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Environmental Earth Sciences
Erschienen in: Environmental Earth Sciences 4/2012

01.06.2012 | Original Article

Assessing spatial uncertainty in mapping soil erodibility factor using geostatistical stochastic simulation

verfasst von: G. Buttafuoco, M. Conforti, P. P. C. Aucelli, G. Robustelli, F. Scarciglia

Erschienen in: Environmental Earth Sciences | Ausgabe 4/2012

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Abstract

Soil erosion is one of most widespread process of degradation. The erodibility of a soil is a measure of its susceptibility to erosion and depends on many soil properties. Soil erodibility factor varies greatly over space and is commonly estimated using the revised universal soil loss equation. Neglecting information about estimation uncertainty may lead to improper decision-making. One geostatistical approach to spatial analysis is sequential Gaussian simulation, which draws alternative, equally probable, joint realizations of a regionalised variable. Differences between the realizations provide a measure of spatial uncertainty and allow us to carry out an error analysis. The objective of this paper was to assess the model output error of soil erodibility resulting from the uncertainties in the input attributes (texture and organic matter). The study area covers about 30 km2 (Calabria, southern Italy). Topsoil samples were collected at 175 locations within the study area in 2006 and the main chemical and physical soil properties were determined. As soil textural size fractions are compositional data, the additive-logratio (alr) transformation was used to remove the non-negativity and constant-sum constraints on compositional variables. A Monte Carlo analysis was performed, which consisted of drawing a large number (500) of identically distributed input attributes from the multivariable joint probability distribution function. We incorporated spatial cross-correlation information through joint sequential Gaussian simulation, because model inputs were spatially correlated. The erodibility model was then estimated for each set of the 500 joint realisations of the input variables and the ensemble of the model outputs was used to infer the erodibility probability distribution function. This approach has also allowed for delineating the areas characterised by greater uncertainty and then to suggest efficient supplementary sampling strategies for further improving the precision of K value predictions.
Vorheriger Artikel Natural and artificial recharge investigation in the Zéroud Basin, Central Tunisia: impact of Sidi Saad Dam storage
Nächster Artikel Groundwater nitrate contamination and risk assessment in an agricultural area, South Korea

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Literatur
Agassi M (1996) Soil erosion, conservation, and rehabilitation. Marcel Dekker Inc., New York
Aitchison J (1982) The statistical analysis of compositional data (with discussion). J R Stat Soc B 44:139–177
Aitchison J (1984) The statistical analysis of geochemical compositions. Math Geol 16:531–564CrossRef
Aitchison J (1986) The statistical analysis of compositional data. Chapman and Hall, Ltd, LondonCrossRef
Aitchison J (1994) Principles of compositional data analysis. In: Anderson TW, Olkin I, Fang K (eds) Multivariate analysis and its applications. Institute of Mathematical Statistics, Hayward, pp 73–81
ARSSA (2003) I suoli della Calabria. Carta dei suoli in scala 1:250000 della Regione Calabria, Monografia divulgativa, ARSSA-Agenzia Regionale per lo Sviluppo e per i Servizi in Agricoltura, Servizio Agropedologia, Rubbettino, Soveria Mannelli (CZ), Italy, pp 387
Bleines C, Deraisme J, Geoffrey F, Jeannée N, Perseval S, Rambert F, Renard D, Torres O, Touffait Y (2008) Isatis Software Manual, 10th edn. Géovariances & Ecole des Mines de Paris, Avon
Burrough PA (2001) GIS and geostatistics: essential partners for spatial analysis. Environ Ecol Stat 8:361–377CrossRef
Calcaterra D, Parise M (2010) Weathering in the crystalline rocks of Calabria, Italy, and relationships to landslides. In: Calcaterra D, Parise M (eds) Weathering as predisposing factor to slope movements. Geological Society of London, Engineering Geology Series, Special Publication 2
Castrignanò A, Buttafuoco G (2004) Geostatistical stochastic simulation of soil water content in a forested area of South Italy. Biosyst Eng 87:257–266CrossRef
Castrignanò A, Buttafuoco G, Canu A, Zucca C, Madrau S (2008) Modelling spatial uncertainty of soil erodibility factor using joint stochastic simulation. Land Degrad Dev 19:198–213CrossRef
Chilès JP, Delfiner P (1999) Geostatistics: modelling spatial uncertainty. Wiley, New YorkCrossRef
Conforti M (2009) Studio geomorfopedologico dei processi erosivi nel bacino del T. Turbolo (Calabria settentrionale) con il contributo della spettrometria della riflettenza. PhD Thesis, University of Calabria, Italy, pp 310
Davis JC (1986) Statistics and data analysis in Geology, 2nd edn. Wiley, New York, pp 107–148
Deutsch CV, Journel AG (1998) GSLIB: Geostatistical Software Library and User’s Guide. Oxford University Press, New York
Faulkner H, Spivey D, Alexander R (2000) The role of some site geochemical processes in the development and stabilisation of three badland sites in Almeria, Southern Spain. Geomorphology 35:87–99CrossRef
Gomez-Hernandez JJ, Journel AG (1992) Joint sequential simulation of multigaussian fields. In: Soares A (ed) Geostatistics Troia 1992, vol I. Kluwer Academic Publishers, Dordrecht, pp 85–94
Goovaerts P (1997) Geostatistics for natural resources evaluation. Oxford University Press, New York
Goovaerts P (1994) Study of spatial relationships between two sets of variables using multivariate geostatistics. Geoderma 62:93–107CrossRef
Heuvelink GBM (1998) Error propagation in environmental modelling with GIS. Taylor and Francis, London
Heuvelink GBM, Pebesma EJ (1999) Spatial aggregation and soil process modelling. Geoderma 89:47–65CrossRef
Hudson N (1995) Soil conservation. Iowa State University Press, Ames
Isaaks EH, Srivastava RM (1989) Applied geostatistics. Oxford University Press, New York
Jansen MJW (1998) Prediction error through modelling concepts and uncertainty from basic data. Nutr Cycl Agroecosyst 50:247–253CrossRef
Journel AG (1983) Non-parametric estimation of spatial distributions. Math Geol 15:445–468CrossRef
Journel AG, Huijbregts CJ (1978) Mining geostatistics. Academic Press, New York
Journel AG, Alabert F (1989) Non-Gaussian data expansion in the earth sciences. Terra Nova 1:123–134CrossRef
Köppen W (1936) Das geographische System der Klimate. In: Köppen W, Geiger R (eds) Handbuch der Klimatologie. Band 5, Teil C. Gebrüder Bornträger, Berlin, pp 1–46
Lanzafame G, Zuffa G (1976) Geologia e petrografia del foglio Bisignano (Bacino del Crati, Calabria). Geol Rom 15:223–270
Lark RM, Bishop TFA (2007) Cokriging particle size fractions of the soil. Eur J Soil Sci 58:763–774CrossRef
Lewis PAW, Orav EJ (1989) Simulation methodology for statisticians, operations analysts, and engineers, vol. 1. Wadsworth Publ. Co, Belmont
McBratney AB, De Gruijter JJ, Brus DJ (1992) Spacial prediction and mapping of continuous soil classes. Geoderma 54:39–64CrossRef
Morgan RPC (2005) Soil erosion and conservation, 3rd edn. Wiley, New York
Pagliai M (ed) (1997) Metodi di Analisi Fisica del Suolo, Ministero per le Politiche Agricole e Forestali. Franco Angeli, Milan
Parysow P, Wang GX, Gertner G, Anderson AB (2003) Spatial uncertainty analysis for mapping soil erodibility based on joint sequential simulation. Catena 53:65–78CrossRef
Pawlowsky-Glahn V, Burger H (1992) Spatial structure analysis of regionalised compositions. Math Geol 24:675–691CrossRef
Pawlowsky-Glahn V, Egozcue JJ (2006) Compositional data and their analysis: an introduction. In: Buccianti A, Mateu-Figueras G, Pawlowsky-Glahn V (eds) Compositional data analysis in the geosciences: from theory to practice, Special Publications 264. Geological Society, London, pp 1–10
Pulice I, Scarciglia F, Leonardi L, Robustelli G, Conforti M, Cuscino M, Lupiano V, Critelli S (2009) Studio multidisciplinare di forme e processi denudazionali nell’area di Vrica (Calabria orientale). Bollettino della Società Geografica Italiana, vol 87, no I–II, pp 403–417
Renard KG, Foster GR, Weesies GA, Mccool DK, Yoder DC (1997) Predicting soil erosion by water: a guide to conservation planning with the revised soil loss equation (RUSLE). U.S. Dept. of Agriculture. Agric. Handbook No. 703, p 404
Shirazi MA, Boersma L, Hart JW (1988) A unifying quantitative analysis of soil texture: improvement of precision and extension of scale. Soil Sci Soc Am J 52:181–190CrossRef
Singh MJ, Khera KL (2009) Nomographic estimation and evaluation of soil erodibility under simulated and natural rainfall conditions. Land Degrad Dev 20:471–480
Soil Survey Staff (2010) Keys to soil taxonomy, 11th edn. USDA-Natural Resources Conservation Service, Washington, DC, p 338
Terranova O, Antronico L, Coscarelli R, Iaquinta P (2009) Soil erosion risk scenarios in the Mediterranean environment using RUSLE and GIS: an application model for Calabria (southern Italy). Geomorphology 112:228–245CrossRef
Terranova O, Catalano E, Langellotti M, Sorriso-Valvo M (1989) Individuazione dei parametri caratterizzanti i fenomeni idraulici ed erosivi di un piccolo bacino (T. Turbolo-Calabria). In: Proceedings of the 1st Workshop on Informatica e Scienze della Terra, October 1989, Sarnano (MC), Italy. Gruppo Informatica Applicata alle Scienze della Terra del CNR, De Frede, Napoli, Italy, pp 32/1–32/22
Tolosana Delgado R (2005) Geostatistics for constrained variables: positive data, compositions and probabilities. Applications to environmental hazard monitoring. PhD Thesis, Universitat de Girona
Tolosana-Delgado R, Otero N, Pawlowsky-Glahn V (2005) Some basic concepts of compositional geometry. Math Geol 37:673–680CrossRef
Torri D, Poesen J, Borselli L (1997) Predictability and uncertainty of the soil erodibility factor using a global dataset. Catena 31:1–22CrossRef
Torri D, Poesen J, Borselli L (2002) Corrigendum to ‘Predictability and uncertainty of the soil erodibility factor using a global dataset’ [Catena 31 (1997) 1–22] and to ‘‘Erratum to Predictability and uncertainty of the soil erodibility factor using a global dataset’’ [Catena 32 (1998) 307–308]. Catena 46:309–310CrossRef
Violante P (ed) (2000) Metodi di Analisi Chimica del Suolo Ministero per le Politiche Agricole e Forestali. Franco Angeli, Milan
Wackernagel H (2003) Multivariate geostatistics: an introduction with applications. Springer, Berlin
Wang G, Gertner GZ, Liu X, Anderson AB (2001) Uncertainty assessment of soil erodibility factor for revised universal soil loss equation. Catena 46:1–14CrossRef
Webster R, Oliver MA (1990) Statistical methods in soil and land resource survey. Oxford University Press, Oxford, pp 291–298
Webster R, Oliver MA (2007) Geostatistics for environmental scientists, 2nd edn. Wiley, ChichesterCrossRef
Wischmeier WH, Smith DD (1978) Predicting rainfall erosion losses. A guide to conservation planning. U.S. Department of Agriculture, Agriculture Handbook No 537, p 58
Metadaten
Titel
Assessing spatial uncertainty in mapping soil erodibility factor using geostatistical stochastic simulation
verfasst von
G. Buttafuoco
M. Conforti
P. P. C. Aucelli
G. Robustelli
F. Scarciglia
Publikationsdatum
01.06.2012
Verlag
Springer-Verlag
Erschienen in
Environmental Earth Sciences / Ausgabe 4/2012
Print ISSN: 1866-6280
Elektronische ISSN: 1866-6299
DOI
https://doi.org/10.1007/s12665-011-1317-0

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