Measurement report: Photochemical production and loss rates of formaldehyde and ozone across Europe

Nussbaumer, Clara M.; Crowley, John N.; Schuladen, Jan; Williams, Jonathan; Hafermann, Sascha; Reiffs, Andreas; Axinte, R.; Harder, Hartwig; Ernest, C. Tatum; Novelli, Anna; Sala, Katrin; Martínez, Mònica; Mallik, Chinmay; Tomsche, Laura; Plaß-Dülmer, C.; Bohn, Birger; Lelieveld, J.; Fischer, H.

doi:10.5194/acp-2021-694

Cited by 2 publications

(6 citation statements)

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“…Many different methods enable the determination of the dominant chemical regime, such as the use of the weekend ozone effect, which considers the response of O 3 to NO x reductions on weekends, or the ratio of HCHO to NO 2 , with various approaches from in situ observations, remote sensing and model simulations (e.g., Jin et al, 2020;Pusede and Cohen, 2012;Nussbaumer and Cohen, 2020;Duncan et al, 2010). We have recently shown that the fraction α of methyl peroxyradicals (CH 3 O 2 ) forming formaldehyde (HCHO) in correlation with ambient NO concentrations is capable of indicating the dominant chemical regime based on three different field campaigns across Europe in Finland (HUMPPA 2012), Germany (HOPE 2012 and Cyprus (CYPHEX 2014) (Nussbaumer et al, 2021). CH 3 O 2 formed from, for example, the oxidation of acetaldehyde (CH 3 CHO) or methane (CH 4 ) can either react with NO or OH radicals to form HCHO or undergo the competing reaction with HO 2 to form methyl hydroperoxide (CH 3 OOH).…”

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confidence: 99%

“…For more details, please see Fig. 1 in Nussbaumer et al (2021). α CH 3 O 2 consequently depends on the ambient concentrations of NO, OH and HO 2 and the respective rate constants for the reaction with CH 3 O 2 , the latter of which were taken from the IUPAC Task Group on Atmospheric Chemical Kinetic Data Evaluation (2021).…”

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confidence: 99%

“…Low values for α CH 3 O 2 with a high response to NO are an indicator for a NO x -limited regime, whereas high values for α CH 3 O 2 with little response to changing NO represent a VOC limitation (Fig. 11 in Nussbaumer et al, 2021). Investigating the dominant chemical regime is an important method for analyzing photochemical processes and air quality.…”

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confidence: 99%

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Tropospheric ozone production and chemical regime analysis during the COVID-19 lockdown over Europe

et al. 2022

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Abstract. The COVID-19 (coronavirus disease 2019) European lockdowns have led to a significant reduction in the emissions of primary pollutants such as NO (nitric oxide) and NO2 (nitrogen dioxide). As most photochemical processes are related to nitrogen oxide (NOx≡ NO + NO2) chemistry, this event has presented an exceptional opportunity to investigate its effects on air quality and secondary pollutants, such as tropospheric ozone (O3). In this study, we present the effects of the COVID-19 lockdown on atmospheric trace gas concentrations, net ozone production rates (NOPRs) and the dominant chemical regime throughout the troposphere based on three different research aircraft campaigns across Europe. These are the UTOPIHAN (Upper Tropospheric Ozone: Processes Involving HOx and NOx) campaigns in 2003 and 2004, the HOOVER (HOx over Europe) campaigns in 2006 and 2007, and the BLUESKY campaign in 2020, the latter performed during the COVID-19 lockdown. We present in situ observations and simulation results from the ECHAM5 (fifth-generation European Centre Hamburg general circulation model, version 5.3.02)/MESSy2 (second-generation Modular Earth Submodel System, version 2.54.0) Atmospheric Chemistry (EMAC), model which allows for scenario calculations with business-as-usual emissions during the BLUESKY campaign, referred to as the “no-lockdown scenario”. We show that the COVID-19 lockdown reduced NO and NO2 mixing ratios in the upper troposphere by around 55 % compared to the no-lockdown scenario due to reduced air traffic. O3 production and loss terms reflected this reduction with a deceleration in O3 cycling due to reduced mixing ratios of NOx, while NOPRs were largely unaffected. We also study the role of methyl peroxyradicals forming HCHO (αCH3O2) to show that the COVID-19 lockdown shifted the chemistry in the upper-troposphere–tropopause region to a NOx-limited regime during BLUESKY. In comparison, we find a volatile organic compound (VOC)-limited regime to be dominant during UTOPIHAN.

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Tropospheric ozone production and chemical regime analysis during the COVID-19 lockdown over Europe

et al. 2022

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“…Jin et al (2020); Pusede and Cohen (2012); Nussbaumer and Cohen (2020); Duncan et al (2010)). We have recently shown that the share α of methyl peroxyradicals (CH 3 O 2 ) forming formaldehyde (HCHO) in correlation with ambient NO concentrations is capable of indicating the dominant chemical regime based on three different field campaigns across Europe in Finland (HUMPPA 2012), Germany (HOPE 2012) and Cyprus (CYPHEX 2014) (Nussbaumer et al, 2021). CH 3 O 2 formed from e.g.…”

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confidence: 99%

“…the oxidation of methanol (CH 3 OH) or methane (CH 4 ) can either react with NO or OH radicals to form HCHO or undergo the competing reaction with HO 2 to form methyl hydroperoxide (CH 3 OOH). For more details, please see Figure 1 in Nussbaumer et al (2021). α CH3O2 consequently depends on the ambient concentrations of NO, OH and HO 2 and the respective rate constants for the reaction with CH 3 O 2 , the latter of which were taken from the IUPAC Task Group on Atmospheric Chemical Kinetic Data Evaluation (2021).…”

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Tropospheric ozone production and chemical regime analysis during the COVID-19 lockdown over Europe

Nussbaumer

Pozzer

Tadić

et al. 2021

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Abstract. The COVID-19 (Coronavirus disease 2019) European lockdowns have lead to a significant reduction in the emissions of primary pollutants such as NO (nitric oxide) and NO2 (nitrogen dioxide). As most photochemical processes are related to nitrogen oxide (NOx ≡ NO + NO2) chemistry, this event has presented an exceptional opportunity to investigate its effects on air quality and secondary pollutants, such as tropospheric ozone (O3). In this study, we present the effects of the COVID-19 lockdown on atmospheric trace gas concentrations, net ozone production rates (NOPR) and the dominant chemical regime throughout the troposphere based on three different research aircraft campaigns across Europe. These are the UTOPIHAN campaigns in 2003 and 2004, the HOOVER campaigns in 2006 and 2007 and the BLUESKY campaign in 2020, the latter performed during the COVID-19 lockdown. We present in situ observations and simulation results from the ECHAM5/MESSy Atmospheric Chemistry model which allows for scenario calculations with business as usual emissions during the BLUESKY campaign, referred to as "no-lockdown scenario". We show that the COVID-19 lockdown reduced NO and NO2 mixing ratios in the upper troposphere by around 55 % compared to the no-lockdown scenario due to reduced air traffic. O3 production and loss terms reflected this reduction with a deceleration in O3 cycling due to reduced mixing ratios of NOx while NOPRs were largely unaffected. We also study the role of methyl peroxyradicals forming HCHO (αCH3O2) to show that the COVID-19 lockdown shifted the chemistry in the upper troposphere/tropopause region to a NOx limited regime during BLUESKY. In comparison, we find a VOC limited regime to be dominant during UTOPIHAN.

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Measurement report: Photochemical production and loss rates of formaldehyde and ozone across Europe

Cited by 2 publications

References 70 publications

Tropospheric ozone production and chemical regime analysis during the COVID-19 lockdown over Europe

Tropospheric ozone production and chemical regime analysis during the COVID-19 lockdown over Europe

Tropospheric ozone production and chemical regime analysis during the COVID-19 lockdown over Europe

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