Journal ArticleDOI
A Phenomenological Model for Wind Speed and Shear Stress Profiles in Vegetation Cover Layers
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In this article, a phenomenological model for the mean wind speed and Reynolds shear stress profiles with height in a vegetation cover layer is derived from forms suggested by truncation of the equations of turbulent fluid motion at second order in fluctuating velocity products.Abstract:
A phenomenological model for the mean wind speed and Reynolds shear stress profiles with height in a vegetation cover layer is derived from forms suggested by truncation of the equations of turbulent fluid motion at second order in fluctuating velocity products. The initial formulation is unique in that the force per unit volume resisting fluid motion is treated as a body force having a height-dependent character. The body force is assumed to be proportional to the instantaneous speed squared and in the opposite direction from the instantaneous velocity. Viscous forces are ignored as are all pressure forces except for a steady vertical pressure gradient. Closure of the, equations is effected by a phenomenological assumption linking the static pressure and the square of the mean wind speed. The mean wind speed profile predicted by the model is an exponential in the cumulative drag area per unit planform area as a function of height, which is a simple exponential in height for cover with uniform pl...read more
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Journal ArticleDOI
Urban fluid mechanics : Air circulation and contaminant dispersion in cities
Harindra J. S. Fernando,Sang-Mi Lee,James R. Anderson,Marko Princevac,Eric R. Pardyjak,S. Grossman-Clarke +5 more
TL;DR: In this paper, a new focus area called Urban Fluid Mechanics (UFM) is proposed to address the issues of air and water quality in urban areas, focusing on the physical, biological, chemical, and geological processes at work on urban scales.
Book ChapterDOI
Canopy Transport Processes
TL;DR: In this article, a review of the development and implications of these changes is presented, along with a discussion of the role of gradient-diffusion theory as a description of the turbulent transfer of scalars and momentum in plant canopies.
Journal ArticleDOI
An Analytical one-Dimensional Second-Order Closure Model of Turbulence Statistics and the Lagrangian Time Scale Within and Above Plant Canopies of Arbitrary Structure
William J. Massman,Jeffrey Weil +1 more
TL;DR: In this article, an analytical second-order closure model is developed to describe the within canopy velocity variances, turbulent intensities, dissipation rates, Lagrangian time scale and Lagrangians far field diffusivities for vegetation canopies of arbitrary structure and density.
Journal ArticleDOI
An analytical one-dimensional model of momentum transfer by vegetation of arbitrary structure
TL;DR: In this paper, an analytical one-dimensional model of momentum transfer by vegetation with variable foliage distribution,sheltering and drag coefficient is developed, which relies on a simple parameterization of the ratio of the above-canopy friction velocity, u*, to the wind speed at the top of the canopy,u(h), to predict vegetation roughness length(z0) and displacement height(d) as functions of canopy height (h) and dragarea index.
Journal ArticleDOI
An Investigation of Higher-Order Closure Models for a Forested Canopy
TL;DR: In this paper, the authors examined two parameterization schemes for the triple-velocity correlation tensor employed in higher-order closure models, i.e., gradient-diffusion approximation and full budget for the Triple-Velocity Correlation tensor, in a uniform pine forest.
References
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Book
Boundary layer climates
TL;DR: This modern climatology textbook explains those climates formed near the ground in terms of the cycling of energy and mass through systems.
Book
The Structure of Turbulent Shear Flow
TL;DR: In this paper, the authors present a method to find the optimal set of words for a given sentence in a sentence using the Bibliogr. Index Reference Record created on 2004-09-07, modified on 2016-08-08
Journal ArticleDOI
Momentum absorption by vegetation
TL;DR: In this paper, measurements were made in a wind-tunnel of the drag on elements of a simply-structured artificial crop, and of the wind profiles above and within the crop.
Journal ArticleDOI
A Higher Order Closure Model for Canopy Flow
N. Robert Wilson,Roger H. Shaw +1 more
TL;DR: In this article, the authors developed a non-buoyant mathematical model of air flow within vegetative canopies, consisting of equations for mean horizontal momentum, Reynolds stress, and for the three components of turbulent kinetic energy with closure achieved by parameterizing the higher order terms.