Investigations of scalar transfer coefficients in fog during the Coupled Boundary Layers and Air Sea Transfer Experiment : a case study

Crofoot, Robert Farrington

doi:10.1575/1912/2065

Cited by 6 publications

(3 citation statements)

References 28 publications

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“…The ABL over the CBLAST region was typically stable during the first half of the summer resulting from the combination of advection and a slowly warming coastal ocean (Crofoot 2004). This is a common occurrence along the East Coast during the late spring and early summer.…”

mentioning

confidence: 99%

The Coupled Boundary Layers and Air–Sea Transfer Experiment in Low Winds

Edson¹,

Crawford²,

Crescenti³

et al. 2007

Bulletin of the American Meteorological Society

170

129

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mentioning

confidence: 99%

The Coupled Boundary Layers and Air–Sea Transfer Experiment in Low Winds

Edson¹,

Crawford²,

Crescenti³

et al. 2007

Bulletin of the American Meteorological Society

170

129

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“…Under weak stable conditions, moisture flux was mostly negative and varied proportionally with sensible heat flux (linear correlation R 2 = 0.68). The observed downward fluxes corresponded to air flows from warmer towards cooler waters upwind the south measuring site and it should be mentioned that downward latent heat fluxes with values one order of magnitude greater have been observed to respond to sea fog events (Crofoot 2004). It is also worth to mention that similar studies of turbulent measurements of moisture under relevant conditions are not often found in the international literature.…”

Section: Surface Heat and Moisture Fluxesmentioning

confidence: 70%

Flux measurements in the surface marine Atmospheric Boundary Layer over the Aegean Sea, Greece

Kostopoulos

Helmis

2014

Science of The Total Environment

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Micro-meteorological measurements within the surface Marine Atmospheric Boundary Layer took place at the shoreline of two islands at northern and south-eastern Aegean Sea of Greece. The primary goal of these experimental campaigns was to study the momentum, heat and humidity fluxes over this part of the north-eastern Mediterranean Sea, characterized by limited spatial and temporal scales which could affect these exchanges at the air-sea interface. The great majority of the obtained records from both sites gave higher values up to factor of two, compared with the estimations from the most widely used parametric formulas that came mostly from measurements over open seas and oceans. Friction velocity values from both campaigns varied within the same range and presented strong correlation with the wind speed at 10 m height while the calculated drag coefficient values at the same height for both sites were found to be constant in relation with the wind speed. Using eddy correlation analysis, the heat flux values were calculated (virtual heat fluxes varied from -60 to 40 W/m(2)) and it was found that they are affected by the limited spatial and temporal scales of the responding air-sea interaction mechanism. Similarly, the humidity fluxes appeared to be strongly influenced by the observed intense spatial heterogeneity of the sea surface temperature.

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“…measurement mast unstable conditions are often present due to cold air advecting above the much warmer ocean, this is consistent with other locations in the North-Sea (Patton et al, 2015;Barthelmie, 1999). However, for the ASIT measurement mast stable conditions do occur often in late spring to early summer when the ocean is slowly warming by warm ocean water flowing over the colder ocean, typically identified with cool summer weather and fog (Edson et al, 2007;Crofoot, 2004). The integrated stability function can be calculated by Eq.…”

mentioning

confidence: 99%

A new roughness parameterization accounting for wind-wave (mis)alignment

Porchetta¹,

Temel²,

Muñoz‐Esparza³

et al. 2018

Preprint

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<p><strong>Abstract.</strong> Two-way feedback occurs between offshore wind and waves. However, the influence of the waves on the wind profile remains remains understudied, in particular the momentum transfer between the sea surface and the atmosphere. Previous studies showed that for swell waves it is possible to have increasing wind speeds in case of aligned wind-wave directions. However, the opposite is valid for opposed wind-wave directions, where a decrease in wind velocity is observed. Up to now, this behavior has not been included in most numerical models due to the lack of an appropriate parameterization of the resulting effective roughness length. Using an extensive data set of offshore measurements in the North Sea and the Atlantic Ocean, we show that the wave roughness affecting the wind is indeed dependent on the alignment between the wind and wave direction. Moreover, we propose a new roughness parameterization taking into account the dependence on alignment, consisting of an enhanced roughness for increasing misalignment. Using this new roughness parameterization in numerical models will facilitate a better representation of offshore wind, which is relevant to many applications including offshore wind energy and climate modeling.</p>

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Investigations of scalar transfer coefficients in fog during the Coupled Boundary Layers and Air Sea Transfer Experiment : a case study

Cited by 6 publications

References 28 publications

The Coupled Boundary Layers and Air–Sea Transfer Experiment in Low Winds

The Coupled Boundary Layers and Air–Sea Transfer Experiment in Low Winds

Flux measurements in the surface marine Atmospheric Boundary Layer over the Aegean Sea, Greece

A new roughness parameterization accounting for wind-wave (mis)alignment

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