Rainsplash As a Mechanism for Soil Contamination of Plant Surfaces

Dreicer, M.; Te, Hakonson; Gc, White; Fw, Whicker

doi:10.1097/00004032-198401000-00015

Cited by 72 publications

(40 citation statements)

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“…Since raindrops have high kinetic energy they might remove many particles by splashing on impact with the leaf surface. Splashing is not only very effective in contaminating surfaces (Dreicer et al, 1984 ;Foster et al, 1985), but might also be an important factor in the removal of particles from smooth surfaces, as has been shown for the dispersal of fungal spores (Gregory, Guthrie & Bunce, 1959 ;Walklate, McCartney & Fitt, 1989). Especially heavy rain occurring during thunderstorms should be very effective in this respect, and might explain reasonably the decrease in contamination of beech leaves in later summer.…”

Section: Wettability and Contaminationmentioning

confidence: 97%

Seasonal changes of leaf surface contamination in beech, oak, and ginkgo in relation to leaf micromorphology and wettability

1998

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The leaf surfaces of beech, oak and ginkgo have been investigated with respect to contamination with particles during one growing season. Based on the observation that particles are removed from water-repellent leaves by rain (Lotus effect) the three species were selected because they differ in leaf surface micromorphology and wettability. Leaves of beech are smooth, lacked wax crystals and were pwettable. Those of ginkgo were rough because their cells were convex and were densely covered by wax crystals, resulting in permanent water repellency. Leaves of oak were covered by waxes and were water repellent when young, but, a few weeks after leaf expansion had ceased the waxes were rapidly eroded. These differences in wettability resulted in different amounts of contamination. Ginkgo collected a very small number of particles during the whole vegetation period. In beech the contamination was significantly higher, but fairly constant, whereas oak leaves accumulated particles with age.

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Section: Wettability and Contaminationmentioning

confidence: 97%

Seasonal changes of leaf surface contamination in beech, oak, and ginkgo in relation to leaf micromorphology and wettability

1998

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“…Dreicer et al (1984) investigated the rain splash pathway for tomato plants and found that only finer soil particles were retained on plant surfaces. The octanol-air partition coefficient (K OA ) has been suggested as a suitable indicator of the significance of the dry deposition contamination pathway for semi-volatile organic chemicals (McLachlan 1999).…”

Section: Particulate Deposition On Plant Surfacesmentioning

confidence: 99%

Plant Uptake of Xenobiotics

Collins

Martín

Doucette

2010

Plant Ecophysiology

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Plant uptake of organic chemicals is an important process when considering the risks associated with land contamination, the role of vegetation in the global cycling of persistent organic pollutants, the potential for contamination of the food chain and the design of pesticides. There have been some significant advances in our understanding of the processes of plant uptake of organic chemicals in recent years; most notably there is now a better understanding of the air to plant transfer pathway, which may be significant for a number of chemicals. This chapter identifies the key processes involved in the plant uptake of organic chemicals and also identifies other important factors in the uptake process e.g., plant lipid content, growth dilution and plant metabolism.

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“…[2] Broad, longstanding interest in rain splash of soil grains as an erosional process [Ellison, 1944;DePloey and Savat, 1968;Carson and Kirkby, 1972;Mosley, 1973;Sharma and Gupta, 1989;Sharma et al, 1991;Erpul et al, 2002Erpul et al, , 2008van Dijk et al, 2002;Gabet and Dunne, 2003;Legout et al, 2005;Furbish et al, 2007] and as a mechanism contributing to transport and dispersal of soil-borne pathogens, contaminants and nutrients [Dreicer et al, 1984;Wainwright et al, 1999;Bock et al, 2005;McGonigle et al, 2005] prompts the need for a unifying, and practical, description of rain splash transport that goes beyond [Dietrich et al, 2003] current semiempirical models. Recent success in clarifying the basic physics of the grain splash process [Furbish et al, 2007] allows us to formulate a description of grain motions, resulting from raindrop impacts, within the stochastic framework of the Master Equation [Risken, 1984].…”

Section: Introductionmentioning

confidence: 99%

“…Recent success in clarifying the basic physics of the grain splash process [Furbish et al, 2007] allows us to formulate a description of grain motions, resulting from raindrop impacts, within the stochastic framework of the Master Equation [Risken, 1984]. The result of this formulation is an advection-dispersion equation that (1) takes into account the highly intermittent activation of soil grains by raindrops; (2) reveals the soil-grain analogue of molecular diffusion; (3) highlights the role of slope-dependent grain drift and distinguishes it from Fick-like diffusion; (4) provides a framework for predicting dispersal of soil-borne substances [Dreicer et al, 1984;Bock et al, 2005;McGonigle et al, 2005]; and (5) clarifies how rain splash contributes to roughening [Jyotsna and Haff, 1997] of desert landscapes in association with variations in vegetation cover [Parsons et al, 1992;Bochet et al, 2000]. The formulation unambiguously clarifies, for the specific case of rain splash transport, the relation between grain-scale motions and the ''diffusion'' of topography as articulated by geomorphologists [Roering et al, 2002].…”

Section: Introductionmentioning

confidence: 99%

Rain splash of soil grains as a stochastic advection‐dispersion process, with implications for desert plant‐soil interactions and land‐surface evolution

et al. 2009

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We formulate soil grain transport by rain splash as a stochastic advection‐dispersion process. By taking into account the intermittency of grain motions activated by raindrop impacts, the formulation indicates that gradients in raindrop intensity, and thus grain activity (the volume of grains in motion per unit area) can be as important as gradients in grain concentration and surface slope in effecting transport. This idea is confirmed by rain splash experiments and manifest in topographic roughening via mound growth beneath desert shrubs. The formulation provides a framework for describing transport and dispersal of any soil material moveable by rain splash, including soil grains, soil‐borne pathogens and nutrients, seeds, or debitage. As such it shows how classic models of topographic “diffusion” reflect effects of slope‐dependent grain drift, not diffusion, and it highlights the role of rain splash in the ecological behavior of desert shrubs as “resource islands.” Specifically, the growth of mounds beneath shrub canopies, where differential rain splash initially causes more grains to be splashed inward beneath the protective canopy than outward, involves the “harvesting” of nearby soil material, including nutrients. Mounds thus represent temporary storage of soil derived from areas surrounding the shrubs. As the inward grain flux associated with differential rain splash is sustained over the shrub lifetime, mound material is effectively sequestered from erosional processes that might otherwise move this material downslope. With shrub death and loss of the protective canopy, differential rain splash vanishes and the mound material is dispersed to the surrounding area, again subject to downslope movement.

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Rainsplash As a Mechanism for Soil Contamination of Plant Surfaces

Cited by 72 publications

References 0 publications

Seasonal changes of leaf surface contamination in beech, oak, and ginkgo in relation to leaf micromorphology and wettability

Seasonal changes of leaf surface contamination in beech, oak, and ginkgo in relation to leaf micromorphology and wettability

Plant Uptake of Xenobiotics

Rain splash of soil grains as a stochastic advection‐dispersion process, with implications for desert plant‐soil interactions and land‐surface evolution

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