Nitrogen oxides and ozone in urban air: A review of 50 plus years of progress

Erickson, Larry E.; Newmark, Gregory L.; Higgins, Michael; Wang, Zixian

doi:10.1002/ep.13484

Cited by 28 publications

(8 citation statements)

References 52 publications

(262 reference statements)

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“…However, the trend of tropospheric NO 2 column densities (columns) observed by satellites and nationwide NO 2 concentrations predicted by an ensemble of models are both inconsistent with the sustained decrease in NO x emissions reported by the NEI, which stopped decreasing after the year of 2009. , Silvern et al separated OMI observations into winter and summer as well as urban and rural and found that OMI NO 2 in rural summer during the 2005–2017 period had no significant reduction trend. Furthermore, an increase in daily nonpeak O 3 concentration was observed in many parts of the U.S. − Recent studies suggest that this enhancement of O 3 can be mainly attributed to the temperature-driven increase in NO x emission, mostly from soils. , Consequently, soils may be an important source of NO x that has been overlooked in previous studies and regulatory frameworks but has a potentially increased impact on tropospheric NO x budget and O 3 pollution.…”

Section: Introductionmentioning

confidence: 99%

Impacts of Soil NO_x Emission on O₃ Air Quality in Rural California

Sha

Zhang

et al. 2021

Environ. Sci. Technol.

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Nitrogen oxides (NO x ) are a key precursor in O3 formation. Although stringent anthropogenic NO x emission controls have been implemented since the early 2000s in the United States, several rural regions of California still suffer from O3 pollution. Previous findings suggest that soils are a dominant source of NO x emissions in California; however, a statewide assessment of the impacts of soil NO x emission (SNO x ) on air quality is still lacking. Here we quantified the contribution of SNO x to the NO x budget and the effects of SNO x on surface O3 in California during summer by using WRF-Chem with an updated SNO x scheme, the Berkeley Dalhousie Iowa Soil NO Parameterization (BDISNP). The model with BDISNP shows a better agreement with TROPOMI NO2 columns, giving confidence in the SNO x estimates. We estimate that 40.1% of the state’s total NO x emissions in July 2018 are from soils, and SNO x could exceed anthropogenic sources over croplands, which accounts for 50.7% of NO x emissions. Such considerable amounts of SNO x enhance the monthly mean NO2 columns by 34.7% (53.3%) and surface NO2 concentrations by 176.5% (114.0%), leading to an additional 23.0% (23.2%) of surface O3 concentration in California (cropland). Our results highlight the cobenefits of limiting SNO x to help improve air quality and human health in rural California.

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Section: Introductionmentioning

confidence: 99%

Impacts of Soil NO_x Emission on O₃ Air Quality in Rural California

Sha

Zhang

et al. 2021

Environ. Sci. Technol.

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“…It has been previously reported that 90% of sulfur dioxide (SO 2 ) and 67% of nitrogen oxides (NO x ) in China are emitted by coal combustion, and on-road mobile sources contribute to emissions of NO x [30][31][32][33]. The presence of NO x in the air is important for the formation of O 3 , and O 3 concentrations in China have increased since 2013 [34]. Changes in urbanization and economic levels have a non-negligible impact on air pollution [35].…”

Section: Introductionmentioning

confidence: 99%

Analysis on the Characteristics of Air Pollution in China during the COVID-19 Outbreak

Chen

Huang

et al. 2021

Atmosphere

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The COVID-19 pandemic poses a serious global threat to human health. In China, the government immediately implemented lockdown measures to curb the spread of this virus. These measures severely affected transportation and industrial production across the country, resulting in a significant change in the concentration of air pollutants. In this study, the Euclidean distance method was used to select the most similar meteorological field during the COVID-19 lockdown period. Changes in the concentration of air pollutants in China were analyzed under similar meteorological background conditions. Results indicate that, compared with data from 2015–2019, air quality in China significantly improved; with the exception of ozone (O3), the concentration of major air pollutants declined. Compared with baseline conditions, the reduction of air pollutants in China from 25 January to 22 February 2020 (Period 2) was the most significant. In particular, NO2 decreased by 41.7% in the Yangtze River Delta. In Period 2, the reduction of air pollutants in areas other than Hubei gradually decreased, but the reduction of NO2 in Wuhan reached 61.92%, and the reduction of air pollutants in various regions after February 23 was significantly reduced. By excluding the influence of meteorological factors and calculating the contribution of human activities to atmospheric pollutants by linear fitting, in Period 2 the effect of artificial controls on NO2 in Wuhan attained 30.66%, and reached 48.17% from 23 February to 23 March (Period 3). Results from this investigation provides effective theoretical support for pollution prevention and control in China.

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“…Due to its complex chemistry, the control of O 3 levels is challenging, and O 3 can remain at elevated concentrations even if the emissions of some O 3 precursors are highly decreased (Sicard et al 2020;Querol et al 2021;Sicard 2021). Being also affected by transboundary long-range transport (Gao et al 2020;Erickson et al 2020), which downplays national efforts to decrease O 3 concentrations, O 3 levels may remain elevated for several decades to come (Sicard et al 2017). Such elevated O 3 levels can lead to inhibited photosynthesis and suppressed woody biomass production and yields (Paoletti 2006;Karnosky et al 2007a;Koike et al 2013;Jolivet et al 2016;Li et al 2017;Cotrozzi 2021), suggesting increased risks to tree productivity (Sicard et al 2017;Feng et al 2019a;Proietti et al 2021;Sacchelli et al 2021).…”

Section: Introductionmentioning

confidence: 99%

Ethylenediurea (EDU) spray effects on willows (Salix sachalinensis F. Schmid) grown in ambient or ozone-enriched air: implications for renewable biomass production

et al. 2021

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Ground-level ozone (O3) is a widespread air pollutant causing extensive injuries in plants. However, its effects on perennial energy crops remain poorly understood due to technical difficulties in cultivating fast-growing shrubs for biomass production under O3 treatment on the field. Here we present the results of a two-year evaluation in the framework of which willow (Salix sachalinensis F. Schmid) shrubs were exposed to ambient (AOZ) or elevated (EOZ) O3 in two successive growing seasons (2014, 2015) and treated with 0 (EDU0) or 400 mg L−1 (EDU400) ethylenediurea spray in the second growing season. In 2014, EOZ altered the chemical composition of both top young and fallen leaves, and a novel mechanism of decreasing Mg in fallen leaves while highly enriching it in young top leaves was revealed in shrubs exposed to EOZ. In 2015, EDU400 alleviated EOZ-induced decreases in leaf fresh mass to dry mass ratio (FM/DM) and leaf mass per area (LMA). While EDU400 protected against EOZ-induced suppression of the maximum rate at which leaves can fix carbon (Amax) in O3-asymptomatic leaves, it did not alleviate EOZ-induced suppression of the maximum rates of carboxylation (VCmax) and electron transport (Jmax) and chlorophylls a, b, and a + b in the same type of leaves. In O3-symptomatic leaves, however, EDU400 alleviated EOZ-induced suppression of chlorophylls a and a + b, indicating different mode of action of EDU between O3-asymptomatic and O3-symptomatic leaves. Extensive herbivory occurred only in AOZ-exposed plants, leading to suppressed biomass production, while EOZ also led to a similar suppression of biomass production (EDU0 × EOZ vs. EDU400 × EOZ). In 2016, carry-over effects were also evaluated following cropping and transplantation into new ambient plots. Effects of EOZ in the preceding growing seasons extended to the third growing season in the form of suppressed ratoon biomass production, indicating carry-over effect of EOZ. Although EDU400 protected against EOZ-induced suppression of biomass production when applied in 2015, there was no carry-over effect of EDU in the absence of EDU treatment in 2016. The results of this study provide novel mechanistic understandings of O3 and EDU modes of action and can enlighten cultivation of willow as energy crop.

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Nitrogen oxides and ozone in urban air: A review of 50 plus years of progress

Cited by 28 publications

References 52 publications

Impacts of Soil NO_x Emission on O₃ Air Quality in Rural California

Impacts of Soil NO_x Emission on O₃ Air Quality in Rural California

Analysis on the Characteristics of Air Pollution in China during the COVID-19 Outbreak

Ethylenediurea (EDU) spray effects on willows (Salix sachalinensis F. Schmid) grown in ambient or ozone-enriched air: implications for renewable biomass production

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Nitrogen oxides and ozone in urban air: A review of 50 plus years of progress

Cited by 28 publications

References 52 publications

Impacts of Soil NOx Emission on O3 Air Quality in Rural California

Impacts of Soil NOx Emission on O3 Air Quality in Rural California

Analysis on the Characteristics of Air Pollution in China during the COVID-19 Outbreak

Ethylenediurea (EDU) spray effects on willows (Salix sachalinensis F. Schmid) grown in ambient or ozone-enriched air: implications for renewable biomass production

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Impacts of Soil NO_x Emission on O₃ Air Quality in Rural California

Impacts of Soil NO_x Emission on O₃ Air Quality in Rural California