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<p>Reactive nitrogen (<span class="inline-formula">N_r</span>, defined as all nitrogen-containing compounds except for <span class="inline-formula">N₂</span> and <span class="inline-formula">N₂O</span>) is one of the most important classes of compounds emitted from wildfire, as <span class="inline-formula">N_r</span> impacts both atmospheric oxidation processes and particle formation chemistry. In addition, several <span class="inline-formula">N_r</span> compounds can contribute to health impacts from wildfires. Understanding the impacts of wildfire on the atmosphere requires a thorough description of <span class="inline-formula">N_r</span> emissions. Total reactive nitrogen was measured by catalytic conversion to NO and detection by NO–<span class="inline-formula">O₃</span> chemiluminescence together with individual <span class="inline-formula">N_r</span> species during a series of laboratory fires of fuels characteristic of western US wildfires, conducted as part of the FIREX Fire Lab 2016 study. Data from 75 stack fires were analyzed to examine the systematics of nitrogen emissions. The measured <span class="inline-formula">N_r</span>&thinsp;<span class="inline-formula">∕</span>&thinsp;total-carbon ratios averaged 0.37&thinsp;% for fuels characteristic of western North America, and these gas-phase emissions were compared with fuel and residue <span class="inline-formula">N∕C</span> ratios and mass to estimate that a mean (<span class="inline-formula">±SD</span>) of 0.68 (<span class="inline-formula">±0.14</span>) of fuel nitrogen was emitted as <span class="inline-formula">N₂</span> and <span class="inline-formula">N₂O</span>. The <span class="inline-formula">N_r</span> detected as speciated individual compounds included the following: nitric oxide (NO), nitrogen dioxide (<span class="inline-formula">NO₂</span>), nitrous acid (HONO), isocyanic acid (HNCO), hydrogen cyanide (HCN), ammonia (<span class="inline-formula">NH₃</span>), and 44 nitrogen-containing volatile organic compounds (NVOCs). The sum of these measured individual <span class="inline-formula">N_r</span> compounds averaged 84.8 (<span class="inline-formula">±9.8</span>)&thinsp;% relative to the total <span class="inline-formula">N_r</span>, and much of the 15.2&thinsp;% “unaccounted” <span class="inline-formula">N_r</span> is expected to be particle-bound species, not included in this analysis.</p> <p>A number of key species, e.g., HNCO, HCN, and HONO, were confirmed not to correlate with only flaming or with only smoldering combustion when using modified combustion efficiency, <span class="inline-formula"><math xmlns="http://www.w3.org/1998/Math/MathML" id="M23" display="inline" overflow="scroll" dspmath="mathml"><mrow><mtext>MCE</mtext><mo>=</mo><mrow class="chem"><msub><mi mathvariant="normal">CO</mi><mn mathvariant="normal">2</mn></msub></mrow><mo>/</mo><mo>(</mo><mrow class="chem"><mi mathvariant="normal">CO</mi></mrow><mo>+</mo><mrow class="chem"><msub><mi mathvariant="normal">CO</mi><mn mathvariant="normal">2</mn></msub></mrow><mo>)</mo></mrow></math><span><svg:svg xmlns:svg="http://www.w3.org/2000/svg" width="123pt" height="14pt" class="svg-formula" dspmath="mathimg" md5hash="e0107b770028f59df7be7c7897ae8dd9"><svg:image xmlns:xlink="http://www.w3.org/1999/xlink" xlink:href="acp-20-8807-2020-ie00001.svg" width="123pt" height="14pt" src="acp-20-8807-2020-ie00001.png"/></svg:svg></span></span>, as a rough indicator. However, the systematic variations in the abundance of these species relative to other nitrogen-containing species were successfully modeled using positive matrix factorization (PMF). Three distinct factors were found for the emissions from combined coniferous fuels: a combustion factor (Comb-N) (800–1200&thinsp;<span class="inline-formula">^∘C</span>) with emissions of the inorganic compounds NO, <span class="inline-formula">NO₂</span>, and HONO, and a minor contribution from organic nitro compounds (R-<span class="inline-formula">NO₂</span>); a high-temperature pyrolysis factor (HT-N) (500–800&thinsp;<span class="inline-formula">^∘C</span>) with emissions of HNCO, HCN, and nitriles; and a low-temperature pyrolysis factor (LT-N) (<span class="inline-formula">&lt;500</span>&thinsp;<span class="inline-formula">^∘C</span>) with mostly ammonia and NVOCs. The temperature ranges specified are based on known<span id="page8808"/> combustion and pyrolysis chemistry considerations. The mix of emissions in the PMF factors from chaparral fuels (manzanita and chamise) had a slightly different composition: the Comb-N factor was also mostly NO, with small amounts of HNCO, HONO, and <span class="inline-formula">NH₃</span>; the HT-N factor was dominated by <span class="inline-formula">NO₂</span> and had HONO, HCN, and HNCO; and the LT-N factor was mostly <span class="inline-formula">NH₃</span> with a slight amount of NO contributing. In both cases, the Comb-N factor correlated best with <span class="inline-formula">CO₂</span> emission, while the HT-N factors from coniferous fuels correlated closely with the high-temperature VOC factors recently reported by Sekimoto et al. (2018), and the LT-N had some correspondence to the LT-VOC factors. As a consequence, <span class="inline-formula">CO₂</span> is recommended as a marker for combustion <span class="inline-formula">N_r</span> emissions, HCN is recommended as a marker for HT-N emissions, and the family <span class="inline-formula">NH₃</span>&thinsp;<span class="inline-formula">∕</span>&thinsp;particle ammonium is recommended as a marker for LT-N emissions.</p>