Aerosol size distribution (0.3-10 um) at Hornsund, spring 2021

Abstract. Accurate modeling of the scattering and absorption of ultraviolet and visible radiation by aerosols is essential for accurate simulations of atmospheric chemistry and climate. Closure studies using in situ measurements of aerosol scattering and absorption can be used to evaluate and improve models of aerosol optical properties without interference from model errors in aerosol emissions, transport, chemistry, or deposition rates. Here we evaluate the ability of four externally mixed, fixed size distribution parameterizations used in global models to simulate submicron aerosol scattering and absorption at three wavelengths using in situ data gathered during the 2008 Arctic Research of the Composition of the Troposphere from Aircraft and Satellites (ARCTAS) campaign. The four models are the NASA Global Modeling Initiative (GMI) Combo model, GEOS-Chem v9-02, the baseline configuration of a version of GEOS-Chem with online radiative transfer calculations (called GC-RT), and the Optical Properties of Aerosol and Clouds (OPAC v3.1) package. We also use the ARCTAS data to perform the first evaluation of the ability of the Aerosol Simulation Program (ASP v2.1) to simulate submicron aerosol scattering and absorption when in situ data on the aerosol size distribution are used, and examine the impact of different mixing rules for black carbon (BC) on the results. We find that the GMI model tends to overestimate submicron scattering and absorption at shorter wavelengths by 10–23 %, and that GMI has smaller absolute mean biases for submicron absorption than OPAC v3.1, GEOS-Chem v9-02, or GC-RT. However, the changes to the density and refractive index of BC in GC-RT improve the simulation of submicron aerosol absorption at all wavelengths relative to GEOS-Chem v9-02. Adding a variable size distribution, as in ASP v2.1, improves model performance for scattering but not for absorption, likely due to the assumption in ASP v2.1 that BC is present at a constant mass fraction throughout the aerosol size distribution. Using a core-shell mixing rule in ASP overestimates aerosol absorption, especially for the fresh biomass burning aerosol measured in ARCTAS-B, suggesting the need for modeling the time-varying mixing states of aerosols in future versions of ASP.

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Retrieval of stratospheric aerosol size distribution from atmospheric extinction of solar radiation at two wavelengths

Applied Optics ◽

10.1364/ao.22.001639 ◽

1983 ◽

Vol 22 (11) ◽

pp. 1639 ◽

Cited By ~ 34

Author(s):

Glenn K. Yue ◽

Adarsh Deepak

Keyword(s):

Solar Radiation ◽

Size Distribution ◽

Stratospheric Aerosol ◽

Aerosol Size Distribution ◽

Atmospheric Extinction

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Faucet aerator design influences aerosol size distribution and microbial contamination level

The Science of The Total Environment ◽

10.1016/j.scitotenv.2021.145690 ◽

2021 ◽

Vol 775 ◽

pp. 145690

Author(s):

Marie-Ève Benoit ◽

Michèle Prévost ◽

Antonella Succar ◽

Dominique Charron ◽

Eric Déziel ◽

...

Keyword(s):

Size Distribution ◽

Microbial Contamination ◽

Aerosol Size Distribution ◽

Contamination Level

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Combining airborne in situ and ground-based lidar measurements for attribution of aerosol layers

10.5194/acp-2017-1085 ◽

2018 ◽

Author(s):

Anna Nikandrova ◽

Ksenia Tabakova ◽

Antti Manninen ◽

Riikka Väänänen ◽

Tuukka Petäjä ◽

...

Keyword(s):

Boundary Layer ◽

Size Distribution ◽

Aerosol Size Distribution ◽

Long Range Transport ◽

Back Trajectories ◽

Clear Sky ◽

Temporal And Spatial Variability ◽

Range Transport ◽

Temporal And Spatial

Abstract. Understanding the distribution of aerosol layers is important for determining long range transport and aerosol radiative forcing. In this study we combine airborne in situ measurements of aerosol with data obtained by a ground-based High Spectral Resolution Lidar (HSRL) and radiosonde profiles to investigate the temporal and vertical variability of aerosol properties in the lower troposphere. The HSRL was deployed in Hyytiälä, Southern Finland, from January to September 2014 as a part of the US DoE ARM (Atmospheric Radiation Measurement) mobile facility during the BAECC (Biogenic Aerosols – Effects on Cloud and Climate) Campaign. Two flight campaigns took place in April and August 2014 with instruments measuring the aerosol size distribution from 10 nm to 10 µm at altitudes up to 3800 m. Two case studies from the flight campaigns, when several aerosol layers were identified, were selected for further investigation: one clear sky case, and one partly cloudy case. During the clear sky case, turbulent mixing ensured low temporal and spatial variability in the measured aerosol size distribution in the boundary layer whereas mixing was not as homogeneous in the boundary layer during the partly cloudy case. The elevated layers exhibited greater temporal and spatial variability in aerosol size distribution, indicating a lack of mixing. New particle formation was observed in the boundary layer during the clear sky case, and nucleation mode particles were also seen in the elevated layers that were not mixing with the boundary layer. Interpreting local measurements of elevated layers in terms of long-range transport can be achieved using back trajectories from Lagrangian models, but care should be taken in selecting appropriate arrival heights, since the modelled and observed layer heights did not always coincide. We conclude that higher confidence in attributing elevated aerosol layers with their air mass origin is attained when back trajectories are combined with lidar and radiosonde profiles.

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A global off-line model of size-resolved aerosol microphysics: I. Model development and prediction of aerosol properties

Atmospheric Chemistry and Physics ◽

10.5194/acp-5-2227-2005 ◽

2005 ◽

Vol 5 (8) ◽

pp. 2227-2252 ◽

Cited By ~ 213

Author(s):

D. V. Spracklen ◽

K. J. Pringle ◽

K. S. Carslaw ◽

M. P. Chipperfield ◽

G. W. Mann

Keyword(s):

Boundary Layer ◽

Sulfuric Acid ◽

Size Distribution ◽

Marine Boundary Layer ◽

Transport Model ◽

Model Development ◽

Aerosol Size Distribution ◽

Chemical Transport Model ◽

Cloud Processing ◽

Nucleation Mechanisms

Abstract. A GLObal Model of Aerosol Processes (GLOMAP) has been developed as an extension to the TOMCAT 3-D Eulerian off-line chemical transport model. GLOMAP simulates the evolution of the global aerosol size distribution using a sectional two-moment scheme and includes the processes of aerosol nucleation, condensation, growth, coagulation, wet and dry deposition and cloud processing. We describe the results of a global simulation of sulfuric acid and sea spray aerosol. The model captures features of the aerosol size distribution that are well established from observations in the marine boundary layer and free troposphere. Modelled condensation nuclei (CN>3nm) vary between about 250–500 cm-3 in remote marine boundary layer regions and are generally in good agreement with observations. Modelled continental CN concentrations are lower than observed, which may be due to lack of some primary aerosol sources or the neglect of nucleation mechanisms other than binary homogeneous nucleation of sulfuric acid-water particles. Remote marine CN concentrations increase to around 2000–10 000 cm

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Geophysical applicability of aerosol size distribution measurements using cascade impactors and proton induced X-ray emission

Atmospheric Environment (1967) ◽

10.1016/0004-6981(76)90040-8 ◽

1976 ◽

Vol 10 (8) ◽

pp. 571-576 ◽

Cited By ~ 22

Author(s):

R.E. Van Grieken ◽

T.B. Johansson ◽

K.R. Akselsson ◽

J.W. Winchester ◽

J.W. Nelson ◽

...

Keyword(s):

Size Distribution ◽

Aerosol Size Distribution ◽

X Ray ◽

Cascade Impactors

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Determination of atmospheric aerosol particle size distribution and visibility using a mobile laboratory

Canadian Journal of Physics ◽

10.1139/p82-150 ◽

1982 ◽

Vol 60 (8) ◽

pp. 1101-1107

Author(s):

C. V. Mathai ◽

A. W. Harrison

Keyword(s):

Particle Size ◽

Particle Size Distribution ◽

Size Distribution ◽

Atmospheric Aerosols ◽

Suspended Particle ◽

Aerosol Size Distribution ◽

Size Distributions ◽

Mobile Laboratory ◽

Mean Values ◽

The City

As part of an ongoing general research program on the effects of atmospheric aerosols on visibility and its dependence on aerosol size distributions in Calgary, this paper presents the results of a comparative study of particle size distribution and visibility in residential (NW) and industrial (SE) sections of the city using a mobile laboratory. The study was conducted in the period October–December, 1979. An active scattering aerosol spectrometer measured the size distributions and the corresponding visibilities were deduced from scattering coefficients measured with an integrating nephelometer.The results of this transit study show significantly higher suspended particle concentrations and reduced visibilities in the SE than in the NW. The mean values of the visibilities are 44 and 97 km for the SE and the NW respectively. The exponent of R (particle radius) in the power law aerosol size distribution has a mean value of −3.36 ± 0.24 in the SE compared with the corresponding value of −3.89 ± 0.39 for the NW. These results arc in good agreement with the observations of Alberta Environment; however, they are in contradiction with a recent report published by the City of Calgary.

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On the competition among aerosol number, size and composition in predicting CCN variability: a multi-annual field study in an urbanized desert

Atmospheric Chemistry and Physics ◽

10.5194/acp-15-6943-2015 ◽

2015 ◽

Vol 15 (12) ◽

pp. 6943-6958 ◽

Cited By ~ 33

Author(s):

E. Crosbie ◽

J.-S. Youn ◽

B. Balch ◽

A. Wonaschütz ◽

T. Shingler ◽

...

Keyword(s):

Chemical Composition ◽

Size Distribution ◽

North American ◽

Monsoon Season ◽

Aerosol Size Distribution ◽

North American Monsoon ◽

Aerosol Composition ◽

Data Set ◽

The North ◽

Concentration Changes

Abstract. A 2-year data set of measured CCN (cloud condensation nuclei) concentrations at 0.2 % supersaturation is combined with aerosol size distribution and aerosol composition data to probe the effects of aerosol number concentrations, size distribution and composition on CCN patterns. Data were collected over a period of 2 years (2012–2014) in central Tucson, Arizona: a significant urban area surrounded by a sparsely populated desert. Average CCN concentrations are typically lowest in spring (233 cm−3), highest in winter (430 cm−3) and have a secondary peak during the North American monsoon season (July to September; 372 cm−3). There is significant variability outside of seasonal patterns, with extreme concentrations (1 and 99 % levels) ranging from 56 to 1945 cm−3 as measured during the winter, the season with highest variability. Modeled CCN concentrations based on fixed chemical composition achieve better closure in winter, with size and number alone able to predict 82 % of the variance in CCN concentration. Changes in aerosol chemical composition are typically aligned with changes in size and aerosol number, such that hygroscopicity can be parameterized even though it is still variable. In summer, models based on fixed chemical composition explain at best only 41 % (pre-monsoon) and 36 % (monsoon) of the variance. This is attributed to the effects of secondary organic aerosol (SOA) production, the competition between new particle formation and condensational growth, the complex interaction of meteorology, regional and local emissions and multi-phase chemistry during the North American monsoon. Chemical composition is found to be an important factor for improving predictability in spring and on longer timescales in winter. Parameterized models typically exhibit improved predictive skill when there are strong relationships between CCN concentrations and the prevailing meteorology and dominant aerosol physicochemical processes, suggesting that similar findings could be possible in other locations with comparable climates and geography.

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