Assessment of Soil Degradation by Erosion Based on Analysis of Soil Properties Using Aerial Hyperspectral Images and Ancillary Data, Czech Republic

The assessment of the soil redistribution and real long-term soil degradation due to erosion on agriculture land is still insufficient in spite of being essential for soil conservation policy. Imaging spectroscopy has been recognized as a suitable tool for soil erosion assessment in recent years. In our study, we bring an approach for assessment of soil degradation by erosion by means of determining soil erosion classes representing soils differently influenced by erosion impact. The adopted methods include extensive field sampling, laboratory analysis, predictive modelling of selected soil surface properties using aerial hyperspectral data and the digital elevation model and fuzzy classification. Different multivariate regression techniques (Partial Least Square, Support Vector Machine, Random forest and Artificial neural network) were applied in the predictive modelling of soil properties. The properties with satisfying performance (R2 > 0.5) were used as input data in erosion classes determination by fuzzy C-means classification method. The study was performed at four study sites about 1 km2 large representing the most extensive soil units of the agricultural land in the Czech Republic (Chernozems and Luvisols on loess and Cambisols and Stagnosols on crystalline rocks). The influence of site-specific conditions on prediction of soil properties and classification of erosion classes was assessed. The prediction accuracy (R2) of the best performing models predicting the soil properties varies in range 0.8–0.91 for soil organic carbon content, 0.21–0.67 for sand content, 0.4–0.92 for silt content, 0.38–0.89 for clay content, 0.73–089 for Feox, 0.59–0.78 for Fed and 0.82 for CaCO3. The performance and suitability of different properties for erosion classes’ classification are highly variable at the study sites. Soil organic carbon was the most frequently used as the erosion classes’ predictor, while the textural classes showed lower applicability. The presented approach was successfully applied in Chernozem and Luvisol loess regions where the erosion classes were assessed with a good overall accuracy (82% and 67%, respectively). The model performance in two Cambisol/Stagnosol regions was rather poor (51%–52%). The results showed that the presented method can be directly and with a good performance applied in pedologically and geologically homogeneous areas. The sites with heterogeneous structure of the soil cover and parent material will require more precise local-fitted models and use of further auxiliary information such as terrain or geological data. The future application of presented approach at a regional scale promises to produce valuable data on actual soil degradation by erosion usable for soil conservation policy purposes.

[1]  Bernard Tychon,et al.  Soil organic carbon assessment by field and airborne spectrometry in bare croplands: accounting for soil surface roughness , 2014 .

[2]  S. Inanaga,et al.  Use of remote sensing to map gully erosion along the Atbara River, Sudan , 1999 .

[3]  Margaret A. Goldman,et al.  Wetland Restoration and Creation for Nitrogen Removal: Challenges to Developing a Watershed-Scale Approach in the Chesapeake Bay Coastal Plain , 2015 .

[4]  Prasad S. Thenkabail,et al.  Land Resources Monitoring, Modeling, and Mapping with Remote Sensing , 2015 .

[5]  Budiman Minasny,et al.  A conditioned Latin hypercube method for sampling in the presence of ancillary information , 2006, Comput. Geosci..

[6]  D. Žížala,et al.  Adjusting the CPmax factor in the Universal Soil Loss Equation (USLE): areas in need of soil erosion protection in the Czech Republic , 2016 .

[7]  Tereza Zádorová,et al.  Colluvial soils as a soil organic carbon pool in different soil regions , 2015 .

[8]  Kurt Hornik,et al.  Misc Functions of the Department of Statistics (e1071), TU Wien , 2014 .

[9]  D. Žížala,et al.  Relating Extent of Colluvial Soils to Topographic Derivatives and Soil Variables in a Luvisol Sub-Catchment, Central Bohemia, Czech Republic , 2018 .

[10]  J. Hill,et al.  Using Imaging Spectroscopy to study soil properties , 2009 .

[11]  Jin Zhang,et al.  An overview and comparison of machine-learning techniques for classification purposes in digital soil mapping , 2016 .

[12]  Robert J. A. Jones,et al.  Indicators for pan-European assessment and monitoring of soil erosion by water , 2004 .

[13]  Panos Panagos,et al.  Predicting soil organic carbon content in Cyprus using remote sensing and Earth observation data , 2014, International Conference on Remote Sensing and Geoinformation of Environment.

[14]  B. Šarapatka,et al.  Erosion processes on intensively farmed land in the Czech Republic: comparison of alternative research methods. , 2010 .

[15]  Luca Montanarella,et al.  Soil erosion risk assessment in Europe , 2000 .

[16]  Max Kuhn,et al.  caret: Classification and Regression Training , 2015 .

[17]  Antonio J. Plaza,et al.  Characterization of Soil Erosion Indicators Using Hyperspectral Data From a Mediterranean Rainfed Cultivated Region , 2016, IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing.

[18]  C. Everson,et al.  Surface organic carbon enrichment to explain greater CO2 emissions from short-term no-tilled soils , 2015 .

[19]  A. Atiya,et al.  Learning with Kernels: Support Vector Machines, Regularization, Optimization, and Beyond , 2005, IEEE Transactions on Neural Networks.

[20]  Sabine Chabrillat,et al.  Potential of hyperspectral imagery for the spatial assessment of soil erosion stages in agricultural semi-arid Spain at different scales , 2014, 2014 IEEE Geoscience and Remote Sensing Symposium.

[22]  Shenglu Zhou,et al.  Using hyperspectral reflectance to detect different soil erosion status in the Subtropical Hilly Region of Southern China: a case study of Changting, Fujian Province , 2013, Environmental Earth Sciences.

[23]  Vladimir N. Vapnik,et al.  The Nature of Statistical Learning Theory , 2000, Statistics for Engineering and Information Science.

[24]  Bas van Wesemael,et al.  Soil Organic Carbon Predictions by Airborne Imaging Spectroscopy: Comparing Cross-Validation and Validation , 2012 .

[25]  D. Coffin A METHOD FOR THE DETERMINATION OF FREE IRON IN SOILS AND CLAYS , 1963 .

[26]  Adrian Chappell,et al.  Using on‐nadir spectral reflectance to detect soil surface changes induced by simulated rainfall and wind tunnel abrasion , 2005 .

[27]  Viacheslav I. Adamchuk,et al.  A global spectral library to characterize the world’s soil , 2016 .

[28]  T. Zádorová,et al.  Identification of Neolithic to Modern erosion–sedimentation phases using geochemical approach in a loess covered sub-catchment of South Moravia, Czech Republic , 2013 .

[29]  Thorsten Behrens,et al.  Digital soil mapping using artificial neural networks , 2005 .

[30]  G. Poręba Caesium-137 as a soil erosion tracer: a review , 2006 .

[31]  Bing Zhang,et al.  Application of hyperspectral remote sensing for environment monitoring in mining areas , 2012, Environmental Earth Sciences.

[32]  B. Terhorst The influence of Pleistocene landforms on soil-forming processes and soil distribution in a loess landscape of Baden–Württemberg (south-west Germany) , 2000 .

[33]  Philippe Lagacherie,et al.  Continuum removal versus PLSR method for clay and calcium carbonate content estimation from laboratory and airborne hyperspectral measurements , 2008 .

[34]  Anne-Katrin Mahlein,et al.  Airborne hyperspectral imaging of spatial soil organic carbon heterogeneity at the field-scale , 2012 .

[35]  P. Lagacherie,et al.  Estimation of soil clay and calcium carbonate using laboratory, field and airborne hyperspectral measurements , 2008 .

[36]  L. Hoffmann,et al.  Measuring soil organic carbon in croplands at regional scale using airborne imaging spectroscopy , 2010 .

[37]  Magaly Koch,et al.  FIELD AND IMAGING SPECTROSCOPY TO DETERMINE SOIL DEGRADATION STAGES IN SEMI-ARID TERRESTRIAL ECOSYSTEMS , 2005 .

[38]  R Core Team,et al.  R: A language and environment for statistical computing. , 2014 .

[39]  Anton Vrieling,et al.  Mapping erosion from space , 2007 .

[40]  J. Campbell Remote Sensing of Soils , 2009 .

[41]  J. Hanuš,et al.  POTENTIAL OF AIRBORNE IMAGING SPECTROSCOPY AT CZECHGLOBE , 2016 .

[42]  José A. Martínez-Casasnovas,et al.  A spatial information technology approach for the mapping and quantification of gully erosion , 2003 .

[43]  Antonio J. Plaza,et al.  Spectral characterisation of land surface composition to determine soil erosion within semiarid rainfed cultivated areas , 2012, 2012 IEEE International Geoscience and Remote Sensing Symposium.

[44]  Sabine Grunwald,et al.  Comparison of multivariate methods for inferential modeling of soil carbon using visible/near-infrared spectra , 2008 .

[45]  B. Wesemael,et al.  Prediction of soil organic carbon for different levels of soil moisture using Vis-NIR spectroscopy , 2013 .

[46]  U. Schmidhalter,et al.  High resolution topsoil mapping using hyperspectral image and field data in multivariate regression modeling procedures , 2006 .

[47]  Nello Cristianini,et al.  An Introduction to Support Vector Machines and Other Kernel-based Learning Methods , 2000 .

[48]  R. V. Rossel,et al.  Visible and near infrared spectroscopy in soil science , 2010 .

[49]  W. Mehl,et al.  Land degradation, soil erosion and desertification monitoring in Mediterranean ecosystems , 1995 .

[50]  A. Gholizadeh,et al.  Visible, Near-Infrared, and Mid-Infrared Spectroscopy Applications for Soil Assessment with Emphasis on Soil Organic Matter Content and Quality: State-of-the-Art and Key Issues , 2013, Applied spectroscopy.

[51]  K. Moffett,et al.  Remote Sens , 2015 .

[52]  J. Hill,et al.  Land Degradation and Soil Erosion Mapping in a Mediterranean Ecosystem , 1994 .

[53]  R. V. Rossel,et al.  Using data mining to model and interpret soil diffuse reflectance spectra. , 2010 .

[54]  N. Kuhn,et al.  Temporal Variation of SOC Enrichment from Interrill Erosion over Prolonged Rainfall Simulations , 2013 .

[55]  B. Merz,et al.  Development of relationships between reflectance and erosion modelling: Test site preliminary field spectral analysis , 2003 .

[56]  S. Wold,et al.  PLS-regression: a basic tool of chemometrics , 2001 .

[57]  J. Hill Mapping Complex Patterns of Erosion and Stability in Dry Mediterranean Ecosystems , 2000 .

[58]  Hermann Kaufmann,et al.  Spatially Explicit Estimation of Clay and Organic Carbon Content in Agricultural Soils Using Multi-Annual Imaging Spectroscopy Data , 2012 .

[59]  Naftaly Goldshleger,et al.  Monitoring of agricultural soil degradation by remote-sensing methods: a review , 2013 .

[60]  Shenglu Zhou,et al.  Spectral response of different eroded soils in subtropical china: A case study in Changting County, China , 2014, Journal of Mountain Science.

[61]  Keith D. Shepherd,et al.  Soil Spectroscopy: An Alternative to Wet Chemistry for Soil Monitoring , 2015 .

[62]  Miloslav Janeček Ochrana zemědělské půdy před erozí , 2002 .

[63]  M. Luleva Tracing soil particle movement : towards a spectral approach to spatial monitoring of soil erosion , 2013 .

[64]  Santiago Beguería,et al.  Identification of eroded areas using remote sensing in a badlands landscape on marls in the central Spanish Pyrenees , 2009 .

[65]  V. Prasuhn Soil erosion in the Swiss midlands: Results of a 10-year field survey , 2011 .

[66]  A. Vrieling Satellite remote sensing for water erosion assessment: A review , 2006 .

[67]  Leo Breiman,et al.  Random Forests , 2001, Machine Learning.

[68]  Michael E. Schaepman,et al.  Determining iron content in Mediterranean soils in partly vegetated areas, using spectral reflectance and imaging spectroscopy , 2007, Int. J. Appl. Earth Obs. Geoinformation.

[69]  Yao Li,et al.  Evaluation of the Chinese Fine Spatial Resolution Hyperspectral Satellite TianGong-1 in Urban Land-Cover Classification , 2016, Remote. Sens..

[70]  J. Bezdek,et al.  FCM: The fuzzy c-means clustering algorithm , 1984 .

[71]  R. Evans,et al.  A comparison of estimates of soil erosion made in the field and from photographs , 1991 .

[72]  Renaud Mathieu,et al.  Field‐based and spectral indicators for soil erosion mapping in semi‐arid mediterranean environments (Coastal Cordillera of central Chile) , 2007 .

[73]  V. Chaplot,et al.  Soil carbon losses by sheet erosion: a potentially critical contribution to the global carbon cycle , 2015 .

[74]  T. Zádorová,et al.  Spatial delineation of organic carbon-rich Colluvial soils in Chernozem regions by Terrain analysis , 2011 .

[75]  J. Šimůnek,et al.  Impact of varying soil structure on transport processes in different diagnostic horizons of three soil types. , 2009, Journal of contaminant hydrology.

[76]  H. Kaufmann,et al.  APPLICATION OF HYPERSPECTRAL IMAGING FOR THE QUANTIFICATION OF SURFACE SOIL MOISTURE IN EROSION MONITORING AND MODELLING , 2005 .

[77]  Prasad S. Thenkabail,et al.  Spectral Sensing from Ground to Space in Soil Science: State of the Art, Applications, Potential, and Perspectives , 2018, Remote Sensing Handbook - Three Volume Set.

[78]  A. F. H. Goetz,et al.  Monitoring infiltration rates in semiarid soils using airborne hyperspectral technology , 2004 .

[79]  J. A. M. Demattê,et al.  Detecção de solos erodidos pela avaliação de dados espectrais , 1999 .

[80]  Gabriele Buttafuoco,et al.  Studying the relationship between water-induced soil erosion and soil organic matter using Vis–NIR spectroscopy and geomorphological analysis: A case study in southern Italy , 2013 .

[81]  H. Bork,et al.  Time and scale of gully erosion in the Jedliczny Dol gully system, south-east Poland , 2006 .

[82]  Panos Panagos,et al.  The new assessment of soil loss by water erosion in Europe , 2015 .

[83]  Sabine Chabrillat,et al.  Quantitative Soil Spectroscopy , 2013 .

[84]  Suresh Kumar,et al.  Prediction Modeling and Mapping of Soil Carbon Content Using Artificial Neural Network, Hyperspectral Satellite Data and Field Spectroscopy , 2015 .

[85]  S. Delwiche,et al.  Use of Airborne Hyperspectral Imagery to Map Soil Properties in Tilled Agricultural Fields , 2011 .

[86]  Stefano Pignatti,et al.  A comparison of sensor resolution and calibration strategies for soil texture estimation from hyperspectral remote sensing , 2013 .

[87]  Vladimir Vapnik,et al.  The Nature of Statistical Learning , 1995 .

[88]  D. Nikkami,et al.  Methodologies of preparing erosion features map by using RS and GIS , 2008 .

[89]  P. Lagacherie,et al.  Regional predictions of eight common soil properties and their spatial structures from hyperspectral Vis–NIR data , 2012 .

[90]  A. Savitzky,et al.  Smoothing and Differentiation of Data by Simplified Least Squares Procedures. , 1964 .