Retrieval of the sea spray aerosol mode from submicron particle size distributions and supermicron scattering during LASIC

Dedrick, Jeramy L.; Saliba, Georges; Williams, A.; Russell, Lynn M.; Lubin, Dan

doi:10.5194/amt-15-4171-2022

Cited by 7 publications

(6 citation statements)

References 93 publications

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“…Two‐hour averaged aerosol measurements from the Department of Energy Atmospheric Radiation Measurement Layered Atlantic Smoke Interactions with Clouds (LASIC) campaign on Ascension Island (8°S, 14.5°W, 360 m ASL) (Zuidema et al., 2018) provided particle concentration and composition measurements (Text S1, Table S2, Figures S1, S2 in Supporting Information ), of which we classified ∼40% as “clean” and the remaining 60% as “smoky” using criteria previously developed (Dedrick et al., 2022a) (Text S2, Figures S3, S4 in Supporting Information ). Submicron aerosol size distribution measurements were fit with three modes comprising of Aitken, accumulation, and sea‐spray modes, with the latter constrained by supermicron nephelometer scattering during clean conditions (Text S3, Figure S5 in Supporting Information ).…”

Section: Clean and Smoky Aerosol Size Distribution Modesmentioning

confidence: 99%

Aerosol‐Correlated Cloud Activation for Clean Conditions in the Tropical Atlantic Boundary Layer During LASIC

Dedrick,

Russell,

Sedlacek

et al. 2024

Geophysical Research Letters

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Aerosol measurements during the DOE ARM Layered Atlantic Smoke Interactions with Clouds (LASIC) campaign were used to quantify the differences between clean and smoky cloud condensation nuclei (CCN) budgets. Accumulation‐mode particles accounted for ∼70% of CCN at supersaturations <0.3% in clean and smoky conditions. Aitken‐mode particles contributed <20% and sea‐spray‐mode particles <10% at supersaturations <0.3%, but at supersaturations >0.3% Aitken particles contributions increased to 30%–40% of clean CCN. For clean conditions, the Hoppel minimum diameter was correlated to the accumulation‐mode number concentration, indicating aerosol‐correlated cloud activation was controlling the lower diameter cutoff for which particles serve as CCN. For smoky conditions, the contributions of Aitken particles increase and the correlation of cloud activation to accumulation‐mode particles is masked by the lower‐hygroscopicity smoke. These results provide the first multi‐month in situ quantitative constraints on the role of aerosol number size distributions in controlling cloud activation in the tropical Atlantic boundary layer.

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Section: Clean and Smoky Aerosol Size Distribution Modesmentioning

confidence: 99%

Aerosol‐Correlated Cloud Activation for Clean Conditions in the Tropical Atlantic Boundary Layer During LASIC

Dedrick,

Russell,

Sedlacek

et al. 2024

Geophysical Research Letters

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“…The linear regression line is shown in solid black. Modini et al (2015), as in Dedrick et al (2022a). Three lognormal modes were then fit to the merged size distributions at both sites using an automated algorithm that calculates the modal number concentration (N), geometric mean diameter (D g ), and geometric standard deviation (σ g ) as parameters of the fitted distribution Dedrick et al (2022a); Modini et al (2015); Saliba et al (2019).…”

Section: In-situ Aerosol Measurementsmentioning

confidence: 99%

Aerosol Size Distribution Properties Associated with Cold-Air Outbreaks in the Norwegian Arctic

Williams,

Dedrick,

Russell

et al. 2024

Preprint

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Abstract. The aerosol particles that provide cloud condensation and ice nuclei contribute to key cloud processes associated with cold-air outbreak (CAO) events but are poorly constrained in climate models due to sparse observations. Here we retrieve aerosol size distribution modes from measurements at Andenes, Norway during the Cold-Air Outbreaks in the Marine Boundary Layer Experiment (COMBLE) and at Zeppelin Observatory, approximately 1000 km upwind in Svalbard. During CAO events at Andenes, the sea spray mode number concentration is correlated to strong over-ocean winds with a mean of 8±4 cm-3 that is 71 % higher than during non-CAO conditions. Additionally during CAO events at Andenes, the mean Hoppel minimum diameter is 6 nm smaller than during non-CAO conditions though the estimated supersaturation is lower and the number concentration of particles that likely activated in-cloud is 109±61 cm-3 (similar to non-CAO conditions). For CAO trajectories between Zeppelin Observatory and Andenes, the upwind-to-downwind change in number concentration is largest for the accumulation mode with a mean decrease of 93±95 cm-3, likely attributable primarily to precipitation scavenging. These characteristic properties of aerosol size distributions during CAO events provide guidance for evaluating CAO aerosol-cloud interaction processes in models.

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“…3b-c), suggesting that its emergence at ASI is driven not by smoke. The likely source is sea spray in the MBL (Clarke et al, 1998;Dedrick et al, 2022;Saliba et al, 2019). A caveat in this dataset is that the LASIC ARM emplacement was within ~500 meters of a sea cliff, where winds and breaking waves may represent a large, localized particle source that is much less influential elsewhere in the SEA BL.…”

Section: Boundary Layer Size Distributionsmentioning

confidence: 99%

Biomass-burning smoke properties and its interactions with marine stratocumulus clouds in WRF-CAM5 and southeastern Atlantic field campaigns

Howes¹,

Saide²,

Coe³

et al. 2023

Preprint

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Abstract. A large part of the uncertainty in climate projections comes from poorly understood or constrained aerosol properties (e.g., particle size, composition, mixing state, aging processes) and aerosol-cloud interactions, as well as the difficulty in remotely sensing them. This is an issue especially in remote regions such as the southeast Atlantic, which exhibits large model spread due to the seasonal coexistence of extensive cloud cover and regional biomass burning smoke. Here we address these gaps by comparing the WRF-CAM5 model to multi-campaign observations (ORACLES, CLARIFY, and LASIC) of the southeastern Atlantic region in August 2017 to evaluate a broad swath of the model’s aerosol properties, processes, and transport, and the degree to which aerosol interactions with clouds are captured. Building on earlier work showing strong performance in model advection and mixing, we find that biomass-burning smoke aerosol size and composition are generally well-captured in the marine free troposphere, except for a likely overprediction of dust in the accumulation mode (7–17 % modeled dust fraction which is not present in the observations). Evaluating smoke aging trends, the model shows a steady increase in aerosol mean diameter and an unchanging composition as smoke ages, deviating from the observed trends that show a rise and subsequent fall in mean diameter over 4–12 days and a decreasing OA : BC ratio beyond 3 days. Both results are likely due to missing processes in the model that remove OA from the particle phase such as photolysis and heterogeneous aerosol chemistry. The observed composition change from the free-troposphere to the marine boundary layer (MBL) is not fully captured in the model, especially the observed enhancement of sulfate from 11 % to 37 % by mean mass fraction in ORACLES, and from 11 % to 26 % in CLARIFY. This points to the importance of properly representing sulfate formation from marine dimethyl sulfide (DMS) emissions and in smoke-free parcels. Additionally, the model does not capture the occurrence of an Aitken mode during clean and medium-smoke conditions in the boundary layer, likely pointing to misrepresentation of new particle formation. The model shows a persistent overprediction of aerosols in the MBL, especially for clean conditions, that multiple pieces of evidence link to weaker aerosol removal in the modeled MBL than reality. This evidence includes the model not representing observed shifts in the aerosol size distribution towards smaller sizes, the model not capturing the relative concentrations of carbon monoxide compared to black carbon, model underprediction of heavy rain events, and little evidence of persistent biases in modeled entrainment. Average below-cloud aerosol activation fraction (NCLD/NAER) remains relatively constant in WRF-CAM5 between field campaigns (~0.65), while it decreases substantially in observations from ORACLES (~0.78) to CLARIFY (~0.5), which could be due to the model misrepresentation of clean aerosol conditions. WRF-CAM5 also overshoots an observed upper limit on liquid cloud droplet concentration around NCLD=400–500 cm-3 observed in both ORACLES and CLARIFY and also overpredicts the spread in NCLD. This could be related to the model often drastically overestimating the strength of boundary layer vertical turbulence by up to a factor of 10 and having a bimodal—rather than the observed unimodal—probability distribution of updraft turbulent kinetic energy. We expect these results to motivate similar evaluations of other modeling systems and promote model development in these critical areas to reduce uncertainties in climate simulations.

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Retrieval of the sea spray aerosol mode from submicron particle size distributions and supermicron scattering during LASIC

Cited by 7 publications

References 93 publications

Aerosol‐Correlated Cloud Activation for Clean Conditions in the Tropical Atlantic Boundary Layer During LASIC

Aerosol‐Correlated Cloud Activation for Clean Conditions in the Tropical Atlantic Boundary Layer During LASIC

Aerosol Size Distribution Properties Associated with Cold-Air Outbreaks in the Norwegian Arctic

Biomass-burning smoke properties and its interactions with marine stratocumulus clouds in WRF-CAM5 and southeastern Atlantic field campaigns

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