Isotopic advances in understanding reactive nitrogen deposition and atmospheric processing

Elliott, Emily M.; Yu, Zhongjie; Cole, Amanda; Coughlin, Justin G.

doi:10.1016/j.scitotenv.2018.12.177

Cited by 135 publications

(82 citation statements)

References 106 publications

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“…The δ 15 N values of the initial NH 3 (denoted as δ 15 N-NH x ) were calculated using an isotope mass-balance model ( eq 1 ), 23 the measured δ 15 N-NH 3 , and the δ 15 N difference between gaseous NH 3 and particulate NH 4 + ( eq 2 ), 24 as follows: where ε (NH 4 + -NH 3 ) is the theoretical N isotopic fractionation factor between the gas and particle and equals 12.522 × 1000/ T – 11.31, 25 where T is the temperature in kelvin. f is the fraction of the initial gaseous NH 3 converted to particulate NH 4 + (NH 4 + /NH x in molar concentrations).…”

Section: Methodsmentioning

confidence: 99%

Atmospheric Ammonia in Beijing during the COVID-19 Outbreak: Concentrations, Sources, and Implications

Zhang

Liu

Fang

et al. 2020

Environ. Sci. Technol. Lett.

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This study investigates the concentrations and δ 15 N values of NH 3 in Beijing during and after the 2020 COVID-19 lockdown. Higher NH 3 concentrations and lower δ 15 N-NH 3(measured) were observed at most sites in 2020 compared to 2017. Except for a site inside a tunnel, NH 3 concentrations did not increase significantly after the lockdown had ended compared to those during the lockdown, while δ 15 N-NH 3(measured) increased by 2.1–9.9‰. Nonagricultural sources (fossil fuel and urban waste) overall contributed 81% and 62% of NH 3 at on-road (tunnel interior) and nonroad (CAU) sites in 2020, respectively, comparable to those in 2017 (without significant difference). The contribution of nonagricultural sources slightly increased after the lockdown compared to the contribution during the lockdown at the nonroad site and hardly changed at the tunnel interior site. Our results suggest that (1) unfavorable meteorological conditions, especially lower boundary layer heights and changes in regional transport patterns, might play a more important role than reduced anthropogenic emissions in the temporal variations of Beijing NH 3 and (2) the effect of reduced anthropogenic emissions, during the COVID-19 outbreak or with the future implementation of emission control strategies, on atmospheric NH 3 can be better demonstrated by isotope-based source apportionment of NH 3 , rather than only by changes in NH 3 concentrations.

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Section: Methodsmentioning

confidence: 99%

Atmospheric Ammonia in Beijing during the COVID-19 Outbreak: Concentrations, Sources, and Implications

Zhang

Liu

Fang

et al. 2020

Environ. Sci. Technol. Lett.

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“…However, only a few studies have measured nitrogen isotopes in gases and particles collected simultaneously over extended periods and have examined isotopic fractionation during gas-particle reactions (Moore, 1977;Freyer, 1991). The review by Elliott et al (2019) described that medium-, and long-term data need for future research. In this study, stable nitrogen isotope ratios (d 15 N) of gaseous NH 3 , NO 2 , and HNO 3 (d 15 N-NH 3 , d 15 N-NO 2 , and d 15 N-HNO 3 , respectively) and of NO 3 À and NH 4 þ ions (d 15 N-NO 3 À and d 15 N-NH 4 þ , respectively) in SPM were measured for long term sampling, and the analysis results were used to examine isotope fractionation during gas-to-aerosol reactions and the sources and behavior of these compounds in the atmosphere.…”

Section: Recent Technical Advances Have Made It Possible Tomentioning

confidence: 99%

Seasonal trends of the stable nitrogen isotope ratio in particulate nitrogen compounds and their gaseous precursors in Akita, Japan

Kawashima

2019

Tellus B: Chemical and Physical Meteorology

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Particulate matter (PM) can have adverse effects on human health. Moreover, because the mechanisms of PM formation and behavior in the atmosphere are notably complicated, to reduce PM concentrations effectively and meet environmental standards, source-receptor relationships must be clearly understood. Stable isotope ratios can be used to detect chemical processes and distinguish sources. In environmental science, especially in research on aerosols, stable isotope ratios have proven to constitute a powerful tool for source identification. However, there are few long-term studies of isotope fractionation during secondary aerosol formation. In this study, stable nitrogen isotope ratios (d 15 N) of ammonia gas (NH 3), nitrogen dioxide gas (NO 2), nitric acid vapor (HNO 3), particulate nitrate (NO 3 À), and ammonium (NH 4 þ) in suspended PM (SPM) were analyzed to investigate seasonal trends and isotope fractionation during aerosol formation for long term sampling in Akita, Japan. The results indicated that d 15 N-NH 4 þ in SPM and d 15 N-NH 3 gas ranged from 1.3& to 38.5& (mean 16.1&) and from À33.6& to À0.0& (À16.9&), respectively. Furthermore, d 15 N-NO 3 À (SPM) and d 15 N-NO 2 and d 15 N-HNO 3 (gaseous) ranged from À4.6& to 4.8& (mean À0.5&), from À8.2& to À3.1& (À5.4&), and from À7.5& to 2.7& (À5.0&), respectively. The mean annual isotope fractionation factors for transformations from gaseous NH 3 to NH 4 þ in SPM, from gaseous NO 2 to gaseous HNO 3 , and from HNO 3 gas to NO 3 in SPM in the atmospheric environment were þ33.3&, þ0.5&, and þ4.9&, respectively. Isotope fractionation of NH 4 þ in SPM was much higher than that of NO 3 in SPM. As the chemical reaction from gaseous precursors progressed, d 15 N-NO 3 in SPM became steadily heavier.

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“…Generally, atmospheric NO 3 − is mainly derived from the conversion of NO x , of which δ 15 N of different anthropogenic and natural sources usually varies over a large range (Elliott et al 2019). For example, NO x from coal combustion owns a higher δ 15 N value, while δ 15 N from microbial processes is more negative (Hastings, Sigman, and Lipschultz 2003).…”

Section: Nitrogen and Oxygen Isotope Characteristics Impacted By Thementioning

confidence: 99%

Impact of an accidental explosion in Tianjin Port on enhanced atmospheric nitrogen deposition over the Bohai Sea inferred from aerosol nitrate dual isotopes

Zong

Sun

Tan

et al. 2019

Atmospheric and Oceanic Science Letters

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In recent years, emergent pollutant's accidents have occurred frequently in China, causing serious harm to the ecological environment. In this study, the impact of an accidental fire and explosion at Tianjin Port in 2015 on the atmosphere over the Bohai Sea was explored. Results showed sharp increases in the concentrations of several important components of fine particulate matter (e.g. NO 3 − , SO 4 2− , NH 4 + , organic carbon, elemental carbon) over Beihuangcheng Island after the explosion. Among them, NO 3 − was most affected (about 10 days), with a maximum concentration of 16.45 μg m −3. The δ 15 N-NO 3 − ranged from −1.58‰ to +8.74‰, with an average of +2.79‰ ± 3.32‰. Influenced by the explosion, δ 15 N-NO 3 − decreased significantly, which was in accordance with the industrial processes of explosives. The δ 18 O-NO 3 − varied between +49.40‰ and +69.52‰, and showed a marked increase (+66.62‰ ± 3.92‰) in the explosion-affected period. Using Monte Carlo simulation, the •OH pathway for NO 3 − formation was 51.79% ± 10.94% at that timemuch lower than in the regular period. The elevated dry deposition of NO 3 − caused by the explosion was 266.08 μmol N m −2 d −1 over the Bohai Seaagain, much higher than in the regular period. With the dry nitrogen deposition of NH 4 + (42.41 μmol N m −2 d −1), the total nitrogen deposition increased by 308.49 μmol N m −2 d −1 , leading to severe ecological risk. Through the inverse computation of the dry deposition flux of NO 3 − , the affected area over the Bohai Sea was less than 1.42 × 10 4 km 2 , which is about 20% of the total area. 利用气溶胶硝酸盐双同位素评估天津港爆炸事故对渤海地区大气氮沉降的影响摘要近年来，我国突发性污染事故频繁发生，对生态环境造成了严重危害。本研究基于气溶胶硝酸盐的氮氧同位素确认并评估了2015年天津港火灾爆炸事故对渤海地区大气氮沉降的影响研究结果表明δ 15 N-NO 3 − 与δ 18 O-NO 3 − 范围分别为−1.58‰至+8.74‰与+49.40‰ 至+69.52‰ 受到火灾爆炸影响，δ 15 N-NO 3 − 显著下降，而δ 18 O-NO 3 − 明显上升。火灾爆炸导致渤海地区大气氮沉降量增加308.49 μmol N m −2 d −1 ，其中硝态氮为266.08 μmol N m −2 d −1 ，总影响区域约为渤海面积的1/5。本研究显示同位素技术是污染事故研究中重要的示踪手段。 ARTICLE HISTORY

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Isotopic advances in understanding reactive nitrogen deposition and atmospheric processing

Cited by 135 publications

References 106 publications

Atmospheric Ammonia in Beijing during the COVID-19 Outbreak: Concentrations, Sources, and Implications

Atmospheric Ammonia in Beijing during the COVID-19 Outbreak: Concentrations, Sources, and Implications

Seasonal trends of the stable nitrogen isotope ratio in particulate nitrogen compounds and their gaseous precursors in Akita, Japan

Impact of an accidental explosion in Tianjin Port on enhanced atmospheric nitrogen deposition over the Bohai Sea inferred from aerosol nitrate dual isotopes

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