Polluants atmosphériques organiques particulaires en Rhône-Alpes : caractérisation chimique et sources d'émissions / Atmospheric aerosols in the Rhône-Alpes region : chemical characterization and sources influences

Piot, Christine

28 September 2011

La réglementation plus sévère sur les niveaux de matières particulaires (PM) en atmosphère ambiante fixée par l'Union européenne à l'horizon 2015 impose de pouvoir quantifier les contributions des différentes sources d'émission. Les sources d'émissions primaires de particules peuvent être anthropiques (chauffage au bois, au fioul, émissions véhiculaires ou industrielles, combustion de déchets verts, activités de cuisine,…) ou naturelles (végétaux, poussières crustales). Des processus secondaires de formation des particules (conversion gaz-particules) peuvent également contribuer aux taux de PM mesurés. L'identification et la quantification des sources peuvent être conduites notamment à travers l'étude de la composante organique des aérosols réalisée à partir d'analyses chimiques de prélèvements sur filtres en atmosphère ambiante ou à l'émission. Dans ce travail, des méthodologies de caractérisation des sources d'émission par l'analyse de la fraction organique des PM et la quantification de leur influence sur les concentrations ambiantes en particules fines ont été développées et/ou adaptées de méthodologies existantes sur de nombreux sites d'observation. Une attention particulière a été portée sur différents sites de la région Rhône-Alpes où de nombreux épisodes de dépassements des valeurs limites en PM sont régulièrement enregistrés. Les méthodologies ont été développés dans un premier temps sur un site urbain de référence (sites des Frênes à Grenoble) et s'appuient à la fois sur des approches qualitatives d'études des sources (étude d'empreinte de grandes familles chimiques, utilisation de ratios de composés traceurs) et quantitatives (ACP, mesures isotopiques du carbone, Molecular-Marker Chemical Mass Balance). Elles permettent une bonne estimation des sources de matière organique (OM) et des PM en hiver. Leurs applications à d'autres sites de topologies différentes (ruraux, fond de vallées, proximités de sources, marin) en France et en Suisse et à d'autres saisons a permis de montrer la complémentarité des différentes approches introduites et la nécessité de leur adaptation aux spécificités des sites pour permettre une bonne estimation des PM. L'estimation des contributions des sources à l'OM reste cependant encore à améliorer. De plus, dans le cadre de leur application à des sites de vallées alpines suisses, l'approche quantitative de type CMB basée sur l'étude de traceurs organiques a pu être confrontée à une méthode basée sur l'étude de la composante inorganique des aérosols. Les méthodologies développées et mises en œuvre au cours de ce travail constituent des outils de référence dans le cadre d'études des sources d'aérosol à portée scientifique ou réglementaire à l'échelle nationale ou internationale. / Tougher European Union regulations of ambient particulate matter (PM) will require apportionment of the different sources. Primary sources can be anthropological sources (biomass burning, fossil-fuel combustion, cooking, ….) and natural sources (vegetative detritus, crustal dust). PM can also be formed by gas-to-particle conversion processes (secondary sources). The identification and sources apportionment can be conducted by studying the organic fraction of aerosols using chemical analysis on off-line filters in ambient and in emissions of sources. In this work, methodologies of emission sources characterization by analyzing the organic fraction of PM and the sources apportionment on fine aerosol mass were developed and/or adapted from previous methodologies on many ambient sites. A special focus was placed on different sites of the Rhône-Alpes Region where many exceedances of authorized PM values are observed. Methodologies were developed primarily for an urban background site (Les Frênes site in Grenoble) and are based both on qualitative approaches (footprints study of large chemical family, use of tracer ratios) and quantitative approaches (PCA, isotopic carbon measurements, Molecular-Marker Chemical Mass Balance). They allow a good estimation of OM (organic matter) and PM sources in winter. Applications of those methodologies for other sites with different topologies (rural, valley bottoms, near sources, marine, in France and in Switzerland, for different seasons) showed the complementarity of the different methodologies proposed. It also pointed out the necessity of adapting them to the specificities of each sites in order to have a good estimation of PM. In addition, further work should still be done to improve sources apportionment of OM. Moreover, in the context of applying those methodologies to Swiss alpine valley sites, it got possible to compare the quantitative CMB approach based on the study of organic compounds with another approach based on the study of the inorganic fraction of aerosols. Methodologies developed and optimized during this work will be used like reference to scientific or regulation applications in other national or international studies.

Aérosols atmosphériques

PM (matières particulaires)

Sources d'émissions

Traceurs de sources

Caractérisation chimique

Atmospheric aerosols

PM (particulate matter)

Emissions of sources

Tracers of sources

Chemical characterization

Sources apportionment

Incorporating Chemical Activity and Relative Humidity Effects in Regional Air Quality Modeling of Organic Aerosol Formation

Marks, Marguerite Colasurdo

20 August 2013

Atmospheric particulate matter is known to have significant effects on human health, visibility, and global climate. The magnitudes of these effects, however, depend in complex ways on chemical composition, relative humidity, temperature, phase state, and other parameters. Current regional air quality models such as CMAQ (Community Multiscale Air Quality model) ignore many of these considerations, and consider that the formation of secondary organic aerosol (SOA) can be calculated by assuming thermodynamic ideality in the organic particulate matter (OPM) phase as well as negligible uptake of water into the OPM phase. Theoretical predictions and model simulations considering non-ideality and water uptake show that the standard model assumptions can lead to large errors in predicted SOA mass, and that the magnitude of these errors is sensitive to the composition of the OPM phase. The SOA module in CMAQ v4.7.1 has been revised in this work to allow consideration of the effects of both non-ideality and water uptake. First, a reasonable specific surrogate structure was assigned to each of the lumped products assumed to be produced by reaction of the different precursor hydrocarbons considered in CMAQ (e.g., isoprene, benzene, and toluene). Second, the CMAQ code was modified to allow iterative calculation (at each point in space and time) of the gas/particle partitioning coefficient for each of the SOA-forming products and for water. Third, model simulations were performed for the Eastern US at a resolution of 36-km x 36-km for late summer 2006, under a range of relative humidity conditions. When compared with an appropriate base case, the modified code produced increases in SOA ranging from 0.17 to 0.51 micrograms per cubic meter. The average change was 0.30 micrograms per cubic meter, corresponding to a 37% increase in SOA formation. Incorporation of phase separation effects would likely lead to further increases in predicted SOA levels.

Air quality -- Mathematical models

Humidity -- Mathematical models

Atmospheric Sciences

Civil and Environmental Engineering

STABLE NITROGEN AND SULFUR ISOTOPES IN ATMOSPHERIC CHEMISTRY

Jianghanyang Li (10702320)

27 April 2021

<p>SO₂ and NO_x (NO+NO₂) are important trace gases in the atmosphere as they adversely affect air quality and are precursors to sulfate and nitrate aerosols in the atmosphere. However, there are significant uncertainties in the emission inventories and the atmospheric chemistry processes of both gases. Addressing these uncertainties will help us to 1) better regulate their emissions from anthropogenic activities, 2) understand the formation mechanism of aerosol pollution events, during which rapid accumulation of nitrate and sulfate aerosols are commonly observed, and 3) better constrain the impact of SO₂, NO_x, sulfate aerosols and nitrate aerosols to the global radiation balance. Stable isotopes of nitrogen and sulfur are useful tools in understanding both the origins and chemistry of SO₂ and NO_x since different emission sources usually display distinct sulfur and nitrogen isotopic compositions, and different SO₂ and NO_xoxidation pathways fractionate sulfur and nitrogen isotopes differently. In this dissertation, five studies are conducted to 1) use sulfur isotopes to investigate the sources and chemistry of atmospheric sulfur, and 2) improve our understanding of the isotopic fractionation processes associated with the atmospheric chemistry of reactive nitrogen. </p><p>Using stable sulfur isotopes, we first analyzed the sources of sulfate aerosols collected at Baring Head, New Zealand and atmospheric deposition at the Atacama Desert. At Baring Head, we found that the secondary sulfate, i.e., sulfate formed from atmospheric oxidation of SO₂, is mainly observed in fine aerosols (<1 µm) while the sulfate in coarse aerosols (>1 µm) is mostly sea salt sulfate. 73-77% of the secondary sulfate is sourced from biogenic emissions by ocean phytoplankton, and the rest is originated from anthropogenic activities. The sulfate deposition across the Atacama Desert, on the other hand, is a mixture of sea salt sulfate (only near the coast), anthropogenic SO₂ emissions, local soil, and lake salts. Then, sulfur isotopes were used to investigate the formation chemistry of sulfate aerosols collected during a strong winter haze episode in Nanjing, China, where the sources of SO₂ were well-understood. We found that, although the sources of sulfur remain unchanged during the haze episode, the sulfur isotopic compositions of sulfate vary significantly, suggesting isotopic fractionation occurred during the formation of sulfate aerosols. We interpreted the variation using a Rayleigh distillation model to evaluate the contribution of sulfate formation pathways. The model suggested that the Transition Metal Ion catalyzed O₂ oxidation pathway contributed 49±10% of the total sulfate production, while the O₃/H₂O₂ oxidations accounted for the rest. </p><p>Next, we conducted experiments in an atmospheric simulation chamber to determine the isotopic fractionations between NO and NO₂. This isotopic fractionation is controlled by a combination of two factors: 1) the equilibrium isotopic exchange between NO and NO₂ molecules, and 2) the kinetic isotope effects of the NO_x photochemical cycle, namely the Leighton Cycle Isotope Effect (LCIE). Our experiments showed that the fractionation factor during the isotopic exchange is 1.0289±0.0019, and the fractionation factor of LCIE is 0.990±0.005. A model was constructed to assess the relative importance of the two factors, showing the isotopic exchange should be the dominant factor when NO_x >20 ppb, while LCIE should be more important at low NO_x concentrations (<1 ppb) and high rates of NO₂photolysis. Last, we quantified the overall nitrogen isotopic fractionation during the formation of nitrate aerosols collected at Baring Head, New Zealand. Our results showed that significant and variable (0-15‰) isotopic fractionations occurred during the formation of nitrate aerosols. The isotopic fractionation factors are lower in the summer and higher in the winter, which is mainly caused by seasonal variations in nitrate formation pathways. </p><p>Overall, this dissertation first applied stable sulfur isotopes in aerosol samples collected in different environments, demonstrating that isotopes are excellent tools in identifying the origins and chemistry of atmospheric sulfur. Then, we investigated the isotopic fractionation processes during the atmospheric nitrogen chemistry, which can be useful for future studies aimed at understanding the origins and chemistry of atmospheric nitrogen using stable nitrogen isotopes.</p>

Environmental Science

Atmospheric Sciences

Atmospheric Aerosols

Isotope Geochemistry

atmospheric chemistry

stable isotopes

nitrogen oxides

sulfur dioxide

aerosol

ATMOSPHERIC PARTICLE IDENTIFICATION AND CHARACTERIZATION OF FIELD COLLECTED SAMPLES

Kevin Alan Jankowski (15339097)

22 April 2023

<p>  </p> <p>Atmospheric particles originate from all over the globe with wildly different sources such as sea spray aerosols of the ocean, mineral dust from deserts, biogenic emissions from forests, anthropogenic emissions of urban and industrial areas, volcanic eruptions, and many more. All of these particles can then be transported during which aging can occur where the external and internal chemical composition of particles and drastically be altered in which their physiochemical properties change or new particles as a whole are formed. Understanding what can cause this aging and correctly identifying how these particles change is vital for assessing climate in local areas. </p> <p>Chapter 3 focuses on dry intrusion (DI) and non-DI periods where vertical mixing of air occurs and allows for long range transport of particles. DI periods introduces populations of aged particles from far away sources into local regions. Identification and chemical characterization is performed for both of these periods to highlight the changes the DI period introduces in regards to particle morphology, chemical composition and lifetime. Analysis was performed via computer controlled scanning electron microscopy (CCSEM) for external information of the particles and scanning transmission x-ray microscopy (STXM) was used for internal information. The combination of these two techniques allows for a complete and thorough understanding of the particles during the two periods. </p> <p>Chapter 4 covers the first experiment done on a newly constructed cryogenic cooling cart which was created in the hopes to identify individual ice nucleating events of particles <em>in situ</em> when mimicking real world atmospheric conditions through temperature and humidity control. </p>

Atmospheric aerosols

Aerosols

Mixing States

An Investigation On Role Of Surface Reflectance And Aerosol Model In Remote Sensing Of Aerosols From Moderate-Resolution Imaging Spectroradiometer Over India

Jethva, Hiren, Satheesh, S K

07 1900

The Moderate-resolution Imaging Spectroradiometer (MODIS) onboard NASA’s Terra and Aqua satellites have provided a global distribution of aerosols. The space-based inversion of MODIS measurements requires assumption about the surface and aerosol properties, both are highly heterogeneous in space and time. This thesis has investigated the role of surface reflectance and aerosol properties on the retrieval of aerosols from MODIS over the Indian region. The aerosol properties retrieved by MODIS including total aerosol optical depth (AOD) and aerosol fine mode fraction (AFMF, fractional contribution of fine mode aerosols in the total AOD) were compared with that obtained from Aerosol Robotic Network (AERONET) at Kanpur (26.45◦N,80.35◦E), Indo-Gangetic Basin, northern India. This region is a special region for the study of aerosols as it offers strong aerosol seasonality, where the region is influenced by dust aerosols during pre-monsoon (March to June) and dominated by the fine mode particles in winter (November to February). The MODIS Collection 004 (C004) aerosol products systematically overestimated AOD in the presence of dust and underestimated when fine particles were dominant. The errors in the retrieval of dust AOD were correlated with the apparent reflectance at 2.1 µm, from which the surface reflectance in the visible channels (0.47 µm and 0.66 µm) were estimated using the “dark target” spectral correlation method. The error in the retrieval of AOD were also found to be large in the scattering angle range 120◦150◦, where the scattering properties of the non-spherical dust aerosols differ from that of the assumed spherical particles. AFMF of C004 was found to be highly biased to fine mode at Kanpur. The Collection 005 (C005) aerosol retrieval of the second-generation aerosol algorithm, however, showed improved retrieval of spectral AOD, which is likely to be attributed to the use of updated aerosol models and parameterized surface reflectance. In contrast to the C004 products, fine AOD and fine-model weighting (FMW) of C005 were biased very low at Kanpur and also over the greater Indian land region. This has indicated that the inversion of the space-based MODIS measurements is non-unique in which an improper combination of surface reflectance and aerosol model provide more accurate retrieval of the total aerosol optical depth. The surface reflectance relationships between the visible and shortwave-infrared 2.1 µm channels derived from the actual measurements of the surface reflectance using a spectroradiometer onboard an aircraft over Bangalore (12.95◦N,77.65◦E) in the southern India were found to have higher slope and intercept than that assumed by the MODIS algorithm over the same region. The high spectral correlations between the measured reflectance at longer wavelengths indicated some potential to estimate the surface reflectance at these wavelengths which needs further investigation. An experiment on the retrieval of aerosols carried out with several combinations of aerosol models and visible surface reflectance clearly shown that the surface reflectance in the visible channels assumed in the MODIS aerosol algorithm should be increased from its current parameterization in order to retrieve more accurate total as well as size-segregated aerosol optical properties at Kanpur and also over the greater Indian land region. In addition to the visible channels, inclusion of longer wavelengths in the aerosol inversion would likely improve the accuracy of retrieval over land by resolving the spectral dependence of aerosols. This in turn can help in separating the anthropogenic and natural aerosols in the total aerosol loading.

Remote Sensing Of Aerosols

Remote Sensing - India

Spectroradiometer

Atmospheric Aerosols

Aerosols - Measurement

Aerosols - Algorithms

Aerosol Robotic Network (AERONET)

Aerosol Variability - Northern India

Aerosol Retrieval - Northern India

Aerosol Models

Surface Reflectance

Meteorology

Characterization and sources of atmospheric particles in different population density environments / Πηγές και χαρακτηρισμός ατμοσφαιρικών σωματιδίων σε περιοχές διαφορετικής πυκνότητος πληθυσμού

Πικριδάς, Μιχαήλ

06 December 2013

In order to reduce uncertainty of atmospheric particle emissions and to examine the mechanism of new particle formation from precursor gases, measurements were conducted in a megacity (Paris, France), an urban area (Patras, Greece) and a remote location (Finokalia, Greece). At Finokalia, the composition of particles with diameter smaller than 1 μm (PM1) depended on air mass origin. The highest concentrations, and most frequent, were observed when air masses were coming from Europe. Organic aerosol was found to be 80% water soluble and the increased organic to elemental carbon ratio correlated with ozone concentration. These findings indicate that particulate matter (PM) at Finokalia was not emitted near the site but was transported from source regions hunderd of kilometers away and thus the area can be considered as a background of Europe. At Finokalia, atmospheric nucleation was observed more frequently during winter when sunlight intensity was below average and favored by air masses that crossed land before reaching the site. This behavior was explained by ammonia involvement in the nucleation process. PM1 was mainly acidic during summer and consumed all available ammonia, contrary to winter when, due to the lower sunlight intensity, particles were neutral and ammonia was available. During both seasons nucleation would only occur if particles were neutral which resulted in higher frequency of events during winter. Air masses that crossed land before reaching the site were enriched with ammonia, thus it was more likely for nucleation to occur. Number size distributions were monitored in Paris, France at fixed and mobile ground stations along with airborne measurements. The Paris plume was identified at a distance of at least 200 km from the city center and the number concentration was found to increase even by a 3-fold when air masses crossed Paris. During summer nucleation was observed approximately half of the campaign days; when the condensational sink was lower than average contrary to winter when no event was identified due to higher sink. Increased number concentration was observed at an altitude outside of the Paris plume simultaneously with new particle formation observed on the ground and was attributed to that phenomenon. At Patras, the legislated by E.U. daily PM10 standards were found to be violated. Exceedances were more frequent (58 of a total of 75) during the colder months (October to March) of the year. The warmer months (April to September) 80% of the PM2.5 was transported from other areas. Contrary during the colder months the contribution of transported PM reduced to 70% during autumn and 50% during winter, when the highest concentrations were observed on average. Local traffic contributed approximately 15% during winter and the remaining 35% was primarily due to domestic heating. PM2.5 and PM1 concentrations were found to exceed 100 μg m-3 on several occasions during nighttime due to domestic heating, either diesel or biomass combustion. Potassium, a tracer of biomass combustion, correlated well (R2=0.79) with PM2.5 during winter indicating a biomass source. Potassium concentrations were higher within the urban premises than a rural area located 36 km away from the city, indicating that at least a portion of the biomass combustion related PM2.5 were emitted locally. / Με σκοπό την μείωση της αβεβαιότητας των εκπομπών ατμοσφαιρικών σωματιδίων (ΑΣ) καθώς και διευκρίνισης του μηχανισμού σχηματισμού ΑΣ από την οξείδωση πρόδρομων αερίων, μετρήσεις πεδίου έλαβαν χώρα σε μία μεγαλούπολη (Παρίσι, Γαλλία), μία αστική περιοχή (Πάτρα, Ελλάδα) και σε μία απομακρυσμένη τοποθεσία (Φινοκαλιά, Ελλάδα). Στην Φινοκαλιά, η σύσταση των σωματιδίων με διάμετρο μικρότερη από 1 μm (ΑΣ1) εξαρτιόταν από την προέλευση των αερίων μαζών. Τις υψηλότερες συγκεντρώσεις εμφάνιζαν οι αέριες μάζες από τη Ευρώπη, που ήταν και οι πιο συχνές. Οργανικές ενώσεις των ΑΣ, εμφάνιζαν, υψηλή διαλυτότητα στο νερό (80%) και αυξημένο λόγο οργανικού προς στοιχειακό άνθρακα που συσχετιζόταν θετικά με τις συγκεντρώσεις όζοντος. Όλα τα παραπάνω υποδεικνύουν πως τα ΑΣ στην περιοχή της Φινοκαλιάς μεταφέρονταν από γειτονικές περιοχές εκατοντάδες χιλιόμετρα μακριά και συνεπώς η περιοχή μπορεί να θεωρηθεί ως σταθμός υποβάθρου για την Ευρώπη. Στην Φινοκαλιά, το φαινόμενο της ατμοσφαιρικής πυρηνογένεσης ήταν συχνότερο τους χειμερινούς μήνες, όταν η ένταση φωτός ήταν χαμηλότερη, και σε αέριες μάζες που παρέμεναν σημαντικό χρόνο πάνω από την στεριά πριν φτάσουν στον σταθμό. Αυτή η συμπεριφορά εξηγήθηκε με την συμμετοχή της αμμωνίας στην διαδικασία της πυρηνογένεσης. Τα ΑΣ1 το καλοκαίρι ήταν κατά κανόνα όξινα και κατανάλωναν όλη την διαθέσιμη αμμωνία σε αντίθεση με τον χειμώνα, όπου εξαιτίας της χαμηλότερης έντασης φωτός, τα ΑΣ1 ήταν ουδέτερα και υπήρχε διαθέσιμη. Και στις δύο περιόδους η πυρηνογένεση λάμβανε χώρα μόνο όταν τα σωματίδια ήταν ουδέτερα, το οποίο είχε ως αποτέλεσμα υψηλότερη συχνότητα του φαινομένου τους χειμερινούς μήνες. Οι αέριες μάζες όταν παρέμεναν πάνω από στεριά εμπλουτίζονταν με αμμωνία, αυξάνοντας την πιθανότητα πυρηνογένεσης. Κατανομές μεγέθους αριθμού μετρήθηκαν στο Παρίσι, Γαλλίας σε επίγειους σταθμούς, σταθερούς και κινητούς, καθώς και σε υψόμετρο. Ο θύσανος του Παρισιού ταυτοποιήθηκε σε απόσταση τουλάχιστον 200 km από την πόλη και οι συγκεντρώσεις αριθμού ΑΣ αύξαναν ακόμα και κατά 300% όταν οι αέριες μάζες προέρχονταν από το Παρίσι. Το καλοκαίρι πυρηνογένεση έλαβε χώρα τις μισές μέρες της δειγματοληψίας, όταν η διαθέσιμη επιφάνειας συμπύκνωσης ήταν χαμηλή, ενώ το χειμώνα, επειδή η διαθέσιμη επιφάνεια ήταν υψηλότερη, δεν ταυτοποιήθηκε το φαινόμενο. Αυξημένες συγκεντρώσεις αριθμού ΑΣ ταυτοποιήθηκαν εκτός του θυσάνου του Παρισιού ταυτόχρονα με πυρηνογένεση στο έδαφος και αποδόθηκαν σε αυτό το φαινόμενο. Στην Πάτρα τα θεσμοθετημένα από την Ε.Ε. ημερήσια όρια ΑΣ10 βρέθηκαν να παραβιάζονται. Οι υπερβάσεις ήταν πιο συχνές (58 από τις 75) τους ψυχρούς μήνες (Οκτώβριο - Μάρτιο). Τους θερμούς μήνες (Απρίλιο - Σεπτέμβριο) το 80% των ΑΣ2.5 μεταφέρονταν από άλλες περιοχές. Αντίθετα τους ψυχρούς μήνες η συνεισφορά από μεταφερόμενα ΑΣ μειωνόταν στο 70% το φθινόπωρο και 50% το χειμώνα, όταν και οι συγκεντρώσεις ΑΣ2.5 ήταν κατά μέσο όρο οι υψηλότερες στην περιοχή. Η τοπική κυκλοφορία συνείσφερε περίπου 15% τον χειμώνα ενώ ένα σημαντικό κομμάτι από το υπόλοιπο 35% οφειλόταν στην οικιακή θέρμανση. Συγκέντρωση ΑΣ2.5 και ΑΣ1 ίση ή μεγαλύτερη των 100 μg m-3 μετρήθηκε κατ'επανάληψη τις νυχτερινές ώρες των χειμερινών μηνών εξαιτίας της οικιακής θέρμανσης, είτε με πετρέλαιο είτε με καύση βιομάζας Η καύση βιομάζας υποδεικνύεται από την συσχέτιση (R2=0.79) των συγκεντρώσεων ΑΣ2.5 με τις συγκεντρώσεις καλίου, ένα δείκτη καύσης βιομάζας. Οι συγκεντρώσεις αυτού του δείκτη βρέθηκαν υψηλότερες μέσα στον αστικό ιστό από μία αγροτική περιοχή 36 km μακριά από την Πάτρα, αποκλείοντας την αποκλειστική μεταφορά ΑΣ2.5 καύσης βιομάζας από γειτονικές περιοχές.

Atmospheric nucleation

Source characterization Patras

Source characterization Finokalia

Atmospheric aerosols

Air suspended particles

Eastern Mediterranean aerosols

660.294 515

Αιωρούμενα σωματίδια

Surfactants in atmospheric aerosols and their role on cloud formation / Surfactants dans les aérosols atmosphériques et leur rôle dans la formation des nuages

Gérard, Violaine

16 November 2016

Les nuages sont essentiels dans le cycle de l'eau et dans le budget climatique mais certains aspects de leur formation sont encore incompris. La théorie de Köhler prédit que les surfactants devraient favoriser l'activation des particules en goutte de nuage alors que les modèles actuels les considèrent comme négligeables. Au début de ce travail de thèse, quelques études commençaient à démontrer le contraire mais des preuves du rôle de ces composés dans l'atmosphère étaient encore manquantes, d'où l'objectif de ce travail de thèse. Le développement d'une méthode pour déterminer la concentration en surfactants dans les aérosols a conduit aux premières courbes de tension de surface de surfactants atmosphériques dans des aérosols PM2.5 côtiers (Suède), et à l'identification du ratio C/CMC comme paramètre clé contrôlant l'efficacité des aérosols à former des nuages. Une seconde étude a révélé des corrélations fortes entre la présence de nuages et les propriétés intrinsèques des surfactants dans des aérosols PM1 boréaux (Finlande), démontrant pour la première fois le rôle des surfactants dans la formation des gouttes de nuage à partir d'observations directes dans l'atmosphère. Les résultats prédisent un nombre de noyaux de condensation en moyenne quatre fois plus important que lorsque les effets des surfactants étaient négligés, montrant l‘importance d'inclure l'effet des surfactants dans les modèles prédictifs. Cette importance a été confirmée en laboratoire par des expériences sur des gouttes individuelles microniques par l'augmentation de leur taille en présence de surfactants. Enfin, les observations à partir des différentes études indiquent une origine biologique des surfactants dans les aérosols atmosphériques / Clouds are essential components of the Earth’s hydrological system and climate but some aspects of their formation are still not completely understood. In particular, although Köhler theory predicts that surfactants should enhance cloud droplet activation, current models consider this role negligible. At the time of this PhD work, a few studies had started to demonstrate the contrary but atmospheric evidence for the role of these compounds was still missing and very little was known about their atmospheric concentrations, sources, and mechanism of action. The objective of this PhD work was to investigate these aspects. A method was developed to quantify surfactant concentrations in aerosols. Its application led to the first absolute atmospheric surfactants’ surface tension curves, in coastal PM2.5 aerosols in Sweden, and to the identification of the ratio C/CMC as the key parameter controlling the cloud-forming efficiency of aerosols. A second study revealed strong correlations between cloud occurrence and intrinsic surfactant properties in boreal PM1 aerosols in Finland, demonstrating for the first time the role of surfactants in cloud formation from direct atmospheric observations. The results predicted Cloud Condensation Nuclei numbers four times larger on average than when neglecting surfactant effects, showing the importance of including surfactant effects in cloud predictions models. The role of surfactants inferred from macroscopic measurements was confirmed by laboratory experiments on individual micron-sized droplets showing an increase of droplet growth in the presence of surfactants. Finally, observations from the different field studies indicated a biological origin for the surfactants present in atmospheric aerosols

Surfactants

Aérosols atmosphériques

Gouttes de nuage

Tension de surface

CMC

Gouttes microniques

Pince optique

Surfactants

Atmospheric aerosols

Cloud droplets

Surface tension

CMC

Micron-sized droplet

Optical trap

Origin of surfactants in atmosphere

540

Réactions photosensibilisées contribuant à la croissance et au vieillissement des aérosols atmosphériques organiques / Photosensitized reactions contributing to the growth and aging of atmospheric aerosols

Aregahegn, Kifle Zeleke

04 December 2014

L'atmosphère est un milieu hautement hétérogène contenant de la matière condensée : les aérosols. Ceux-ci sont des composants importants de l'atmosphère car ils impactent le bilan radiatif planétaire mais aussi la qualité de l'air. En particulier les aérosols organiques secondaires (AOS), produits par la transformation chimique dans l'air de nombreux composés organiques, plus ou moins volatils, représentent une fraction conséquente dans le budget global des aérosols atmosphériques pour laquelle de nombreuses incertitudes persistent. En particulier, leurs voies de formation et de transformation dans la troposphère restent très mal décrites. C'est pourquoi, cette thèse décrit principalement l'étude de trois aspects de la croissance et du vieillissement (transformation) des aérosols : caractérisation de la croissance des AOS par des processus photosensibilisés ; investigations mécanistiques du vieillissement des AOS et de la photochimie des photosensibilisateurs ; analyse chimique des composés issus du vieillissement des AOS / Aerosols are important constituents of the atmosphere and secondary organic aerosols (SOA) represent a main fraction of the organic aerosols in the total budget. This thesis mainly reports the investigation of three aspects of the growth and aging of SOA: the photosensitized SOA growth ; the mechanistic investigation of SOA aging and of the photochemistry of photosensitizers ; the analysis of the chemical composition of aged SOA. The photosensitized growth and aging processes of SOA were investigated using an aerosol flow tube coupled with various aerosol and gas sensing instruments. For further analysis of the aerosol composition and a better understanding of the formation and growth of SOA in these experiments the aerosols produced in the dark and in the light were sampled on filters at the exit of the flow tube

Réactions photosensibilisées

Photosensibilisateurs

Aérosols organiques secondaires

Aérosols atmosphériques

Croissance des particules

Vieillissement

Tube à écoulement

Photolyse à laser pulsé

Photosensitized reaction

Photosensitizers

Secondary organic aerosols

Atmospheric aerosols

Particle growth

Aging

Flow tube

Laser flash photolysis

541.35

LINKING INFANT LOCOMOTION DYNAMICS WITH FLOOR DUST RESUSPENSION AND EXPOSURE

Neeraja Balasubrahmaniam (8802989)

07 May 2020

<p>Infant exposure to the microbial and allergenic content of indoor floor dust has been shown to play a significant role in both the development of, and protection against, allergies and asthma later in life. Resuspension of floor dust during infant locomotion induces a vertical transport of particles to the breathing zone, leading to inhalation exposure to a concentrated cloud of coarse (> 1μm) and fine (≤ 1μm) particles. Resuspension, and subsequent exposure, during periods of active infant locomotion is likely influenced by gait parameters. This dependence has been little explored to date and may play a significant role in floor dust resuspension and exposure associated with forms of locomotion specific to infants. This study explores associations between infant locomotion dynamics and floor dust resuspension and exposure in the indoor environment. Infant gait parameters for walking and physiological characteristics expected to influence dust resuspension and exposure were identified, including: contact frequency (steps min^-1), contact area per step (m²), locomotion speed (m s^-1), breathing zone height (cm), and time-resolved locomotion profiles. Gait parameter datasets for standard gait experiments were collected for infants in three age groups: 12, 15, and 19 months-old (m/o). The gait parameters were integrated with an indoor dust resuspension model through a Monte Carlo framework to predict how age-dependent variations in locomotion affect the resuspension mass emission rate (mg h^-1) for five particle size fractions from 0.3 to 10 μm. Eddy diffusivity coefficients (m² s^-1) were estimated for each age group and used in a particle transport model to determine the vertical particle concentration profile above the floor.</p><p>Probability density functions of contact frequency, contact area, locomotion speed, breathing zone height, and size-resolved resuspension mass emission rates were determined for infants in each group. Infant standard gait contact frequencies were generally in the range of 100 to 300 steps min^-1and increased with age, with median values of 186 steps min^-1for 12 m/o, 207 steps min^-1 for 15 m/o, and 246.2 steps min^-1 for 19 m/o infants. Similarly, locomotion speed increased with age, from 67.3 cm s^-1at 12 m/o to 118.83 cm s^-1 at 19 m/o, as did the breathing zone height, which varied between 60 and 85 cm. Resuspension mass emission rates increased with both infant age and particle size. A 19 m/o infant will resuspend comparably more particles from the same indoor settled dust deposit compared to a 15 m/o or 12 m/o infant. Age-dependent variations in the resuspension mass emission rate and eddy diffusivity coefficient drove changes in the vertical particle concentration profile within the resuspended particle cloud. For all particle size fractions, there is an average of a 6% increase in the resuspended particle concentration at a height of 1 m from the floor for a 19 m/o compared to a 12 m/o infant. Time-resolved locomotion profiles were obtained for infants in natural gait during free play establish the transient nature of walking-induced particle resuspension and associated exposures for infants, with variable periods of active locomotion, no motion, and impulsive falls. This study demonstrates that floor dust resuspension and exposure can be influenced by the nature of infant locomotion patterns, which vary with age and are distinctly different from those for adults.</p>

Environmental Science

Atmospheric Aerosols

Developmental Psychology and Ageing

Environmental Engineering Modelling

Indoor air quality (IAQ)

infant development

microbial exposures

Particle Resuspension

house dust

AIRCRAFT-BASED STUDIES OF GREENHOUSE GASES AND AEROSOLS

Jay M Tomlin (14221835)

06 December 2022

<p>The Earth–atmosphere energy balance is dictated by incoming solar radiation and outgoing thermal radiation with greenhouse gases (GHG) and aerosols playing a major role in this effect. The atmospheric abundance and properties of airborne particles and gases lead to the redistribution of radiative energy, resulting in a warming or cooling effect. However, the extent of this effect remains to be insufficiently constrained. Improved quantification and characterization of GHG and aerosols are important requirements to inform current climate models. High-precision instrumentation and thoughtful experimental strategies are necessary to yield various analytical measurement datasets, despite complex meteorological and environmental conditions. This dissertation focuses on the assessment of CO₂and atmospheric particles from aircraft-based measurements enabling representative and spatially sampling of local regions of interest.</p> <p>Chapter 1 provides introductory discussion on the atmospheric implication of GHG and aerosols on the climate and related uncertainties. Chapter 2 summarizes the employed experimental techniques for quantification of GHG and characterization of atmospheric particles. We relied on an aircraft platform equipped with an air turbulence probe for 3D wind vector calculation and a high-precision cavity ring-down spectrometer for the quantification of ambient CO₂, CH₄, and H2O_<em>v</em>. Furthermore, the simultaneous composition and morphological information of aerosol samples were assessed using complementary chemical imaging techniques. Chemical composition of elements with Z > 23 was determined using computer-controlled scanning electron microscopy with energy dispersive X-ray spectroscopy (CCSEM/EDX). Scanning transmission X-ray microscopy coupled with near edge X-ray absorption fine structure spectroscopy (STXM/NEXAFS) was used to determined spatially resolved elemental specific molecular information present in atmospheric particles.</p> <p>Chapter 3 presents our study focused on the characterization of mixed mineral dust and biomass burning (BB) aerosols during an intensive burning event. We identified distinct particle types based on individual elemental contribution pre-, syn-, and post-burning event including highly carbonaceous (54–83%) particles, aged mineral dust (1–6%), and sulfur-containing particles (17–41%). X-ray spectromicroscopy techniques were used to characterize the internal chemical heterogeneity of individual BB particles and the morphology of soot inclusions, as well as changes in the particle organic volume fraction (OVF). An estimation method for particle component masses (i.e., organics, elemental carbon, and inorganics) inferred from STXM measurements was used to determine quantitative mixing state metrics based on entropy-derived diversity measures for particles acquired at different periods of the BB event. In general, there was a small difference in the particle-specific diversity among the samples (<em>D</em>_<em>α</em> = 1.3–1.8). However, the disparity from the bulk population diversity observed during the intense periods was found to have high values of <em>D</em>_<em>γ</em> = 2.5–2.9, while particles collected outside of the burning event displayed lower bulk diversity of <em>D</em>_<em>γ</em> = 1.5–2.0. Quantitative methods obtained from chemical imaging measurements presented here will serve to accurately characterize the evolution of mixed BB aerosols within urban environments.</p> <p>Chapter 4 follows the investigation of the physicochemical properties of atmospheric particles collected onboard a research aircraft flown over the Azores using offline spectromicroscopy techniques. Particles were collected within the marine boundary layer (MBL) and free troposphere (FT) comparing samples after long-range atmospheric transport episodes facilitated by dry intrusion (DI) events. The quantification of the OVF of individual particles derived from X-ray spectromicroscopy, which relates to the multi-component internal composition of individual particles, showed a factor of 2.06±0.16 and 1.11±0.04 increase in the MBL and FT, respectively, among DI samples. We show that supplying particle OVF into the <em>κ</em>-Köhler equation can be used as a good approximation of field-measured <em>in situ</em> CCN concentrations. We also report changes in the <em>κ</em> values in the MBL from <em>κ</em>_{MBL, non-DI} = 0.48 to <em>κ</em>_{MBL, DI} = 0.41, while changes in the FT result in <em>κ</em>_{FT, non-D}_I = 0.36 to <em>κ</em>_{FT, DI} = 0.33, which is consistent with enhancements in OVF followed by the DI episodes. Our observations suggest that the entrainment of particles from long-range continental sources alters the mixing state population and CCN properties of aerosol in the region.</p> <p>Chapter 5 discusses the identification and characterization of fine-mode primary biogenic atmospheric particles (PBAP) from the harvesting of crops. Particle samples were analyzed using complementary chemical imaging techniques to apportion the particle-type population based on their size, morphology, and composition. The contribution of PBAP in the size range of 0.15−1.25 μm is estimated to be 10−12% of ∼39,000 analyzed particles. In addition, particle viscosity and phase state were inferred with X-ray spectromicroscopic analysis has shown that the fine-mode organic particles collected are viscous/semisolid (10²−10¹² Pa s) while the majority of PBAP fragments are solid (>10¹²Pa s). The observation of submicrometer, solid carbonaceous fragments of biogenic origin have implications for the regional CCN and ice nuclei budget. Therefore, the seasonal harvesting of crops may play an important, yet unrecognized, role in regional cloud formation and climate.</p> <p>Chapter 6  explores the measurements and quantification of latent heat, sensible heat, and CO₂ fluxes among different land covers in the surrounding area of urban regions using airborne flux techniques. Cities account for the majority of the global CO₂ emissions due to the consumption of energy, resources, infrastructure, and transportation demands. Accordingly, the accurate quantification of these emissions, with exceptional precision, is necessary so that progress towards emission reduction can be monitored. However, a major challenge in quantifying urban emission estimates arises from accurate background emission definitions and apportionment of emission sources in complex urban environments. Airborne eddy covariance measurements were performed to quantify the bidirectional exchange of latent heat, sensible heat, and CO₂ fluxes in the upwind region of Indianapolis within an active biosphere. Here, we observed differences in fluxes across different days and land covers (e.g., corn, soybean, and forests) allowing us to understand the impact of seasonal variability in urban emissions during the full growing season. These experiments illustrate the capability of a research aircraft to perform technically challenging near-direct measurements of atmosphere–surface exchange over local and regional scales.</p> <p>Chapter 7 presents a new method to spatially allocate airborne mass balance CO₂ emissions. We performed seven aircraft measurements downwind of New York City (NYC) quantifying CO₂ emissions during the non-growing seasons of 2018–2020. A series of prior inventories and footprint transport models were used to account for flux contribution outside the area of interest and attribute emission sources within policy-relevant boundaries of the five boroughs encompassing NYC and then employ the modeled enhancement fraction (Φ) to the bulk emission observations from the mass balance approach. Here, we calculated a campaign-averaged source apportioned mass balance CO₂ emission rate of 56±24 kmol/s. The performance and accuracy of this approach were evaluated against other published works including inventory scaling and inverse modeling, yielding a difference of 5.1% with respect to the average emission rate reported by the two complementary approaches. Utilizing the ensemble of emissions inventories and transport models, we also evaluated the overall sources of variability induced by the prior (1.7%), the transport (4.2%), and the daily variability (42.0%). This approach provides a solution to interpreting aircraft-based mass balance results in complex emission environments.</p> <p>Chapter 8 concludes with a brief discussion of technological advances and research outlooks for X-ray spectromicroscopy analysis on atmospheric particles and the quantification of GHG. Opportunities for future applications and novel development of CCSEM/EDX and STXM/NEXAFS to substantially extend the instrument capabilities and improve our understanding of the physicochemical properties of individual atmospheric particles. Chapter 8 also discusses recent developments in satellite-based CO₂ monitoring to complement direct airborne observations. In recent years, significant progress has been made in satellite-based measurements of CO₂ to reveal the spatio-temporal variation in atmospheric CO₂ concentration. The column-averaged dry air CO₂ mole have reached an accuracy of ~1 ppm with a spatial resolution of less than 4 km. Furthermore, column-averaged retrievals can be used to detect and estimate the surface CO₂ fluxes in an active biosphere, quantify anthropogenic emissions over megacities, and monitor the transport of fossil fuel plumes across different continents and seasons.</p>

Atmospheric aerosols

Greenhouse gas inventories and fluxes

Aerosols

Greenhouse Gases

Airborne Measurements

Scanning Transmission X-ray Microscopy

Scanning Electron Microscopy

Cavity Ring-Down Spectroscopy

Mixing States

Airborne Eddy Covariance

Airborne Mass Balance Experiments