Southern Ocean latitudinal gradients of cloud condensation nuclei

Humphries, Ruhi S.; Keywood, Melita; Gribben, Sean; McRobert, Ian M.; Ward, Jason; Selleck, Paul; Taylor, Sally; Harnwell, James; Flynn, Connor; Kulkarni, Gourihar; Mace, Gerald G.; Protat, Alain; Alexander, Simon P.; McFarquhar, Greg M.

doi:10.5194/acp-21-12757-2021

Cited by 36 publications

(57 citation statements)

References 68 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Zealand have observed N10 of 681 (388-839) cm −3 at latitudes similar to Baring Head(Humphries et al, 2021), which is also in line with our results. Out of other coastal sites, previous work at Mace Head by Dall'Osto et al (2011) saw N10 of 327 cm −3 in open ocean air and 1469 cm −3 during open ocean nucleation.…”

supporting

confidence: 92%

New particle formation in coastal New Zealand with a focus on open ocean air masses

Peltola

Trueblood

Gray

et al. 2021

Preprint

View full text Add to dashboard Cite

Abstract. Even though oceans cover the majority of the Earth, most aerosol measurements are from continental sites. We measured aerosol particle number size distribution at Baring Head, in coastal New Zealand, over a total period of 10 months to study aerosol properties and new particle formation, with a special focus on aerosol formation in open ocean air masses. Particle concentrations were higher in land-influenced air compared to clean marine air in all size classes from sub-10 nm to cloud condensation nuclei sizes. When classifying the particle number size distributions with traditional methods designed for continental sites, new particle formation was observed at the station throughout the year with an average event frequency of 23 %. While most of these traditional event days had some land-influence, we also observed particle growth starting from nucleation mode during 16 % of the data in clean marine air and at least part of this growth was connected to nucleation in the marine boundary layer. Sub-10 nm particles accounted for 29 % of the total aerosol number concentration of particles larger than 1 nm in marine air during the spring. This shows that nucleation in marine air is frequent enough to influence the total particle concentration. Particle formation in land-influenced air was more intense and had on average higher growth rates than what was found for marine air. Particle formation and primary emissions increased particle number concentrations as a function of time spent over land during the first 1–2 days spent over land. After this, nucleation seems to start getting suppressed by the pre-existing particle population, but accumulation mode particle concentration keeps increasing, likely due to primary particle emissions. Further work showed that traditional NPF events were favoured by sunny conditions with low relative humidity and wind speeds. In marine air, formation of sub-10 nm particles was favoured by low temperatures, relative humidity, and wind speeds and could happen even during the night. Our future work will study the mechanisms responsible for particle formation at Baring Head with a focus on different chemical precursor species. This study sheds light on both new particle formation in open ocean air masses coming from the Southern Ocean and local aerosol properties in New Zealand.

show abstract

supporting

confidence: 92%

New particle formation in coastal New Zealand with a focus on open ocean air masses

Peltola

Trueblood

Gray

et al. 2021

Preprint

View full text Add to dashboard Cite

show abstract

“…I. L. McCoy et al (2021) suggest that these FT Aitken particles (diameters ≤0.1 μm), in addition to acting as the primary source of CCN, also buffer SO CCN and N d against precipitation removal during biologically active time periods. The latitudinal pattern is driven in part by the large increases in the amount of phytoplankton and thus DMS production in the summertime seasonal ice zone around Antarctica (Curran & Jones, 2000) and increases in small aerosol particles south of the oceanic polar front during the SO summer (Humphries et al, 2016(Humphries et al, , 2021. Across the SO, strong correlations are observed between satellite retrieved N d and sea surface chlorophyll-a concentrations (a proxy for phytoplankton biomass; D. T. McCoy et al, 2015).…”

mentioning

confidence: 99%

Coalescence Scavenging Drives Droplet Number Concentration in Southern Ocean Low Clouds

Kang

Marchand

Wood

et al. 2022

Geophysical Research Letters

View full text Add to dashboard Cite

Cloud droplet number concentration (Nd) is a key microphysical property that is largely controlled by the balance between sources and sinks of aerosols that serve as cloud condensation nuclei (CCN). Despite being a key sink of CCN, the impact of coalescence scavenging on Southern Ocean (SO) cloud is poorly known. We apply a simple source‐and‐sink budget model based on parameterizations to austral summer aircraft observations to test model behavior and examine the relative influence of processes that determine Nd in SO stratocumulus clouds. The model predicts Nd with little bias and a correlation coefficient of ∼0.7 compared with observations. Coalescence scavenging is found to be an important sink of CCN in both liquid and mixed‐phase precipitating stratocumulus and reduces the predicted Nd by as much as 90% depending on the precipitation rate. The free tropospheric aerosol source controls Nd more strongly than the surface aerosol source during austral summer.

show abstract

“…There is an annual cycle in observed aerosol optical depth at Cape Grim, driven by both biogenic activity and long-range transport (Mitchell et al, 2017); however, the magnitude and location dependence is poorly characterized. These data sets only measured the northern region of the Southern Ocean, which has recently been shown to be distinct from the mid-and high-latitude regions (Humphries et al, 2021). There are also a number of portable sun photometers measurements that have been made within the AERONET Maritime Aerosol Network (Smirnov et al, 2009;Smirnov et al, 2011) and used in validation and model development of important aerosol components such as oceanic sea salt (Bian et al, 2019).…”

Section: The Important Role Of the Southern Ocean For Atmospheric Chemistrymentioning

confidence: 99%

Key challenges for tropospheric chemistry in the Southern Hemisphere

Paton-Walsh

Emmerson

Garland

et al. 2022

Elementa: Science of the Anthropocene

Self Cite

View full text Add to dashboard Cite

This commentary paper from the recently formed International Global Atmospheric Chemistry (IGAC) Southern Hemisphere Working Group outlines key issues in atmospheric composition research that particularly impact the Southern Hemisphere. In this article, we present a broad overview of many of the challenges for understanding atmospheric chemistry in the Southern Hemisphere, before focusing in on the most significant factors that differentiate it from the Northern Hemisphere. We present sections on the importance of biogenic emissions and fires in the Southern Hemisphere, showing that these emissions often dominate over anthropogenic emissions in many regions. We then describe how these and other factors influence air quality in different parts of the Southern Hemisphere. Finally, we describe the key role of the Southern Ocean in influencing atmospheric chemistry and conclude with a description of the aims and scope of the newly formed IGAC Southern Hemisphere Working Group.

show abstract

Southern Ocean latitudinal gradients of cloud condensation nuclei

Cited by 36 publications

References 68 publications

New particle formation in coastal New Zealand with a focus on open ocean air masses

New particle formation in coastal New Zealand with a focus on open ocean air masses

Coalescence Scavenging Drives Droplet Number Concentration in Southern Ocean Low Clouds

Key challenges for tropospheric chemistry in the Southern Hemisphere

Contact Info

Product

Resources

About