John A. Gillies scite author profile

Abstract. Simulations of the dust cycle and its interactions with the changing Earth system are hindered by the empirical nature of dust emission parameterizations in weather and climate models. Here we take a step towards improving dust cycle simulations by using a combination of theory and numerical simulations to derive a physically based dust emission parameterization. Our parameterization is straightforward to implement into large-scale models, as it depends only on the wind friction velocity and the soil's threshold friction velocity. Moreover, it accounts for two processes missing from most existing parameterizations: a soil's increased ability to produce dust under saltation bombardment as it becomes more erodible, and the increased scaling of the dust flux with wind speed as a soil becomes less erodible. Our treatment of both these processes is supported by a compilation of quality-controlled vertical dust flux measurements. Furthermore, our scheme reproduces this measurement compilation with substantially less error than the existing dust flux parameterizations we were able to compare against. A critical insight from both our theory and the measurement compilation is that dust fluxes are substantially more sensitive to the soil's threshold friction velocity than most current schemes account for.

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Effect of vehicle characteristics on unpaved road dust emissions

Gillies

Etyemezian

Kuhns

et al. 2005

Atmospheric Environment

153

136

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Characterizing Mineral Dusts and Other Aerosols from the Middle East—Part 1: Ambient Sampling

Engelbrecht

McDonald

Gillies

et al. 2009

Inhalation Toxicology

199

124

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Representation of vegetation and other nonerodible elements in aeolian shear stress partitioning models for predicting transport threshold

2005

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[1] The presence of nonerodible elements is well understood to be a reducing factor for soil erosion by wind, but the limits of its protection of the surface and erosion threshold prediction are complicated by the varying geometry, spatial organization, and density of the elements. The predictive capabilities of the most recent models for estimating wind driven particle fluxes are reduced because of the poor representation of the effectiveness of vegetation to reduce wind erosion. Two approaches have been taken to account for roughness effects on sediment transport thresholds. Marticorena and Bergametti (1995) in their dust emission model parameterize the effect of roughness on threshold with the assumption that there is a relationship between roughness density and the aerodynamic roughness length of a surface. Raupach et al. (1993) offer a different approach based on physical modeling of wake development behind individual roughness elements and the partition of the surface stress and the total stress over a roughened surface. A comparison between the models shows the partitioning approach to be a good framework to explain the effect of roughness on entrainment of sediment by wind. Both models provided very good agreement for wind tunnel experiments using solid objects on a nonerodible surface. However, the Marticorena and Bergametti (1995) approach displays a scaling dependency when the difference between the roughness length of the surface and the overall roughness length is too great, while the Raupach et al. (1993) model's predictions perform better owing to the incorporation of the roughness geometry and the alterations to the flow they can cause.Citation: King, J., W. G. Nickling, and J. A. Gillies (2005), Representation of vegetation and other nonerodible elements in aeolian shear stress partitioning models for predicting transport threshold,

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Aeolian sediment transport through large patches of roughness in the atmospheric inertial sublayer

Gillies¹,

Nickling²,

King³

2006

J. Geophys. Res.

107

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[1] Roughness influences the flux of wind-driven sand transport. In this paper, we report on sediment transport measurements for four different surface roughness configurations composed of the same size (solid) roughness elements in the atmospheric inertial sublayer. Results of these tests indicate that sediment transport rates through patches of roughness in the atmospheric inertial sublayer are to a large extent controlled and scale proportionally with the roughness density (l = n b h/S, where n is number of elements of breadth b and height h in area S) of the surface. However, element size apparently increases the magnitude of the reduction beyond that attributable to l. A sediment transport model that incorporates the effect of shear stress partitioning appears to predict reasonably well the effect of roughness on sand transport in the cases where the roughness elements are 0.10 m in height. However, when the dimensions of the roughness itself are equivalent to or are greater than the range of saltation lengths (vertical and horizontal), additional interactions of the elements with the saltation cloud appear to reduce the transport efficiency.

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John A. Gillies

An improved dust emission model – Part 1: Model description and comparison against measurements

Effect of vehicle characteristics on unpaved road dust emissions

Characterizing Mineral Dusts and Other Aerosols from the Middle East—Part 1: Ambient Sampling

Representation of vegetation and other nonerodible elements in aeolian shear stress partitioning models for predicting transport threshold

Aeolian sediment transport through large patches of roughness in the atmospheric inertial sublayer

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