Momentum and mass transfers in the surface boundary layer

Pruitt, William O.; Morgan, D. L.; Lourence, F. J.

doi:10.1002/qj.49709942014

Cited by 140 publications

(45 citation statements)

References 22 publications

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“…Other experiments on air temperature (C=T ) and water vapor (C=q) exchange from different geographic regions around the world are also presented for illustration (as symbols). These experiments include the influential Kansas data [4], the data collected in the towns of Kerang and Hay [5] on heat and water vapor exchange in Australia, the data on heat exchange over the Pampas in Brazil [6], the long-term (day-time only) heat exchange data from the Steppe region in Russia [7], the long-term data on heat exchange from the island of Gotland in the Baltic Sea [8], data for water vapor exchange using drag plate (to estimate u * ) and weighing lysimeter (to estimate water vapor fluxes) from University of California Davis, California, USA [9]. pressure, respectively, ρ is the mean air density, ν is the air kinematic viscosity, D m is the molecular diffusivity of scalar C in air, u ′ i = (u ′ , v ′ , w ′ ) are the componentwise turbulent velocity excursions in direction x i , c ′ is the turbulent scalar concentration fluctuation, and unless otherwise stated, primed quantities represent turbulent excursions from the Reynolds-averaged mean state represented by overbar or capital letter symbols.…”

Section: Theorymentioning

confidence: 99%

Mean scalar concentration profile in a sheared and thermally stratified atmospheric surface layer

Katul

Chameki

et al. 2013

Phys. Rev. E

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Using only dimensional considerations, Monin and Obukhov proposed a 'universal' stability correction function φc(ζ) that accounts for distortions caused by thermal stratification to the mean scalar concentration profile in the atmospheric surface layer when the flow is stationary, planar homogeneous, fully turbulent, and lacking any subsidence. For nearly six decades, their analysis provided the basic framework for almost all operational models and data interpretation in the lower atmosphere. However, the canonical shape of φc(ζ) and the departure from the Reynold's analogy continue to defy theoretical explanation. Here, the basic processes governing the scalar-velocity cospectrum, including buoyancy and the scaling laws describing the velocity and temperature spectra, are considered via a simplified co-spectral budget. The solution to this co-spectral budget is then used to derive φc(ζ), thereby establishing a link between the energetics of turbulent velocity and scalar concentration fluctuations and the bulk flow describing the mean scalar concentration profile. The resulting theory explains all the canonical features of φc(ζ), including the onset of power-laws for various stability regimes and their concomitant exponents, as well as the causes of departure from Reynold's analogy.

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Section: Theorymentioning

confidence: 99%

Mean scalar concentration profile in a sheared and thermally stratified atmospheric surface layer

Katul

Chameki

et al. 2013

Phys. Rev. E

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“…That research has generally shown that airflow is logarithmic and enhanced within the boundary layer above the canopy, and exponential and retarded within the canopy (Plate & Quraishi 1964, Cionco 1965, Businger et al 1971, Oliver 1971, Pruitt et al 1973, Businger 1975, Hartog & Shaw 1975, Legg & Monteith 1975, Seginer et al 1976, Raupach & Thom 1981. I adapted these profiles to my model and defined the appropriate parameters for eelgrass canopies.…”

Section: The Modelmentioning

confidence: 99%

Effect of eelgrass Zostera marina canopies on flow and transport

Abdelrhman¹

2003

Mar. Ecol. Prog. Ser.

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Ecological effects of the interaction between submerged aquatic vegetation and currents depend on the plants and their associated organisms as well as the large-scale transport of dissolved and suspended constituents near the canopy. Mathematical models for airflow within plant canopies were adapted to describe water flow through and above meadows of aquatic eelgrass Zostera marina. The resulting model provided the vertical distribution of velocity and shear in a water column within the meadow, and it was developed to automatically conserve flow within the canopy. It was tested and calibrated with data from the laboratory and the field, and it performed adequately. The flow profile was nearly exponential within the canopy and logarithmic above it. The model was used to study how the eelgrass canopy affected the horizontal transport of conservative constituents. The most important finding was that the vertical distribution of a constituent determines whether the canopy will reduce or enhance its transport through the water column. This effect has direct implications for transport of nonconservative constituents such as dissolved oxygen, nutrients, organic carbon, and particulate pollen, larvae, plankton, and detritus. It also has direct implications for biological issues such as vertical distributions of photosynthesis and of recruitment of organisms on blades of grass while they are exposed to varying degrees of currents and shear.

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“…The turbulent transfer coefficient for vapour, KE, could be greater than that for momentum, KM. Pruitt et al (1973) derived the relation of KE=1.13KM (with k= 0.42), and Yasuda and Toya (1988) obtained the result of KE=1.3KM (with k=0.4) based on the careful turbulent and vertical profile measurements conducted at the paddy field after harvest. In the work of Lettau and Davidson (1957), Lettau and Halstead referred to this question.…”

Section: Results Of Simulation and Discussionmentioning

confidence: 99%

Parameterization of Evaporation from a Non-saturated Bare Surface for Application in Numerical Prediction Models

Toya¹,

Yasuda²

1988

Journal of the Meteorological Society of Japan

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Force restore treatment for the prediction of the surface volumetric soil water content proposed by Deardorff (1977) was applied to the precisely measured data of evaporation from the bare surface and soil water content close to the surface. Parameters C1, C2 and wb involved in the force restore method equation were investigated for the Kanto loam at Tsukuba, Japan.The results show that C1 monotonically decreases with an increase of the surface volumetric water content ws, and this relation is similar to that proposed by Deardorff (1978) for the Adelanto loam. The parameter C2 is not related to ws. It is suggested that C2 be taken as about 2 to 4 for the Kanto loam. It is shown that taking the soil water content at the depth of 1cm around 06JST as wb is effective for the further simplification of force restore treatment.Combination of the parameterization by the force restore method with the bulk method for the turbulent flux using the concept of surface moisture availability gives a good prediction of diurnal variations of evaporation and surface soil water content.

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Momentum and mass transfers in the surface boundary layer

Cited by 140 publications

References 22 publications

Mean scalar concentration profile in a sheared and thermally stratified atmospheric surface layer

Mean scalar concentration profile in a sheared and thermally stratified atmospheric surface layer

Effect of eelgrass Zostera marina canopies on flow and transport

Parameterization of Evaporation from a Non-saturated Bare Surface for Application in Numerical Prediction Models

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