Your search keyword '"Sciare Jean"' showing total 4 results

1. Response of atmospheric composition to COVID-19 lockdown measures during spring in the Paris region (France).

Author

Petit, Jean-Eudes, Dupont, Jean-Charles, Favez, Olivier, Gros, Valérie, Zhang, Yunjiang, Sciare, Jean, Simon, Leila, Truong, François, Bonnaire, Nicolas, Amodeo, Tanguy, Vautard, Robert, and Haeffelin, Martial

Subjects

ATMOSPHERIC composition, COVID-19, STAY-at-home orders, PARTICULATE nitrate, COVID-19 pandemic, CARBONACEOUS aerosols

Abstract

Since early 2020, the COVID-19 pandemic has led to lockdowns at national scales. These lockdowns resulted in large cuts of atmospheric pollutant emissions, notably related to the vehicular traffic source, especially during spring 2020. As a result, air quality changed in manners that are still currently under investigation. The robust quantitative assessment of the impact of lockdown measures on ambient concentrations is however hindered by weather variability. In order to circumvent this difficulty, an innovative methodology has been developed. The Analog Application for Air Quality (A 3 Q) method is based on the comparison of each day of lockdown to a group of analog days having similar meteorological conditions. The A 3 Q method has been successfully evaluated and applied to a comprehensive in situ dataset of primary and secondary pollutants obtained at the SIRTA observatory, a suburban background site of the megacity of Paris (France). The overall slight decrease of submicron particulate matter (PM 1) concentrations (-14 %) compared to business-as-usual conditions conceals contrasting behaviors. Primary traffic tracers (NO x and traffic-related carbonaceous aerosols) dropped by 42 %–66 % during the lockdown period. Further, the A 3 Q method enabled us to characterize changes triggered by NO x decreases. Particulate nitrate and secondary organic aerosols (SOAs), two of the main springtime aerosol components in northwestern Europe, decreased by -45 % and -25 %, respectively. A NO x relationship emphasizes the interest of NO x mitigation policies at the regional (i.e., city) scale, although long-range pollution advection sporadically overcompensated for regional decreases. Variations of the oxidation state of SOA suggest discrepancies in SOA formation processes. At the same time, the expected ozone increase (+20 %) underlines the negative feedback of NO titration. These results provide a quasi-comprehensive observation-based insight for mitigation policies regarding air quality in future low-carbon urban areas. [ABSTRACT FROM AUTHOR]

Published

2021

2. Seasonal variability and source apportionment of volatile organic compounds (VOCs) in the Paris megacity (France).

Author

Baudic, Alexia, Gros, Valérie, Sauvage, Stéphane, Locoge, Nadine, Sanchez, Olivier, Sarda-Estève, Roland, Kalogridis, Cerise, Petit, Jean-Eudes, Bonnaire, Nicolas, Baisnée, Dominique, Favez, Olivier, Albinet, Alexandre, Sciare, Jean, and Bonsang, Bernard

Subjects

HYDROCARBONS & the environment, VOLATILE organic compounds & the environment, AIR quality, CLIMATE change

Abstract

Within the framework of air quality studies at the megacity scale, highly time-resolved volatile organic compound (C2-C8) measurements were performed in downtown Paris (urban background sites) from January to November 2010. This unique dataset included non-methane hydrocarbons (NMHCs) and aromatic/oxygenated species (OVOCs) measured by a GC-FID (gas chromatograph with a flame ionization detector) and a PTR-MS (proton transfer reaction - mass spectrometer), respectively. This study presents the seasonal variability of atmospheric VOCs being monitored in the French megacity and their various associated emission sources. Clear seasonal and diurnal patterns differed from one VOC to another as the result of their different origins and the influence of environmental parameters (solar radiation, temperature). Source apportionment (SA) was comprehensively conducted using a multivariate mathematical receptor modeling. The United States Environmental Protection Agency's positive matrix factorization tool (US EPA, PMF) was used to apportion and quantify ambient VOC concentrations into six different sources. The modeled source profiles were identified from near-field observations (measurements from three distinct emission sources: inside a highway tunnel, at a fireplace and from a domestic gas flue, hence with a specific focus on road traffic, wood-burning activities and natural gas emissions) and hydrocarbon profiles reported in the literature. The reconstructed VOC sources were cross validated using independent tracers such as inorganic gases (NO, NO2, CO), black carbon (BC) and meteorological data (temperature). The largest contributors to the predicted VOC concentrations were traffic-related activities (including motor vehicle exhaust, 15% of the total mass on the annual average, and evaporative sources, 10%), with the remaining emissions from natural gas and background (23%), solvent use (20%), wood-burning (18%) and a biogenic source (15%). An important finding of this work is the significant contribution from wood-burning, especially in winter, where it could represent up to ~ 50% of the total mass of VOCs. Biogenic emissions also surprisingly contributed up to ~ 30% in summer (due to the dominating weight of OVOCs in this source). Finally, the mixed natural gas and background source exhibited a high contribution in spring (35%, when continental air influences were observed) and in autumn (23%, for home heating consumption). [ABSTRACT FROM AUTHOR]

Published

2016

3. Evidence for a significant contribution of wood burning aerosols to PM2.5 during the winter season in Paris, France

Author

Favez, Olivier, Cachier, Hélène, Sciare, Jean, Sarda-Estève, Roland, and Martinon, Laurent

Subjects

*AEROSOLS, *WINTER, *AIR quality

Abstract

Abstract: Although particulate emissions from residential wood burning have become a subject of great scientific concern for a few years, data related to their impact on the air quality of large European urban centres are still missing. In the present study, we investigated the chemical and optical properties of fine (PM2.5) carbonaceous aerosols in Paris during the 2005 winter season in order to track the presence of wood burning emissions in such a large city. The use of a seven wavelength Aethalometer allowed us to document shortwave light absorption by brown-carbon-containing organic aerosols of biomass burning origin. In particular, a well-marked diurnal pattern of the spectral dependence of light absorption, with maxima during the night, could be observed every day of the campaign and attributed to wood burning emissions. Relatively high absorption Ångstrom exponents and WSOC/OC ratios (respectively 1.25 and 0.35 on average for the period of study) also indicated the importance of biomass burning aerosols in the Paris atmosphere in winter. Finally, a rough estimate of the contribution of wood burning carbonaceous aerosols to PM2.5 could be achieved. This contribution was found to be as high as 20 ± 10% on average at the Paris background site investigated here. [Copyright &y& Elsevier]

Published

2009

4. Characterization and contribution to PM2.5 of semi-volatile aerosols in Paris (France)

Author

Favez, Olivier, Cachier, Hélène, Sciare, Jean, and Le Moullec, Yvon

Subjects

*PARTICULATE matter, *AEROSOLS, *AIR sampling apparatus, *MICROBALANCES, *VOLATILE organic compounds, *AMMONIUM nitrate, *SEASONAL variations in biogeochemical cycles

Abstract

Collocated PM2.5 measurements using a conventional R&P TEOM (model 1400a) and a TEOM-FDMS were performed at a Paris urban background site during winter/summer field experiments. Results showed that conventional TEOM underestimates PM2.5 mass concentrations by about 50% in winter and 35% in summer. They also confirmed that this negative sampling artifact, due to the volatilization of semi-volatile material (SVM) inside the instrument, cannot be accurately accommodated by a single correction factor because of SVM routine fluctuations. A basic filter-based investigation of the SVM chemical composition also indicated that SVM, measured by the TEOM–FDMS, is mainly formed by ammonium nitrate in winter while significant contributions of semi-volatile organic matter were observed in summer. The latter species was found to possibly account for more than 50% of secondary organic aerosol formed during summer afternoons. These findings call for more investigation of the SVM chemical composition, particularly during the summer season, in Paris and in Europe. [Copyright &y& Elsevier]

Published

2007