Jamshidi, Reza; Dragovich, Deirdre; Webb, Ashley Adrian

Author(s)

Jamshidi, Reza

Dragovich, Deirdre

Webb, Ashley Adrian

Publication Date

2014

Abstract

Soil erodibility (K) affects sediment delivery to streams and needs to be appropriately quantified and interpolated as a fundamental geographic variable for implementing suitable catchment management and conservation practices. The spatial distribution of K for erosion modelling at non-sampling grid locations has traditionally been estimated using interpolation algorithms such as kriging which do not adequately represent the uncertainty of estimates. These methods cause smoothing effects through overestimating the low values and underestimating the large values. In this study observed values were used to implement a sequential Gaussian simulation (SGS) procedure to evaluate the certainty of modelled data. Soil erodibility values were computed using 41 soil samples taken from the top 10 cm soil layer regularly distributed across four catchments, 367-770 ha in area, within Kangaroo River State forest, New South Wales (NSW). One hundred realisations were applied in the simulation process to provide spatial uncertainty and error estimates of soil erodibility. The results indicated that values simulated by the SGS algorithm produced similar K values for the neighbouring cells. At the pixel level, the SGS approach generated a reliable estimation of soil erodibility in most areas. Spatial variation of the K factor in this study was strongly related to soil landscape differences across the catchments; within catchments slope gradient did not have a substantial impact on the numerical values of the K factor using pixel-by-pixel comparisons of raster grid maps.

Citation

Environmental Earth Sciences, 71(12), p. 4965-4976

ISSN

1866-6299

1866-6280

Link

https://hdl.handle.net/1959.11/15246

Publisher

Springer

Title

Catchment scale geostatistical simulation and uncertainty of soil erodibility using sequential Gaussian simulation

Type of document

Journal Article

Entity Type

Publication

Author(s)	Jamshidi, Reza Dragovich, Deirdre Webb, Ashley Adrian
Publication Date	2014
Abstract	Soil erodibility (K) affects sediment delivery to streams and needs to be appropriately quantified and interpolated as a fundamental geographic variable for implementing suitable catchment management and conservation practices. The spatial distribution of K for erosion modelling at non-sampling grid locations has traditionally been estimated using interpolation algorithms such as kriging which do not adequately represent the uncertainty of estimates. These methods cause smoothing effects through overestimating the low values and underestimating the large values. In this study observed values were used to implement a sequential Gaussian simulation (SGS) procedure to evaluate the certainty of modelled data. Soil erodibility values were computed using 41 soil samples taken from the top 10 cm soil layer regularly distributed across four catchments, 367-770 ha in area, within Kangaroo River State forest, New South Wales (NSW). One hundred realisations were applied in the simulation process to provide spatial uncertainty and error estimates of soil erodibility. The results indicated that values simulated by the SGS algorithm produced similar K values for the neighbouring cells. At the pixel level, the SGS approach generated a reliable estimation of soil erodibility in most areas. Spatial variation of the K factor in this study was strongly related to soil landscape differences across the catchments; within catchments slope gradient did not have a substantial impact on the numerical values of the K factor using pixel-by-pixel comparisons of raster grid maps.
Citation	Environmental Earth Sciences, 71(12), p. 4965-4976
ISSN	1866-6299 1866-6280
Link	https://hdl.handle.net/1959.11/15246
Publisher	Springer
Title	Catchment scale geostatistical simulation and uncertainty of soil erodibility using sequential Gaussian simulation
Type of document	Journal Article
Entity Type	Publication

Catchment scale geostatistical simulation and uncertainty of soil erodibility using sequential Gaussian simulation

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