209 research outputs found
Hygroscopic and chemical characterisation of Po Valley aerosol
Continental summer-time aerosol in the Italian Po Valley was characterised in
terms of hygroscopic properties and the influence of chemical composition
therein. Additionally, the ethanol affinity of particles was analysed. The
campaign-average minima in hygroscopic growth factors (HGFs, at 90%
relative humidity) occurred just before and during sunrise from 03:00 to
06:00 LT (all data are reported in the local time), but, more generally, the
hygroscopicity during the whole night is very low, particularly in the
smaller particle sizes. The average HGFs recorded during the low HGF period
were in a range from 1.18 (for the smallest, 35nm particles) to 1.38 (for the
largest, 165 nm particles). During the day, the HGF gradually increased to
achieve maximum values in the early afternoon hours 12:00–15:00, reaching
1.32 for 35 nm particles and 1.46 for 165 nm particles. Two contrasting
case scenarios were encountered during the measurement period: Case 1 was
associated with westerly air flow moving at a moderate pace and Case 2 was
associated with more stagnant, slower moving air from the north-easterly
sector. Case 1 exhibited weak diurnal temporal patterns, with no distinct
maximum or minimum in HGF or chemical composition, and was associated with
moderate non-refractory aerosol mass concentrations (for 50% size cut at
1 μ) of the order of 4.5 μg m<sup>−3</sup>. For Case 1,
organics contributed typically 50% of the mass. Case 2 was characterised
by >9.5 μg m<sup>−3</sup> total non-refractory mass
(<1 μ) in the early morning hours (04:00), decreasing to
~3 μg m<sup>−3</sup> by late morning (10:00) and exhibited strong
diurnal changes in chemical composition, particularly in nitrate mass but
also in total organic mass concentrations. Specifically, the concentrations
of nitrate peaked at night-time, along with the concentrations of
hydrocarbon-like organic aerosol (HOA) and of semi-volatile oxygenated
organic aerosol (SV-OOA). In general, organic growth factors (OGFs) followed
a trend which was opposed to HGF and also to the total organic mass as
measured by the aerosol mass spectrometer. The analysis of the HGF
probability distribution function (PDF) reveals an existence of a predominant
"more hygroscopic" (MH) mode with HGF of 1.5 around noon, and two
additional modes: one with a "less hygroscopic" (LH) HGF of 1.26, and
another with a "barely hygroscopic" (BH) mode of 1.05. Particles sized
165 nm exhibited moderate diurnal variability in HGF, ranging from 80% at
night to 95% of "more hygroscopic" growth factors (i.e. HGFs 1.35–1.9)
around noon. The diurnal changes in HGF progressively became enhanced with
decreasing particle size, decreasing from 95% "more hygroscopic" growth
factor fraction at noon to 10% fraction at midnight, while the "less
hygroscopic" growth factor fraction (1.13–1.34) increased from 5% at
noon to > 60% and the "barely hygroscopic" growth factor
fraction (1.1–1.2) increased from less than 2% at noon to 30% at
midnight. Surprisingly, the lowest HGFs occurred for the period when nitrate
mass reached peak concentrations (Case 2). We hypothesised that the low HGFs
of nitrate-containing particles can be explained by a) an organic coating
suppressing the water-uptake, and/or by b) the existence of nitrates in a
less hygroscopic state, e.g. as organic nitrates. The latter hypothesis
allows us to explain also the reduced OGFs observed during the early morning
hours (before dawn) when nitrate concentrations peaked, based on the evidence
that organic nitrates have significant lower ethanol affinity than other
SV-OOA compounds
Model evaluation of marine primary organic aerosol emission schemes
In this study, several marine primary organic aerosol (POA) emission schemes have been evaluated using the GEOS-Chem chemical transport model in order to provide guidance for their implementation in air quality and climate models. These emission schemes, based on varying dependencies of chlorophyll <i>a</i> concentration ([chl <i>a</i>]) and 10 m wind speed (<i>U</i><sub>10</sub>), have large differences in their magnitude, spatial distribution, and seasonality. Model comparison with weekly and monthly mean values of the organic aerosol mass concentration at two coastal sites shows that the source function exclusively related to [chl <i>a</i>] does a better job replicating surface observations. Sensitivity simulations in which the negative <i>U</i><sub>10</sub> and positive [chl <i>a</i>] dependence of the organic mass fraction of sea spray aerosol are enhanced show improved prediction of the seasonality of the marine POA concentrations. A top-down estimate of submicron marine POA emissions based on the parameterization that compares best to the observed weekly and monthly mean values of marine organic aerosol surface concentrations has a global average emission rate of 6.3 Tg yr<sup>−1</sup>. Evaluation of existing marine POA source functions against a case study during which marine POA contributed the major fraction of submicron aerosol mass shows that none of the existing parameterizations are able to reproduce the hourly-averaged observations. Our calculations suggest that in order to capture episodic events and short-term variability in submicron marine POA concentration over the ocean, new source functions need to be developed that are grounded in the physical processes unique to the organic fraction of sea spray aerosol
Office Indoor PM and BC Level in Lithuania: The Role of a Long-Range Smoke Transport Event
While the impacts of climate change on wildfires and resulting air pollution levels have been observed, little is known about how indoor air filtering systems are performing under intensive smoke conditions. For this aim, particle number size distribution and concentration in a size range 0.5–18 μm and equivalent black carbon (eBC) mass concentration were measured in a modern office with a mechanical ventilation system. Measurements took place from 30 September to 6 October 2020 in the Center for Physical Sciences and Technology (FTMC) campus located in the urban background environment in Lithuania. During the measurement campaign, an intensive pollution episode, related to long-range transport wildfire smoke, was observed. The results indicated that the smoke event increased both indoor and outdoor eBC mass concentrations twice. Filters were non-selective for different eBC sources (biomass burning versus traffic) or chemical composition of carbonaceous aerosol particles (eBC versus brown carbon (BrC)). Air filtering efficiency was found to be highly dependent on particle size. During the smoke event the highest particle number concentration was observed at 2.1 μm and 1.0 μm size particles in outdoor and indoor air, respectively. Differences of indoor to outdoor ratio between event and non-event days were not significant. Because of lower removal rate for small particles, eBC had higher contribution to total PM2.5 mass concentration in indoor air than in outdoor air. The results gained are crucial for decision-making bodies in order to implement higher-quality air-filtering systems in office buildings and, as a result, minimize potential health impacts. © 2021 by the authors
Shipborne measurements of Antarctic submicron organic aerosols: an NMR perspective linking multiple sources and bioregions
Abstract. The concentrations of submicron aerosol particles in maritime regions around
Antarctica are influenced by the extent of sea ice. This effect is two ways:
on one side, sea ice regulates the production of particles by sea spray
(primary aerosols); on the other side, it hosts complex communities of
organisms emitting precursors for secondary particles. Past studies
documenting the chemical composition of fine aerosols in Antarctica indicate
various potential primary and secondary sources active in coastal areas, in
offshore marine regions, and in the sea ice itself. In particular,
beside the well-known sources of organic and sulfur material originating
from the oxidation of dimethylsulfide (DMS) produced by microalgae, recent
findings obtained during the 2015 PEGASO cruise suggest that
nitrogen-containing organic compounds are also produced by the microbiota
colonizing the marginal ice zone. To complement the aerosol source
apportionment performed using online mass spectrometric techniques, here we
discuss the outcomes of offline spectroscopic analysis performed by nuclear
magnetic resonance (NMR) spectroscopy. In this study we (i) present the
composition of ambient aerosols over open-ocean waters across bioregions,
and compare it to the composition of (ii) seawater samples and (iii) bubble-bursting aerosols produced in a sea-spray chamber onboard the ship. Our
results show that the process of aerosolization in the tank enriches primary
marine particles with lipids and sugars while depleting them of free
amino acids, providing an explanation for why amino acids occurred only at
trace concentrations in the marine aerosol samples analyzed. The analysis of
water-soluble organic carbon (WSOC) in ambient submicron aerosol samples
shows distinct NMR fingerprints for three bioregions: (1) the open Southern
Ocean pelagic environments, in which aerosols are enriched with primary
marine particles containing lipids and sugars; (2) sympagic areas in the
Weddell Sea, where secondary organic compounds, including methanesulfonic
acid and semivolatile amines abound in the aerosol composition; and (3)
terrestrial coastal areas, traced by sugars such as sucrose, emitted by land
vegetation. Finally, a new biogenic chemical marker, creatinine, was
identified in the samples from the Weddell Sea, providing another
confirmation of the importance of nitrogen-containing metabolites in
Antarctic polar aerosols
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Top-down and bottom-up aerosol–cloud closure: towards understanding sources of uncertainty in deriving cloud shortwave radiative flux
Top-down and bottom-up aerosol–cloud shortwave radiative flux closures were conducted at the Mace Head Atmospheric Research Station in Galway, Ireland, in August 2015. This study is part of the BACCHUS (Impact of Biogenic versus Anthropogenic emissions on Clouds and Climate: towards a Holistic UnderStanding) European collaborative project, with the goal of understanding key processes affecting aerosol–cloud shortwave radiative flux closures to improve future climate predictions and develop sustainable policies for Europe. Instrument platforms include ground-based unmanned aerial vehicles (UAVs)1 and satellite measurements of aerosols, clouds and meteorological variables. The ground-based and airborne measurements of aerosol size distributions and cloud condensation nuclei (CCN) concentration were used to initiate a 1-D microphysical aerosol–cloud parcel model (ACPM). UAVs were equipped for a specific science mission, with an optical particle counter for aerosol distribution profiles, a cloud sensor to measure cloud extinction or a five-hole probe for 3-D wind vectors. UAV cloud measurements are rare and have only become possible in recent years through the miniaturization of instrumentation. These are the first UAV measurements at Mace Head. ACPM simulations are compared to in situ cloud extinction measurements from UAVs to quantify closure in terms of cloud shortwave radiative flux. Two out of seven cases exhibit sub-adiabatic vertical temperature profiles within the cloud, which suggests that entrainment processes affect cloud microphysical properties and lead to an overestimate of simulated cloud shortwave radiative flux. Including an entrainment parameterization and explicitly calculating the entrainment fraction in the ACPM simulations both improved cloud-top radiative closure. Entrainment reduced the difference between simulated and observation-derived cloud-top shortwave radiative flux (δRF) by between 25 and 60 W m−2. After accounting for entrainment, satellite-derived cloud droplet number concentrations (CDNCs) were within 30 % of simulated CDNC. In cases with a well-mixed boundary layer, δRF is no greater than 20 W m−2 after accounting for cloud-top entrainment and up to 50 W m−2 when entrainment is not taken into account. In cases with a decoupled boundary layer, cloud microphysical properties are inconsistent with ground-based aerosol measurements, as expected, and δRF is as high as 88 W m−2, even high (> 30 W m−2) after accounting for cloud-top entrainment. This work demonstrates the need to take in situ measurements of aerosol properties for cases where the boundary layer is decoupled as well as consider cloud-top entrainment to accurately model stratocumulus cloud radiative flux
Response of the Aerodyne Aerosol Mass Spectrometer to Inorganic Sulfates and Organosulfur Compounds: Applications in Field and Laboratory Measurements
Organosulfur compounds are important components of secondary organic aerosols (SOA). While the Aerodyne high-resolution time-of-flight aerosol mass spectrometer (AMS) has been extensively used in aerosol studies, the response of the AMS to organosulfur compounds is not well-understood. Here, we investigated the fragmentation patterns of organosulfurs and inorganic sulfates in the AMS, developed a method to deconvolve total sulfate into components of inorganic and organic origins, and applied this method in both laboratory and field measurements. Apportionment results from laboratory isoprene photooxidation experiment showed that with inorganic sulfate seed, sulfate functionality of organic origins can contribute ∼7% of SOA mass at peak growth. Results from measurements in the Southeastern U.S. showed that 4% of measured sulfate is from organosulfur compounds. Methanesulfonic acid was estimated for measurements in the coastal and remote marine boundary layer. We explored the application of this method to unit mass-resolution data, where it performed less well due to interferences. Our apportionment results demonstrate that organosulfur compounds could be a non-negligible source of sulfate fragments in AMS laboratory and field data sets. A reevaluation of previous AMS measurements over the full range of atmospheric conditions using this method could provide a global estimate/constraint on the contribution of organosulfur compounds
Effects of NH3 and alkaline metals on the formation of particulate sulfate and nitrate in wintertime Beijing
Sulfate and nitrate from secondary reactions remain as the most abundant inorganic species in atmospheric particle matter (PM). Their formation is initiated by oxidation (either in gas phase or particle phase), followed by neutralization reaction primarily by NH3, or by other alkaline species such as alkaline metal ions if available. The different roles of NH3 and metal ions in neutralizing H2SO4 or HNO3, however, are seldom investigated. Here we conducted semi-continuous measurements of SO4 2−, NO3 −, NH4 +, and their gaseous precursors, as well as alkaline metal ions (Na+, K+, Ca2+, and Mg2+) in wintertime Beijing. Analysis of aerosol acidity (estimated from a thermodynamic model) indicated that preferable sulfate formation was related to low pH conditions, while high pH conditions promote nitrate formation. Data in different mass fraction ranges of alkaline metal ions showed that in some ranges the role of NH3 was replaced by alkaline metal ions in the neutralization reaction of H2SO4 and HNO3 to form particulate SO4 2− and NO3 −. The relationships between mass fractions of SO4 2− and NO3 − in those ranges of different alkaline metal ion content also suggested that alkaline metal ions participate in the competing neutralization reaction of sulfate and nitrate. The implication of the current study is that in some regions the chemistry to incorporate sulfur and nitrogen into particle phase might be largely affected by desert/fugitive dust and sea salt, besides NH3. This implication is particularly relevant in coastal China and those areas with strong influence of dust storm in the North China Plain (NCP), both of which host a number of megacities with deteriorating air quality
Surface ocean-lower atmosphere study: Scientific synthesis and contribution to Earth system science
The domain of the surface ocean and lower atmosphere is a complex, highly dynamic component of the Earth system. Better understanding of the physics and biogeochemistry of the air-sea interface and the processes that control the exchange of mass and energy across that boundary define the scope of the Surface Ocean-Lower Atmosphere Study (SOLAS) project. The scientific questions driving SOLAS research, as laid out in the SOLAS Science Plan and Implementation Strategy for the period 2004-2014, are highly challenging, inherently multidisciplinary and broad. During that decade, SOLAS has significantly advanced our knowledge. Discoveries related to the physics of exchange, global trace gas budgets and atmospheric chemistry, the CLAW hypothesis (named after its authors, Charlson, Lovelock, Andreae and Warren), and the influence of nutrients and ocean productivity on important biogeochemical cycles, have substantially changed our views of how the Earth system works and revealed knowledge gaps in our understanding. As such SOLAS has been instrumental in contributing to the International Geosphere Biosphere Programme (IGBP) mission of identification and assessment of risks posed to society and ecosystems by major changes in the Earth́s biological, chemical and physical cycles and processes during the Anthropocene epoch. SOLAS is a bottom-up organization, whose scientific priorities evolve in response to scientific developments and community needs, which has led to the launch of a new 10-year phase. SOLAS (2015–2025) will focus on five core science themes that will provide a scientific basis for understanding and projecting future environmental change and for developing tools to inform societal decision-making
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