Water storage and evaporation as constituents of rainfall interception

Klaassen, Wim; Bosveld, Fred C.; Water, E. De

doi:10.1016/s0022-1694(98)00200-5

Cited by 226 publications

(210 citation statements)

References 43 publications

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“…The values fall within the typical range of 0.5 to 2.5 mm for deciduous canopies and 0.3 to 2.4 mm for coniferous canopies (Whitehead and Kelliher, 1991;Návar and Bryan, 1994;Klaassen et al, 1998;. The storage capacity is assumed to be constant during a single storm, but is probably variable between events (Robin, 2003;Keim, 2004).…”

Section: Canopy Storage Capacitymentioning

confidence: 88%

Modelling and measurement of two-layer-canopy interception losses in a subtropical evergreen forest of central-south China

Zhang

Zeng

Jiang

et al. 2006

Hydrol. Earth Syst. Sci.

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Abstract.The original Gash analytical model and the sparse Gash's model were combined to simulate rainfall interception losses from the top-and sub-canopy layers in Shaoshan evergreen forest located in central-south China in 2003. The total estimated interception loss from the two canopy layers was 334.1 mm with an overestimation of 39.8 mm or 13.5% of the total measured interception (294.3 mm). The simulated interception losses of the top-and sub-canopy suggested that the simulated interception losses in the stages of "during storms" and "after storms" were in good agreement with the published ones. Both the original Gash model and the sparse model overestimated the interception losses, but the sparse model gave more accurate estimates than the original Gash model.

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Section: Canopy Storage Capacitymentioning

confidence: 88%

Modelling and measurement of two-layer-canopy interception losses in a subtropical evergreen forest of central-south China

Zhang

Zeng

Jiang

et al. 2006

Hydrol. Earth Syst. Sci.

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“…The parameters b 0 and b 1 results in estimates of the ratio of evaporation to rainfall and S, respectively (Klaassen et al, 1998). Drainage was predicted using the relation between D and C (Bussiere and Cellier, 1994): and because the experiment was conducted in a laboratory environment and wind speed was zero.…”

Section: Estimation Of Model Parametersmentioning

confidence: 99%

Experimental analysis of drainage and water storage of litter layers

Guevara-Escobar

González-Sosa

Ramos-Salinas

et al. 2007

Hydrol. Earth Syst. Sci.

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Abstract. Many hydrological studies of forested ecosystems focus on the study of the forest canopy and have partitioned gross precipitation into throughfall and stemflow. However, the presence of forest litter can alter the quantities of water available for soil infiltration and runoff. Little information exists regarding the value of storage and drainage parameters for litter layers. Vegetation parameters of this kind are required in physically-based and lumped conceptual models to quatify the availabilty and distribution of water. Using a rainfall simulator and laboratory conditions two main objectives were investigated using layers of recently seneced poplar leaves, fresh grass or woodchips: 1) Effect of rain intensity on storage. With this respect we found that: maximum storage (C max ), defined as the detention of water immediately before rainfall cessation, increased with rainfall intensity. The magnitude of the increment was up to 0.5 mm kg −1 m −2 between the lowest (9.8 mm h −1 ) and highest (70.9 mm h −1 ) rainfall intensities for poplar leaves. Minimum storage (C min ), defined as the detention of water after drainage ceased, was not influenced by rainfall intensity. Repeated wetting-draining cycles or layer thickness have no effect on C max or C min .2) The evaluation of drainage coefficient for the Rutter model. This model was found accurate to predict storage and drainage in the case of poplar leaves, was less accurate for fresh grass and resulted in overestimations for woodchips.Additionally, the effect of an underlaying soil matrix on lateral movement of water and storage of poplar leaves was studied. Results indicated that the soil matrix have no effect on C max or C min of the litter layer. Lateral movement of water in the poplar layer was observed at intermediate rainfall intensities (30.2 and 40.4 mm h −1 ), but not a the lowest or highest rates.

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“…The present analysis still suggests to use the common correction (E/EpM ---C/S, equation (6)). A larger correction also results from a decrease in canopy wetness (C/S), which can result from a decrease in C or an increase in S. The maximum storage capacity S is commonly determined indirectly from throughfall measurement and results in an underestimation of S when drainage from the canopy occurs before the canopy is saturated [Klaassen et al, 1998]. Three processes cause drainage before saturation: raindrops splashing on wetted parts [Calder, 1986], slow saturation of barks and undersides of leaves [Herwitz, 1985], and upper leaves sheltering lower leaves.…”

Section: Environmental Control Of Wet Forest Evaporationmentioning

confidence: 99%

“…For dense forest, maximum storage is larger and results in an increase of interception. The realistic simulation of interception of dense forest using the reference model is thus explained by compensation errors, resulting from an overestimation of the evaporation rate and an underestimation of storage [Klaassen et al, 1998]. …”

Section: Environmental Control Of Wet Forest Evaporationmentioning

confidence: 99%

Evaporation From rain‐wetted forest in relation to canopy wetness, canopy cover, and net radiation

Klaassen¹

2001

Water Resources Research

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Abstract. Evaporation from wet canopies is commonly calculated using E pM , the Penman-Monteith equation with zero surface resistance. However, several observations show a lower evaporation from rain-wetted forest. Possible causes for the difference between E pM and experiments are evaluated to provide rules for the simulation of rainfall interception by forest canopies. The evaluation is executed using a micrometeorological model with a detailed representation of the forest canopy. Simulated results are compared with experimental results. In spite of theoretical reservations the evaporation of completely wet forest appears to agree with EpM. Evaporation from wet forest appears mainly dependent on net radiation. Rainfall interception is related to evaporation from the canopy. Evaporation from the canopy appears proportional with the square root of canopy cover and sensitive to canopy wetness. An accurate estimate of canopy wetness is needed to use E pM for the calculation of evaporation from rain-wetted forest.

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Water storage and evaporation as constituents of rainfall interception

Cited by 226 publications

References 43 publications

Modelling and measurement of two-layer-canopy interception losses in a subtropical evergreen forest of central-south China

Modelling and measurement of two-layer-canopy interception losses in a subtropical evergreen forest of central-south China

Experimental analysis of drainage and water storage of litter layers

Evaporation From rain‐wetted forest in relation to canopy wetness, canopy cover, and net radiation

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