LEAFlood: Landscape and vEgetAtion-dependent Flood model (Version 1)

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OriginalspracheEnglisch
PublikationsstatusVeröffentlicht - 30 Mai 2022

Abstract

The LEAFlood model (Landscape and vEgetAtion-dependent Flood model) is based on existing model components of the Catchment Modelling Framework (CMF, Kraft et al., 2011). It is in between a conceptual and physically-based, distributed, deterministic model. LEAFlood considers the hydrological processes of canopy interception, canopy evaporation, throughfall, soil infiltration and surface runoff. The geometry is created on the basis of an irregular polygon shapefile. The model is forced by meteorological data of rainfall, temperature, wind speed, relative humidity and solar radiation. The interception utilizes the Rutter approach. LAI, Interception capacity and canopy closure are required parameters. Depending on the canopy closure, the precipitation can either be intercepted in the canopy or fall directly to the ground. A canopy closure of 1 means all rain is intercepted and 0 indicates 100% throughfall. The soil consists of one soil layer with the Green-Ampt infiltration method and the Brooks-Corey Retention Curve. A multi soil layer approach can be adapted. The saturated conductivity can be set individual for each cell. Further soil defining parameters are the porosity and the saturated depth. The surface runoff follows the kinematic approach based on topography and surface roughness (Manning’s roughness coefficient). First release of LEAFlood in May 2022.

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LEAFlood: Landscape and vEgetAtion-dependent Flood model (Version 1). Wübbelmann, Thea (Autor*in); Förster, Kristian (Autor*in). 2022.

Publikation: Nicht-textuelle MedienSoftwareForschung

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title = "LEAFlood: Landscape and vEgetAtion-dependent Flood model (Version 1)",
abstract = "The LEAFlood model (Landscape and vEgetAtion-dependent Flood model) is based on existing model components of the Catchment Modelling Framework (CMF, Kraft et al., 2011). It is in between a conceptual and physically-based, distributed, deterministic model. LEAFlood considers the hydrological processes of canopy interception, canopy evaporation, throughfall, soil infiltration and surface runoff. The geometry is created on the basis of an irregular polygon shapefile. The model is forced by meteorological data of rainfall, temperature, wind speed, relative humidity and solar radiation. The interception utilizes the Rutter approach. LAI, Interception capacity and canopy closure are required parameters. Depending on the canopy closure, the precipitation can either be intercepted in the canopy or fall directly to the ground. A canopy closure of 1 means all rain is intercepted and 0 indicates 100% throughfall. The soil consists of one soil layer with the Green-Ampt infiltration method and the Brooks-Corey Retention Curve. A multi soil layer approach can be adapted. The saturated conductivity can be set individual for each cell. Further soil defining parameters are the porosity and the saturated depth. The surface runoff follows the kinematic approach based on topography and surface roughness (Manning{\textquoteright}s roughness coefficient). First release of LEAFlood in May 2022.",
author = "Thea W{\"u}bbelmann and Kristian F{\"o}rster",
year = "2022",
month = may,
day = "30",
doi = "10.5281/ZENODO.6594180",
language = "English",

}

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TY - ADVS

T1 - LEAFlood

T2 - Landscape and vEgetAtion-dependent Flood model (Version 1)

AU - Wübbelmann, Thea

AU - Förster, Kristian

PY - 2022/5/30

Y1 - 2022/5/30

N2 - The LEAFlood model (Landscape and vEgetAtion-dependent Flood model) is based on existing model components of the Catchment Modelling Framework (CMF, Kraft et al., 2011). It is in between a conceptual and physically-based, distributed, deterministic model. LEAFlood considers the hydrological processes of canopy interception, canopy evaporation, throughfall, soil infiltration and surface runoff. The geometry is created on the basis of an irregular polygon shapefile. The model is forced by meteorological data of rainfall, temperature, wind speed, relative humidity and solar radiation. The interception utilizes the Rutter approach. LAI, Interception capacity and canopy closure are required parameters. Depending on the canopy closure, the precipitation can either be intercepted in the canopy or fall directly to the ground. A canopy closure of 1 means all rain is intercepted and 0 indicates 100% throughfall. The soil consists of one soil layer with the Green-Ampt infiltration method and the Brooks-Corey Retention Curve. A multi soil layer approach can be adapted. The saturated conductivity can be set individual for each cell. Further soil defining parameters are the porosity and the saturated depth. The surface runoff follows the kinematic approach based on topography and surface roughness (Manning’s roughness coefficient). First release of LEAFlood in May 2022.

AB - The LEAFlood model (Landscape and vEgetAtion-dependent Flood model) is based on existing model components of the Catchment Modelling Framework (CMF, Kraft et al., 2011). It is in between a conceptual and physically-based, distributed, deterministic model. LEAFlood considers the hydrological processes of canopy interception, canopy evaporation, throughfall, soil infiltration and surface runoff. The geometry is created on the basis of an irregular polygon shapefile. The model is forced by meteorological data of rainfall, temperature, wind speed, relative humidity and solar radiation. The interception utilizes the Rutter approach. LAI, Interception capacity and canopy closure are required parameters. Depending on the canopy closure, the precipitation can either be intercepted in the canopy or fall directly to the ground. A canopy closure of 1 means all rain is intercepted and 0 indicates 100% throughfall. The soil consists of one soil layer with the Green-Ampt infiltration method and the Brooks-Corey Retention Curve. A multi soil layer approach can be adapted. The saturated conductivity can be set individual for each cell. Further soil defining parameters are the porosity and the saturated depth. The surface runoff follows the kinematic approach based on topography and surface roughness (Manning’s roughness coefficient). First release of LEAFlood in May 2022.

UR - https://zenodo.org/record/6594180

U2 - 10.5281/ZENODO.6594180

DO - 10.5281/ZENODO.6594180

M3 - Software

ER -

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