论文信息 - THE GLOBALSOILMAP PROJECT: PAST, PRESENT, FUTURE, AND NATIONAL EXAMPLES FROM FRANCE - 字舞流文

THE GLOBALSOILMAP PROJECT: PAST, PRESENT, FUTURE, AND NATIONAL EXAMPLES FROM FRANCE

Soils have critical relevance to global issues, such as food and water security, climate regulation, sustainable energy, desertification and biodiversity protec-tion. As a consequence, soil is becoming one of the top priorities for the global environmental policy agenda. Conventional soil maps suffer from large limita-tions, i.e. most of them are static and often obsolete, are often generated at coarse scale, and can be uneasy to handle. Digital Soil Mapping has been developed as a solution to generate high-resolution maps of soil properties over large areas. Two projects, GlobalSoilMap and SoilGrids, presently aim at delivering the first generation of global, high-resolution soil property fine grids. In this paper, we briefly describe the GlobalSoilMap history, its present status and present achievements, and illustrate some of these with (mainly) French examples. At given moment there is still an enormous potential for forthcoming research and for delivering products more helpful for end users. Key here is the continuous progress in available covariates, in their spatial, spectral and temporal coverage and resolution through remote sensing products. All over the world, there is still a very large amount of point soil data still to be rescued and this effort should be pursued and encouraged. Statistically advances are expected by exploring and implementing new models. Especially relevant are spatial-temporal models and contemporary Artificial Intelligence for handling the complex big data. Advances should be made and research efforts are needed on estimating the uncertainties, and even on estimating uncertainties on uncertainties. Attempts to merge different model strategies and products (for instance deriving from different covariates, spatial extents, soil data sources, and models) should be made in order to get the most useful information from each of these predictions, and to identify how controlling factors may change depending on scales.

Cécile Gomez | Alfred E. Hartemink | Neil McKenzie | Pierre Roudier | Dominique Arrouays | Anne C. Richer-de-Forges | Alex B. McBratney | Budiman Minasny | Igor Savin | Mike Grundy | J.G.B. Leenaars | Laura Poggio | Zamir Libohova | H. van den Bosch | Bas Kempen | V. L. Mulder | Marine Lacoste | Songchao Chen | Nicolas P.A. Saby | Manuel P. Martin | M. Román Dobarco | Isabelle Cousin | Thomas Loiseau | S. Lehmann | M. Caubet | Blandine Lemercier | Christian Walter | Emmanuelle Vaudour | Guillaume Martelet | Pavel Krasilnikov | Philippe Lagacherie | C. Gomez | B. Minasny | L. Poggio | Z. Libohova | A. Hartemink | C. Walter | B. Kempen | E. Vaudour | M. Grundy | J. Leenaars | P. Lagacherie | D. Arrouays | M. Lacoste | B. Lemercier | S. Lehmann | A. Richer-de-Forges | P. Krasilnikov | I. Cousin | P. Roudier | G. Martelet | N. Saby | M. Caubet | M. Román Dobarco | T. Loiseau | N. Mckenzie | H. van den Bosch | S. Chen | A. Mcbratney | I. Savin | M. P. Martín

[1] Philippe Lagacherie,et al. Using quantile regression forest to estimate uncertainty of digital soil mapping products , 2017 .

[2] Sabine Grunwald,et al. Digital Soil Mapping and Modeling at Continental Scales: Finding Solutions for Global Issues , 2011 .

[3] Dominique Arrouays,et al. Evaluating large-extent spatial modeling approaches: A case study for soil depth for France , 2016 .

[4] Dominique Arrouays,et al. First evidence of large-scale PAH trends in French soils , 2013, Environmental Chemistry Letters.

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

[6] Dominique Arrouays,et al. GlobalSoilMap France: High-resolution spatial modelling the soils of France up to two meter depth. , 2016, The Science of the total environment.

[7] Ciro Gardi,et al. Continuous Mapping of Soil pH Using Digital Soil Mapping Approach in Europe , 2012 .

[8] C. Ballabio,et al. Mapping topsoil physical properties at European scale using the LUCAS database , 2016 .

[9] Dominique Arrouays,et al. Merging country, continental and global predictions of soil texture: Lessons from ensemble modelling in France , 2019, Geoderma.

[10] Philippe Lagacherie,et al. Sensitivity of clay content prediction to spectral configuration of VNIR/SWIR imaging data, from multispectral to hyperspectral scenarios , 2018 .

[11] A. McBratney,et al. The dimensions of soil security , 2014 .

[12] Emmanuelle Vaudour,et al. Geostatistical mapping of topsoil organic carbon and uncertainty assessment in Western Paris croplands (France) , 2017 .

[13] Dominique Arrouays,et al. RETRACTED: Soil carbon stocks are underestimated in mountainous regions , 2018, Geoderma.

[14] Budiman Minasny,et al. High‐Resolution 3‐D Mapping of Soil Texture in Denmark , 2013 .

[15] Dominique Arrouays,et al. Building a pedotransfer function for soil bulk density on regional dataset and testing its validity over a larger area , 2018 .

[16] Priyabrata Santra,et al. Digital soil mapping of sand content in arid western India through geostatistical approaches , 2017 .

[17] A. McBratney,et al. A soil science renaissance , 2008 .

[18] Budiman Minasny,et al. Digital soil mapping: A brief history and some lessons , 2016 .

[19] André Beaudoin,et al. Digital mapping of soil properties in Canadian managed forests at 250m of resolution using the k-nearest neighbor method , 2014 .

[20] Philippe Lagacherie,et al. Digital soil mapping across the globe , 2017 .

[21] Luca Montanarella,et al. World's soils are under threat , 2015 .

[22] Dominique Arrouays,et al. GlobalSoilMap : Basis of the global spatial soil information system , 2014 .

[23] Philippe Lagacherie,et al. Prediction of topsoil texture for Region Centre (France) applying model ensemble methods , 2017 .

[24] Gerard B. M. Heuvelink,et al. Soil legacy data rescue via GlobalSoilMap and other international and national initiatives , 2017, GeoResJ.

[25] Alfred E. Hartemink,et al. Predicting soil properties in the tropics , 2011 .

[26] Blandine Lemercier,et al. Spatial disaggregation of complex Soil Map Units at the regional scale based on soil-landscape relationships , 2015 .

[27] Alfred E. Hartemink,et al. Digital Mapping of Soil Particle-Size Fractions for Nigeria Pedology , 2022 .

[28] Alex B. McBratney,et al. Modelling soil attribute depth functions with equal-area quadratic smoothing splines , 1999 .

[29] B. Marchant,et al. A survey of topsoil arsenic and mercury concentrations across France. , 2017, Chemosphere.

[30] Dominique Arrouays,et al. Regional Regolith Parameter Prediction Using the Proxy of Airborne Gamma Ray Spectrometry , 2013 .

[31] Kacem Chehdi,et al. Regional prediction of soil organic carbon content over temperate croplands using visible near-infrared airborne hyperspectral imagery and synchronous field spectra , 2016, Int. J. Appl. Earth Obs. Geoinformation.

[32] David G. Rossiter,et al. Past, present & future of information technology in pedometrics , 2018, Geoderma.

[33] Arwyn Jones,et al. The LUCAS topsoil database and derived information on the regional variability of cropland topsoil properties in the European Union , 2013, Environmental Monitoring and Assessment.

[34] Budiman Minasny,et al. On digital soil mapping , 2003 .

[35] Dominique Arrouays,et al. Quantifying and mapping topsoil inorganic carbon concentrations and stocks: approaches tested in France , 2015 .

[36] P. Lagacherie,et al. How far can the uncertainty on a Digital Soil Map be known?: A numerical experiment using pseudo values of clay content obtained from Vis-SWIR hyperspectral imagery , 2019, Geoderma.

[37] Dominique Arrouays,et al. Explaining and mapping total phosphorus content in French topsoils , 2015 .

[38] J.G.B. Leenaars,et al. Africa Soil Profiles Database (version 1.1) , 2014 .

[39] Dominique Arrouays,et al. Fine resolution map of top- and subsoil carbon sequestration potential in France. , 2018, The Science of the total environment.

[40] D. Sparks,et al. Soil and human security in the 21st century , 2015, Science.

[41] N. Odgers,et al. Fuzzy disaggregation of conventional soil maps using database knowledge extraction to produce soil property maps , 2012 .

[42] David Clifford,et al. The Australian three-dimensional soil grid: Australia’s contribution to the GlobalSoilMap project , 2015 .

[43] G. Heuvelink,et al. SoilGrids1km — Global Soil Information Based on Automated Mapping , 2014, PloS one.

[44] G. Heuvelink,et al. Mapping Soil Properties of Africa at 250 m Resolution: Random Forests Significantly Improve Current Predictions , 2015, PloS one.

[45] Mike Grundy,et al. Soil and landscape grid of Australia. , 2015 .

[46] Wei Sun,et al. Dsmart: An algorithm to spatially disaggregate soil map units , 2014 .

[47] Budiman Minasny,et al. Harmonizing legacy soil data for digital soil mapping in Indonesia , 2013 .

[48] Philippe Lagacherie,et al. Digital soil mapping : an introductory perspective , 2007 .

[49] M. Guevara,et al. Building a national framework for pedometric mapping: Soil depth as an example from Mexico , 2014 .

[50] T. G. Orton,et al. Evaluation of modelling approaches for predicting the spatial distribution of soil organic carbon stocks at the national scale , 2014, 1502.02513.

[51] E. Barriuso,et al. Spatial distribution of Lindane concentration in topsoil across France. , 2013, The Science of the total environment.

[52] Gerard B.M. Heuvelink,et al. Mapping rootable depth and root zone plant-available water holding capacity of the soil of sub-Saharan Africa , 2018, Geoderma.

[53] Scott Smith,et al. Spatial disaggregation of soil map polygons to estimate continuous soil property values at a resolution of 90 m for a pilot study area in Manitoba, Canada , 2014 .

[54] Budiman Minasny,et al. Predicting and mapping soil available water capacity in Korea , 2013, PeerJ.

[55] Isabelle Cousin,et al. Pedotransfer functions for predicting available water capacity in French soils, their applicability domain and associated uncertainty , 2019, Geoderma.