO2), nitrous acid (HONO), nitric acid (HNO3) and particulate nitrate (NO3−(p)). Here we study direct biomass burning (BB) emissions during the  Fire Influence on Regional to Global Environments Experiment (FIREX, later evolved into FIREX-AQ) laboratory experiments at the Missoula Fire Laboratory in the fall of 2016. An annular denuder system (ADS) developed to efficiently collect HONO for isotopic composition analysis was deployed to the Fire Lab study. Concentrations of HONO recovered from the ADS collection agree well with mean concentrations averaged over each fire measured by 4 other high time resolution techniques, including mist chamber/ion chromatography (MC/IC), open-path Fourier transform infrared spectroscopy (OP-FTIR), cavity enhanced spectroscopy (CES), proton-transfer-reaction time-of-flight mass spectrometer (PTR-ToF). The concentration validation ensures complete collection of BB emitted HONO, of which the isotopic composition is preserved during the collection process. In addition, the isotopic composition of NOx and NO3−(p) from direct BB emissions were also characterized. In 20 stack fires (direct emission within ~ 5 seconds of production by the fire) that burned various biomass materials, δ15N-NOx ranges from −4.3 ‰ to +7.0 ‰, falling near the middle of the range reported in previous work. The first measurements of δ15N-HONO and δ18O-HONO in biomass burning smoke reveal a range of −5.3 – +5.8 ‰ and +5.2 – +15.2 ‰ respectively. Both HONO and NOx are sourced from N in the biomass fuel and δ15N-HONO and δ15N-NOx are strongly correlated (R2 = 0.89, p

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