Meteorology-normalized impact of the COVID-19 lockdown  upon NO&amp;lt;sub&amp;gt;2&amp;lt;/sub&amp;gt; pollution in Spain

Pétetin, Hervé; Bowdalo, Dene; Soret, Albert; Guevara, Marc; Jorba, Oriol; Serradell, Kim; García‐Pando, Carlos Pérez

doi:10.5194/acp-20-11119-2020

Cited by 125 publications

(109 citation statements)

References 15 publications

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“…In Europe, reductions of NO 2 are typically slightly larger than we have seen in the UK in our study, perhaps reflecting more stringent lockdown policy. In Spain, NO 2 was reduced by 50 % at both urban traffic and urban background sites (Petetin et al, 2020); in Rome, Turin and Nice, NO 2 was reduced by 46, 30 and 63 %, respectively (Sicard et al, 2020). In all of these studies similarmagnitude increases of O 3 were observed, mainly attributed to the decreased nitric oxide (NO).…”

Section: Introductionmentioning

confidence: 83%

UK surface NO₂ levels dropped by 42 % during the COVID-19 lockdown: impact on surface O₃

et al. 2020

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Abstract. We report changes in surface nitrogen dioxide (NO2) across the UK during the COVID-19 pandemic when large and rapid emission reductions accompanied a nationwide lockdown (23 March–31 May 2020, inclusively), and compare them with values from an equivalent period over the previous 5 years. Data are from the Automatic Urban and Rural Network (AURN), which forms the basis of checking nationwide compliance with ambient air quality directives. We calculate that NO2 reduced by 42 %±9.8 % on average across all 126 urban AURN sites, with a slightly larger (48 %±9.5 %) reduction at sites close to the roadside (urban traffic). We also find that ozone (O3) increased by 11 % on average across the urban background network during the lockdown period. Total oxidant levels (Ox=NO2+O3) increased only slightly on average (3.2 %±0.2 %), suggesting the majority of this change can be attributed to photochemical repartitioning due to the reduction in NOx. Generally, we find larger, positive Ox changes in southern UK cities, which we attribute to increased UV radiation and temperature in 2020 compared to previous years. The net effect of the NO2 and O3 changes is a sharp decrease in exceedances of the NO2 air quality objective limit for the UK, with only one exceedance in London in 2020 up until the end of May. Concurrent increases in O3 exceedances in London emphasize the potential for O3 to become an air pollutant of concern as NOx emissions are reduced in the next 10–20 years.

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Section: Introductionmentioning

confidence: 83%

UK surface NO₂ levels dropped by 42 % during the COVID-19 lockdown: impact on surface O₃

et al. 2020

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“…At the same time, PM 10 mass represents disintegration sources, e.g. windblown soil, crustal rock, mineral and roadside dust, resuspended dust by car movement, agricultural activities in the region, construction work and material wear such as tire abrasion of cars at kerbside sites (Salma and Maenhaut, 2006;Putaud et al, 2010;Harrison et al, 2012;Salma et al, 2020a). They all can be important, particularly under dry weather conditions.…”

Section: Methodsmentioning

confidence: 99%

“…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: 92%

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

Atmos. Chem. Phys.

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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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“…Only essential businesses, including grocery stores and food trade, pharmacies, and other industries, were authorized to be open. While other non-essential businesses such as retail shops, bars, restaurants, and commercial companies, had to close [17]. After the lockdown, businesses in some nonessential sectors, including construction and industry, were gradually allowed to return to work.…”

Section: Air Pollution and Meteorological Data Collectionmentioning

confidence: 99%

Relations between Air Quality and Covid-19 Lockdown Measures in Valencia, Spain

Donzelli

Cioni

Cancellieri³

et al. 2021

IJERPH

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The set of measures to contain the diffusion of COVID-19 instituted by the European governments gave an unparalleled opportunity to improve our understanding of the transport and industrial sectors’ contribution to urban air pollution. The purpose of this study was to assess the impacts of the lockdown measures on air quality and pollutant emissions in Valencia, Spain. For this reason, we determined if there was a significant difference in the concentration levels of different particulate matter (PM) sizes, PM10, PM2.5, and NOx, NO2, NO, and O3, between the period of restrictions in 2020 and the same period in 2019. Our findings indicated that PM pollutant levels during the lockdown period were significantly different from the same period of the previous year, even if there is variability in the different local areas. The highest variations reduction in the PM10 and PM2.5 levels were observed for the València Centre, València Avd Francia, and València Pista de Silla (all of the urban traffic type) in which there was a reduction of 58%–42%, 56%–53%, and 60%–41% respectively. Moreover, consistent with recent studies, we observed a significant reduction in nitric oxide levels in all the air monitoring stations. In all seven monitoring stations, it was observed, in 2020, NOx, NO2, and NO concentrations decreased by 48.5%–49.8%–46.2%, 62.1%–67.4%–45.7%, 37.4%–35.7%–35.3%, 60.7%–67.7%–47.1%, 65.5%–65.8%–63.5%, 60.0%–64.5%–41.3%, and 60.4%–61.6%–52.5%, respectively. Lastly, overall O3 levels decreased during the lockdown period, although this phenomenon was more closely related to weather conditions. Overall, no significant differences were observed between the meteorological conditions in 2019 and 2020. Our findings suggest that further studies on the effect of human activities on air quality are needed and encourage the adoption of a holistic approach to improve urban air quality.

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Meteorology-normalized impact of the COVID-19 lockdown upon NO<sub>2</sub> pollution in Spain

Cited by 125 publications

References 15 publications

UK surface NO₂ levels dropped by 42 % during the COVID-19 lockdown: impact on surface O₃

UK surface NO₂ levels dropped by 42 % during the COVID-19 lockdown: impact on surface O₃

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

Relations between Air Quality and Covid-19 Lockdown Measures in Valencia, Spain

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Meteorology-normalized impact of the COVID-19 lockdown upon NO&lt;sub&gt;2&lt;/sub&gt; pollution in Spain

Cited by 125 publications

References 15 publications

UK surface NO2 levels dropped by 42 % during the COVID-19 lockdown: impact on surface O3

UK surface NO2 levels dropped by 42 % during the COVID-19 lockdown: impact on surface O3

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

Relations between Air Quality and Covid-19 Lockdown Measures in Valencia, Spain

Contact Info

Product

Resources

About

Meteorology-normalized impact of the COVID-19 lockdown upon NO<sub>2</sub> pollution in Spain

UK surface NO₂ levels dropped by 42 % during the COVID-19 lockdown: impact on surface O₃

UK surface NO₂ levels dropped by 42 % during the COVID-19 lockdown: impact on surface O₃