Enhancement of marine cloud albedo via controlled sea spray injections: a global model study of the influence of emission rates, microphysics and transport

Korhonen, Hannele; Carslaw, K. S.; Romakkaniemi, Sami

doi:10.5194/acp-10-4133-2010

Cited by 62 publications

(120 citation statements)

References 42 publications

(43 reference statements)

Supporting

Mentioning

111

Contrasting

Order By: Relevance

“…The size of the injected particles in this study is in the same size range as most previous ESM studies on sea spray climate engineering that simulate the aerosol injection (e.g. Alterskjaer et al, 2012Jones and Haywood, 2012;Korhonen et al, 2010;Muri et al, 2015;and Wang et al, 2011). It should also be mentioned that extensive measurements show that organics contribute substantially to the composition of sea spray aerosol, and in many areas is even the dominant constituent (e.g.…”

Section: Methodsmentioning

confidence: 48%

“…One of the advantages of simulating sea spray climate engineering in ESMs through sea salt aerosol emissions, compared to just increasing the CDNC, is that the cloud droplet activation process is taken into account. Previous studies have shown that injection of sea spray particles in some circumstances may actually reduce the CDNC due to increased competition for water vapour and reduced activation of background aerosol particles (Korhonen et al, 2010;Alterskjaer et al, 2012). showed in a single-model study that while the injection of accumulation-mode particles increased the CDNC, the injections of Aitken-or coarse-mode particles could have the opposite effect with a reduction in CDNC.…”

Section: Change In Sea Salt Concentrations Cloud Properties and Atmmentioning

confidence: 96%

See 1 more Smart Citation

Marine cloud brightening – as effective without clouds

et al. 2017

View full text Add to dashboard Cite

Abstract. Marine cloud brightening through sea spray injection has been proposed as a climate engineering method for avoiding the most severe consequences of global warming. A limitation of most of the previous modelling studies on marine cloud brightening is that they have either considered individual models or only investigated the effects of a specific increase in the number of cloud droplets. Here we present results from coordinated simulations with three Earth system models (ESMs) participating in the Geoengineering Model Intercomparison Project (GeoMIP) G4sea-salt experiment. Injection rates of accumulation-mode sea spray aerosol particles over ocean between 30 • N and 30 • S are set in each model to generate a global-mean effective radiative forcing (ERF) of −2.0 W m −2 at the top of the atmosphere. We find that the injection increases the cloud droplet number concentration in lower layers, reduces the cloud-top effective droplet radius, and increases the cloud optical depth over the injection area. We also find, however, that the global-mean clear-sky ERF by the injected particles is as large as the corresponding total ERF in all three ESMs, indicating a large potential of the aerosol direct effect in regions of low cloudiness. The largest enhancement in ERF due to the presence of clouds occur as expected in the subtropical stratocumulus regions off the west coasts of the American and African continents. However, outside these regions, the ERF is in general equally large in cloudy and clear-sky conditions. These findings suggest a more important role of the aerosol direct effect in sea spray climate engineering than previously thought.

show abstract

Section: Methodsmentioning

confidence: 48%

Section: Change In Sea Salt Concentrations Cloud Properties and Atmmentioning

confidence: 96%

Marine cloud brightening – as effective without clouds

et al. 2017

View full text Add to dashboard Cite

show abstract

“…perpendicular to the wind direction as suggested by Salter et al [7]. The vessel emits particles of 300 nm dry diameter [14,15], 25 m above the sea surface [7], at a rate of 15 kg s −1 (half the rate suggested by Salter et al [7]) for about 40 min and travels across the domain (4.8 km) once. From this emission rate, assuming the salinity of seawater to be 35 g kg −1 and NaCl being the sole solute, we derived a particle number flux of 1.72 × 10 16 s −1 .…”

Section: Methodsmentioning

confidence: 99%

Modelling artificial sea salt emission in large eddy simulations

Maalick

Korhonen

Kokkola

et al. 2014

Phil. Trans. R. Soc. A.

Self Cite

View full text Add to dashboard Cite

We study the dispersion of sea salt particles from artificially injected sea spray at a cloud-resolving scale. Understanding of how different aerosol processes affect particle dispersion is crucial when designing emission sources for marine cloud brightening. Compared with previous studies, we include for the first time an explicit treatment of aerosol water, which takes into account condensation, evaporation and their effect on ambient temperature. This enables us to capture the negative buoyancy caused by water evaporation from aerosols. Additionally, we use a higher model resolution to capture aerosol loss through coagulation near the source point. We find that, with a seawater flux of 15 kg s −1 , the cooling due to evaporation can be as much as 1.4 K, causing a delay in particle dispersion of 10–20 min. This delay enhances particle scavenging by a factor of 1.14 compared with simulations without aerosol water. We further show that both cooling and particle dispersion depend on the model resolution, with a maximum particle scavenging efficiency of 20% within 5 h after emission at maximum resolution of 50 m. Based on these results, we suggest further regional high-resolution studies which model several injection periods over several weeks.

show abstract

“…The recognition of the importance of sea salt nuclei in marine cloud processes has led to the interesting suggestion that global warming could be ameliorated somewhat through controlled enhancement of albedo and lifetime in low level marine clouds , in other words, geoengineering, whereby artificial floating sea spray generators are deployed in regions of persistent stratocumulus clouds. While intriguing as a geo-engineering solution to global warming, Korhonen et al (2010b), using a global model, and simulating emissions from a fleet of spray-emitting vessels in four regions of persistent stratocumulus fields found increases in cloud droplet concentration of maximum 20 %, and even a reduction was predicted in one region.…”

Section: Effects On Cloud Formation and Indirect Radiative Effectsmentioning

confidence: 99%

Ocean–Atmosphere Interactions of Particles

Leeuw

Guieu

Arneth

et al. 2013

Ocean-Atmosphere Interactions of Gases and Particles

View full text Add to dashboard Cite

This chapter provides an overview of the current knowledge on aerosols in the marine atmosphere and the effects of aerosols on climate and on processes in the oceanic surface layer. Aerosol particles in the marine atmosphere originate predominantly from direct production at the sea surface due to the interaction between wind and waves (sea spray aerosol, or SSA) and indirect production by gas to particle conversion. These aerosols are supplemented by aerosols produced over the continents, as well as aerosols emitted by volcanoes and ship traffic, a large part of it being deposited to the ocean surface by dry and wet deposition. The SSA sources, chemical composition and ensuing physical and optical effects, are discussed. An overview is presented of continental sources and their ageing and mixing processes during transport. The current status of our knowledge on effects of marine aerosols on the Earth radiative balance, both direct by their interaction with solar radiation and indirect through their effects on cloud properties, is discussed. The deposition on the ocean surface of some key species, such as nutrients, their bioavailability and how they impact biogeochemical cycles are shown and discussed through different time and space scales approaches.

show abstract

Enhancement of marine cloud albedo via controlled sea spray injections: a global model study of the influence of emission rates, microphysics and transport

Cited by 62 publications

References 42 publications

Marine cloud brightening – as effective without clouds

Marine cloud brightening – as effective without clouds

Modelling artificial sea salt emission in large eddy simulations

Ocean–Atmosphere Interactions of Particles

Contact Info

Product

Resources

About