Global   Impact   of   COVID-19   Restrictions   on   the Surface Concentrations of Nitrogen Dioxide and Ozone

Keller, Christoph A.; Evans, M. J.; Knowland, K. Emma; Hasenkopf, C. A.; Modekurty, Sruti; Lucchesi, Robert A.; Oda, Tatsuya; França, Bruno Wanderley; Mandarino, Felipe; Suárez, M. Valeria Díaz; Ryan, Robert G.; Fakes, Luke H.; Pawson, Steven

doi:10.5194/acp-2020-685

“…At the same time, some other important pollutants such as N 100-1000 or SO 2 -which are typically related to larger spatial extent or region and which could, therefore, be influenced by meteorology -did not change significantly. Similar reductions were reported for other urban locations in the world (Keller et al, 2020;Lal et al, 2020;Le et al, 2020;Lee et al, 2020;Tobías et al, 2020). This all can be interpreted that the alterations in NO, NO 2 , CO, N 6-1000 and N 6-100 concentrations were primarily caused by the lower vehicular traffic intensity in the city and that the PBLH could also contribute by approximately 9 % in an absolute sense ( Table 1).…”

Section: Quantification Of Concentration Changessupporting

confidence: 83%

“…As a consequence of the implemented measures, road traffic in many cities worldwide was reduced in a substantial manner and for a considerable time interval. In parallel, lower concentrations of several air pollutants were reported from both satellite observations and in situ measurements (Conticini et al, 2020;Frontera et al, 2020;Keller et al, 2020;Lal et al, 2020;Le et al, 2020;Lee et al, 2020;Liu et al, 2020;Mahato et al, 2020;Morawska and Cao, 2020;Nakada and Urban, 2020;Petetin et al, 2020;Tobías et al, 2020;Wang et al, 2020).…”

Section: Introductionmentioning

confidence: 91%

What can we learn about urban air quality with regard to the first outbreak of the COVID-19 pandemic? A case study from central Europe

Salma¹,

Vörösmarty²,

Gyöngyösi³

et al. 2020

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Abstract. Motor vehicle road traffic in central Budapest was reduced by approximately 50 % of its ordinary level for several weeks as a consequence of various limitation measures introduced to mitigate the first outbreak of the COVID-19 pandemic in 2020. The situation was utilised to assess the real potentials of urban traffic on air quality. Concentrations of NO, NO2, CO, O3, SO2 and particulate matter (PM) mass, which are ordinarily monitored in cities for air quality considerations, aerosol particle number size distributions, which are not rarely measured continuously on longer runs for research purposes, and meteorological properties usually available were collected and jointly evaluated in different pandemic phases. The largest changes occurred over the severest limitations (partial lockdown in the Restriction phase from 28 March to 17 May 2020). Concentrations of NO, NO2, CO, total particle number (N6–1000) and particles with a diameter < 100 nm declined by 68 %, 46 %, 27 %, 24 % and 28 %, respectively, in 2020 with respect to the average reference year comprising 2017–2019. Their quantification was based on both relative difference and standardised anomaly. The change rates expressed as relative concentration difference due to relative reduction in traffic intensity for NO, NO2, N6–1000 and CO were 0.63, 0.57, 0.40 and 0.22 (%/%), respectively. Of the pollutants which reacted in a sensitive manner to the change in vehicle circulation, it is the NO2 that shows the most frequent exceedance of the health limits. Intentional tranquillising of the vehicle flow has considerable potential for improving the air quality. At the same time, the concentration levels of PM10 mass, which is the most critical pollutant in many European cities including Budapest, did not seem to be largely affected by vehicles. Concentrations of O3 concurrently showed an increasing tendency with lower traffic, which was explained by its complex reaction mechanism. Modelling calculations indicated that spatial gradients of NO and NO2 within the city became further enhanced by reduced vehicle flow.

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“…At the same time, some other important pollutants such as N100-1000 or SO2which are typically related to larger spatial extent or region and which could, therefore, be influenced strongly by meteorologydid not change significantly. Similar reductions were reported for other urban locations in the world (Keller et al, 2020;Le et al, 2020;Lee et al, 2020;Tobías et al, 2020). This all can be interpreted that the alterations in NO, NO2, CO, N6-1000 and N6-100 concentrations were primarily caused by the lower vehicular https://doi.org/10.5194/acp-2020-997 Preprint.…”

Section: Quantification Of Concentration Changessupporting

confidence: 80%

“…As a consequence of the implemented measures, road traffic in many cities worldwide was reduced in a substantial manner and for a considerable time interval. In parallel, lower concentrations of several air pollutants were reported from both satellite observations and in situ measurements (Keller et al, 2020;Le et al, 2020;Lee et al 2020;Mahato et al, 2020;Nakada and Urban, 2020;Petetin et al, 2020;Tobías et al, 2020;Wang et al, 2020).…”

Section: Introductionmentioning

confidence: 91%

What can we learn about urban air quality with regard to the first outbreak of the COVID-19 pandemic? A case study from Central Europe

Salma¹,

Vörösmarty²,

Gyöngyösi³

et al. 2020

Preprint

View full text Add to dashboard Cite

Abstract. Motor vehicle road traffic in central Budapest was reduced by approximately 50 % of its ordinary level for several weeks as a consequence of various limitation measures introduced to mitigate the first outbreak of COVID-19 pandemic in 2020. The situation was utilised to assess the real potentials of urban traffic on air quality. Concentrations of NO, NO2, CO, O3, SO2 and particulate matter (PM) mass, which are ordinarily monitored in cities for air quality considerations, aerosol particle number size distributions, which are not rarely measured on-line continuously on longer run for research purposes and basic meteorological properties usually available were jointly evaluated. The largest changes occurred in the time interval of the severest limitations (partial lock-down in the Restriction phase from 28 March to 17 May 2020). Concentrations of NO, NO2, CO, total particle number (N6–1000) and particles with a diameter

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“…Factors that likely contribute to the high NH surface O3 in GEOS-CF are uncertainties in the production of O3 from the oxidation of isoprene (Travis et al, 2016;Bates et al, 2019) and errors in O3 deposition to wet surfaces (Travis et al, 2019). In addition, most OpenAQ observation sites are located near densely populated areas, and the 25x25 km 2 model simulation cannot fully capture the fine-scale features characteristic for these environments (Keller et al, 2020).…”

Section: Accepted Articlementioning

confidence: 99%