World’s Soil Resources

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Lugato, E., Berti, A. & Giardini, L. 2006. Soil organic carbon (SOC) dynamics with and without residue incorporation in relation to different nitrogen fertilisation rates. Geoderma, 135: 315-321. MacDonald, G. K., Bennett, E. M., Potter, P. A. & Ramankutty, N. 2011. Agronomic phosphorus imbalances across the world's croplands. Proceedings of the National Academy of Sciences of the United States of America, 108(7): 3086-3091. McDowell, R.W., Cox, N., Daughney, C.J., Wheeler, D. & Moreau, M. 2014. A national assessment of the potential linkage between soil, and surface and groundwater concentrations of phosphorus. Journal of the American Water Resources Association. In press. McGill, W.B. 1996. Review and classification of ten soil organic matter (SOM) models In D.S. Powlson, P. Smith and J.U. Smith, eds. Evaluation of soil organic matter models using existing, long-term datasets. pp. 111 -1 32. NATO ASI Series, Global Environmental Change, Vol. 38. Berlin Springer Verlag. Miltner, A., Bombach, P., Schmidt-Brücken, B. & Kästner, M. 2012. Som genesis: Microbial biomass as a significant source. Biogeochemistry, 111: 41-55. Mueller, C.W., Weber, P.K., Kilburn, M.R., Hoeschen, C., Kleber, M. & Pett-Ridge, J. 2013. Advances in the analysis of biogeochemical interfaces: NanoSIMS to investigate soil microenvironments. Advances in Agronomy, 121: 2-39. Nordt, L.C., Wilding, L.P. & Drees, L.R. 2000. Pedogenic carbonate transformations in leaching soil systems: Implications for the global C cycle. In R. Lal, J.M. Kimble, H. Eswaran, & B.A. Stewart, eds. Global Climate Change and Pedogenic Carbonates. pp. 43-64. USA, FL, Boca Raton, Lewis Publishers. Parton, W.J., Schimel, D.S., Cole, C.V. & Ojima, D.S. 1987. Analyses of factors controlling soil organic matter levels in great plain soils. Soil Science Society of America Journal, 51: 1173 -1 179. Paul, E.A. 2014. Soil microbiology, ecology and biochemistry. Academic press. 598 p. Paul, E.A., Follett, R.F., Leavitt, S.W., Halvorson, A., Peterson, G.A. & Lyon, D.J. 1997. Radiocarbon dating for determination of soil organic matter pool sizes and fluxes. Soil Sci.Soc. Amer.J. 61: 1058 -1 067. Paustian, K. 1994. Modelling soil biology and biogeochemical processes for sustainable agriculture research. In C. Pankhurst, B.M. Doube, V.V.S.R. Gupta & P.R. Grace, eds. Management of Soil Biota in Sustainable Farming Systems. pp. 182 -1 96. Melbourne, CSIRO Publ. 262 pp. Paustian, K., Cole, C.V., Sauerbeck, D. & Sampson, N. 1998. CO 2 mitigation by agriculture: An overview. Climatic Change, 40: 135 -1 62. Radajewski, S., Ineson, P., Parekh N.R. & Murrell J.C. 2000. Stable-isotope probing as a tool in microbial ecology. Nature, 403: 646-649. Rasse, D.P., Rumpel, C. & Dignac, M.F. 2005 : Is soil carbon mostly root carbon? Mechanisms for a specific stabilisation. Plant and Soil, 269: 341-356. Robinson, D.A., Fraser, I., Dominati, E.J., Davíðsdóttir, B., Jónsson, J.O.G., Jones, L. Jones, S.B., Tuller, M., Lebron, I., Bristow, K.L., Souza, D.M., Banwart, S. & Clothier, B.E. 2014. On the value of soil resources in the context of natural capital and ecosystem service delivery. Soil Sci. Soc. Am. J. In press. Robinson, D.A., Hockley, N., Cooper, D.M., Emmett, B.A., Keith, A.M., Lebron, I., Reynolds, B., Tipping, E., Tye, A.M., Watts, C.W., Whalley, W.R., Black, H.I.J., Warren, G.P. & Robinson, J.S. 2013. Natural capital and ecosystem services, developing an appropriate soils framework as a basis for valuation. Soil Biology and Biochemistry, 57: 1023 -1 033. Robinson, D.A., Lebron, I. & Vereecken, H. 2009. On the Definition of the Natural Capital of Soils: A Framework for Description, Evaluation, and Monitoring. Soil Sci. Soc. Am. J. 73: 1904 -1 911. Rumpel, C. & Kögel-Knabner, I. 2011. Deep soil organic matter – a key but poorly understood component of terrestrial C cycle. Plant and Soil, 338: 143 -1 58. Status of the World’s Soil Resources | Main Report The role of soils in ecosystem processes 28
Sato, T., Qadir, M., Yamamoto, S., Endo, T. & Zahoor, A. 2013. Global, regional, and country level need for data on wastewater generation, treatment, and use. Agric. Water Manage. 130: 1 -1 3. Scharpenseel, H.W., Becker-Heidmann, P., Neue, H.U. & Tsutsuki, K. 1989. Bomb-carbon, 14 C dating and 13 C measurements as tracers of organic matter dynamics as well as of morphogenetic and turbation processes. The Science of the Total Environment, 81/82: 99 -1 10. Schmidt, M.W.I. & Noack, A.G. 2000. Black carbon in soils and sediments: Analysis, distribution, implications, and current challenges. Global Biogeochemical Cycles, 14: 777-793. Schmidt, M.W.I., Torn, M.S., Abiven, S., Dittmar, T., Guggenberger, G., Janssens, I.A., Kleber, M., Kogel- Knaber, I., Lehmann, J., Manning, D.A.C., Nannipieri, P., Rasse, D.P., Weiner, S. & Trumbore, S.E. 2011. Persistence of soil organic matter as an ecosystem property. Nature, 478: 49-56. Setälä, H., Bardgett, R. D., Birkhofer, K., Brady, M., Byrne, L., de Ruiter, P. C., de Vries, F. T., Gardi, C., Hedlund, K., Hemerik, L., Hotes, S., Liiri, M., Mortimer, S. R., Pavao-Zuckerman, M., Pouyat, R., Tsiafouli, M. & van der Putten, W. H. 2014. Urban and agricultural soils: conflicts and trade-offs in the optimization of ecosystem services. Urban Ecosyst, 17: 239–253. Six, J., Conant, R.T., Paul, E.A., & Paustian, K. 2002. Stabilization mechanisms of soil organic matter: Implications for C-saturation of soils. Plant and Soil, 241: 155 -1 76. Six, J., Elliott, E.T. & Paustian, K. 2000. Soil microaggregate turnover and microaggregate formation: a mechanism for C sequestration under no-tillage agriculture. Soil Biology and Biochemistry, 32 (14): 2099-2103. Smith, J.U., Smith, P., Monaghan, R. & MacDonald, J. 2002. When is a measured soil organic matter fraction equivalent to a model pool? European Journal of Soil Science, 53: 405-416. Smith, P., Ashmore, M., Black, H., Burgess, P.J., Evans, C., Quine, T., Thomson, A.M., Hicks, K. & Orr, H. 2013. The role of ecosystems and their management in regulating climate, and soil, water and air quality. Journal of Applied Ecology, 50: 812-829. Smith, P., Martino, D., Cai, Z., Gwary, D., Janzen, H.H., Kumar, P., McCarl ,B., Ogle, S., O’Mara, F., Rice, C., Scholes, R.J., Sirotenko, O., Howden, M., McAllister, T., Pan, G., Romanenkov, V., Schneider, U., Towprayoon, S., Wattenbach, M. & Smith, J.U. 2007. Greenhouse gas mitigation in agriculture. Philosophical Transactions of the Royal Society, B., 363: 789-813. Smith, P., Smith, J.U., Powlson, D.S., McGill, W.B., Arah, J.R.M., Chertov, O.G., Coleman, K., Franko, U., Frolking, S., Jenkinson, D.S., Jensen, L.S., Kelly, R.H., Klein-Gunnewiek, H., Komarov, A.S., Li, C., Molina, J.A.E., Mueller, T., Parton, W.J., Thornley, J.H.M. & Whitmore, A.P., 1997. A comparison of the performance of nine soil organic matter models using datasets from seven long-term experiments. Geoderma 81: 153-225. Sollins, P., Homann, P. & Caldwell, B.A. 1996. Stabilization and destabilization of soil organic matter: mechanisms and controls. Geoderma, 74: 65 -1 05. Sparling, G.S., Cheschire, M.V. & Mundie, C.M. 1982. Effect of barley plants on the decomposition of 14C-labelled soil organic matter. Journal of Soil Science, 33: 89 -1 00. Tarnocai, C., Canadell, J.G., Schuur, E.A.G., Kuhry, P., Mazhitova, G. & Zimov, S. 2009. Soil organic carbon pools in the northern circumpolar permafrost region. Global Biogeochemical Cycles, 23, GB 2023. Thévenot, M., Dignac, M.-F. & Rumpel, C. 2010. Fate of lignins in soils: a review. Soil Biology and Biochemistry, 42: 1200 -1 211. Todd-Brown, K.E.O, Randerson, J.T., Post, W.M., Hoffman, F.M., Tarnocai, C., Schuur, E.A.G. & Allison, S.D. 2013. Causes of variation in soil carbon simulations from CMIP 5 Earth system models and comparison with observations. Biogeosciences, 10: 1717 -1 736. Status of the World’s Soil Resources | Main Report The role of soils in ecosystem processes 29
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Status of the World’s Main Report
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Dick, Warren Dos Santos Baptista, I
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Table of contents Disclaimer and co
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4.1 | Current land cover and land u
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6.5.5 | Responses | 126 6.6 | Soil
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7.7.3 | Soil and drought hazard | 1
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9.5.2 | South Africa | 266 9.6 | Su
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12.3.8 | Soil acidification | 373 1
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14.5.4 | Nutrient imbalance | 464 1
Page 19 and 20: Foreword This document presents the
Page 21 and 22: Preface | Scope of The State of the
Page 23 and 24: Acknowledgments The Status of the W
Page 25 and 26: CACILM CAMRE CAZRI CBD CBM-CFS CCAF
Page 27 and 28: FDNPS FFS FIA FSI FSR GAP GDP GEF G
Page 29 and 30: LU MA MADRPM MAF MAFF MDBA MDGS MEN
Page 31 and 32: SKM SLAM SLC SLM SMAP SMOS SOC SOE
Page 33 and 34: List of tables Table 1.1 | Chronolo
Page 35 and 36: List of figures Figure 2.1 | Overvi
Page 37 and 38: Figure 6.15 | Factors controlling s
Page 39 and 40: Figure 11.4 | Soil map and soil deg
Page 41 and 42: colored diaper associated with micr
Page 43 and 44: Preface The main objectives of The
Page 45 and 46: Global soil resources Coordinating
Page 47 and 48: The balance between the supporting
Page 49 and 50: 1.2 | Basic concepts Prior to the 2
Page 51 and 52: Soil functions and ecosystem servic
Page 53 and 54: Climate regulation ∑ Regulation o
Page 55 and 56: 2 | The role of soils in ecosystem
Page 57 and 58: 2.1.2 | Nature and formation of soi
Page 59 and 60: 2.1.4 | Factors influencing soil C
Page 61 and 62: In coming years, human population a
Page 63 and 64: Management practices need to be imp
Page 65 and 66: Another important role of soil wate
Page 67 and 68: The development of molecular techno
Page 69: Fierer, N., Ladau, J., Clemente, J.
Page 73 and 74: 3 | Global Soil Resources 3.1 | The
Page 75 and 76: Fridland’s was the first attempt
Page 77 and 78: Soil management has a considerable
Page 79 and 80: Accumulation of water soluble salts
Page 81 and 82: and increases infiltration, which r
Page 83 and 84: Figure 3.7 Soil suitability for cro
Page 85 and 86: 3.7 | Global assessments of soil ch
Page 87 and 88: 3.7.2 | LADA-GLADIS: the ecosystem
Page 89 and 90: References AFES. 2008. Réferentiel
Page 91 and 92: Neustuev, S.S. 1931. Elements of So
Page 93 and 94: 75% crops Mixed >50% artificial 50-
Page 95 and 96: or increasing forest areas. Between
Page 97 and 98: Degrading land covers approximately
Page 99 and 100: 70 60 (A) soil carbon 50 Soil
Page 101 and 102: A meta-analysis of 57 publications
Page 103 and 104: the nutrient inputs remain in the c
Page 105 and 106: Livestock density Livestock product
Page 107 and 108: 4.3.3 | Land use change resulting i
Page 109 and 110: Impact of land take Land take, by i
Page 111 and 112: Photo by F. Macias Photo by J.C. Fe
Page 113 and 114: The formation of sulfidic material
Page 115 and 116: are however strongly dependent on t
Page 117 and 118: Figure 4.10 Global distribution of
Page 119 and 120: Bardgett, R.D. & van der Putten, W.
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Dentener, F., Drevet, J., Lamarque,
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Hettelingh, J.P., Sliggers, J., van
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Magnani, F., Mencuccini, M., Borghe
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Pugh, T.A.M., Arneth, A., Olin, S.,
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Van Aardenne, J.A., Dentener, F.J.,
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5 | Drivers of global soil change D
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5.1.2 | Urbanization In tandem with
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Large areas of arable land have bee
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most affected zone with 15 million
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(Brito et al., 2005). This has impl
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MA. 2005. Ecosystems and Human Well
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6.1.2 | Status of Soil Erosion Over
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Figure 6.2 Location of active and f
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High soil erosion rates will also h
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Near-surface soil water content has
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6.2 | Global soil organic carbon st
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where the drainage in the 1960’s
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6.2.4 | Spatial distribution of car
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Vegetation Classes Topsoil Subsoil
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Soil Order Historic Area 10 6 ha Pr
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6.3 | Soil contamination status and
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and Uruguay. The number of exposed
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products increase soil acidity (Bar
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availability and inhibit plant grow
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In several Asian countries, a blend
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underlines the need for global-scal
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Figure 6.10 Urbanisation of the bes
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Figure 6.11 Major components of the
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Within the same continent, large va
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Box 6.2 | Nutrient balances in urba
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is among the top options in the por
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The quality of the soil’s water i
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At continental scales, the only pra
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Figure 6.16 (a) Global distribution
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Engineering in Japan, 5: 157-174. A
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Chadwick, D., Sommer, S., Thorman,
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Drechsel, Pay, Giordano, Mark, Gyie
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Gardner, T., Acosta-Martinez, V., C
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Hue, N.V. & Licudine, D.L. 1999. Am
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Liski, J., Ilvesniemi, H., Mäkelä
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Ng, H. 2010. Regional Assessment: S
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Reheis, M. 1997. Dust deposition do
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Smith, K.A., McTaggart, I.P. & Tsur
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United Nations. 2008. World Urbaniz
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Wood, M.K. & Blackburn, W.H. 1984.
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7 | The impact of soil change on ec
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Rockström et al. (2009) suggest we
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0.0 Response 1.0 Water quality Soil
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One approach to maintaining soil he
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Author Database Used Extent Estimat
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salinization. Safe design and opera
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The second limitation to prediction
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Figure 7.6 Some soil-related feedba
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soils occurs on largely unmanaged a
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extremes several weeks in advance (
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The direct effect of aerosols on th
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capacity declines as N loads increa
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The concept of the critical load of
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as it indicates that management and
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10-year frequency Ten-year frequenc
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phenomena such as the onset of mass
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Although poorly explored, diversity
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affect the health of humans and ani
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Bever, J.D., Westover, K.M. & Anton
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Damoah, R., Spichtinger, N., Servra
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Fenn, M.E., Poth, M.A., Aber, J.D.,
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Heimann, M. & Reichstein, M. 2008.
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Koster, R.D., Dirmeyer, P.A., Guo,
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Naeem, S., Bunker, D.E., Hector, A.
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Raufman, Y.J. & Fraser, R.S. 1997.
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Sheffield, J. & Wood, E.F. 2007. Pr
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UNEP. 2012. Policy Implications of
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8 | Governance and policy responses
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contemporary challenge for policy m
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Year 1982 FAO World Soil Charter 19
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Ensure integrated management of pes
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8.4 | Regional soil policies 8.4.1
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while in areas with fertile soils t
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In New Zealand, there are few regul
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The SEEA Central Framework identifi
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EC. 2013. Decision No 1386/2013/EU
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World Bank. 2011. Rising Global Int
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9.1 | Introduction Land degradation
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Figure 9.1 Agro-ecological zones in
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The soils are strongly weathered an
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It exposes the soil to the erosive
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In many African cultures, harvestin
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Maputo accounts for 83 percent of t
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Poverty: General poverty of the far
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Considering that over 80 percent of
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Extent of SOM decline in the region
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Many farmers do not follow recommen
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9.5 | Case studies 9.5.1 | Senegal
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Figure 9.7 Extent of dominant degra
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management, it is important to note
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From 2006, several further national
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Figure 9.12 Actual water erosion pr
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Figure 9.13 Topsoil pH derived from
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Figure 9.14 Change in land-cover be
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Waterlogging Compaction Soil sealin
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Birru, T.C. 2002. Organic matter re
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Hein, L. & De Ridder, N. 2006. Dese
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Meyer, J.H., Harding, R., Rampersad
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Smith P. 2008. Soil organic carbon
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10 | Regional Assessment of Soil Ch
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Figure 10.1 Length of the available
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Figure 10.2 Threats to soils in the
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10.3.4 | Soil acidification There i
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In paddy rice cultivation and uplan
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10.3.10 | Sealing and capping Seali
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practices. On low slopes, agronomic
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(Valentin et al., 2008). For peatla
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in Laos (59 kg N ha -1 ). On the ot
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Sub-Regions. Inceptisols are the do
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10.5.2 | Case study for Indonesia T
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Peat fire is another important proc
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An agricultural soil monitoring pro
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The Basic Soil-Environmental Monito
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Figure 10.8 Estimate CH 4 emission
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Threat to soil function Soil erosio
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References Aggarwal, G.C., Sidhu, A
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FAO. 2012. FAOSTAT. Rome, FAO. (Als
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Kukal, S.S. & Aggarwal, G.C. 2003.
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Piao, S., Fang, J., Ciais, P., Peyl
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Taniyama, I. 2003. Study of soil fa
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Zhao, Y., Duan, L., Xing, J., Larss
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11.1 | Introduction The majority of
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The internal stratification within
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Mediterranean zone This zone by def
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(5) Salinization and sodification I
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The real extent of diffuse soil con
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While there is no harmonised exhaus
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Prepared by I. Alyabina Figure 11.2
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This is due to the country’s geo-
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Future changes in climate and land
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Considering an increase of industri
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Comparison of cultivated soils with
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Figure 11.3 Some types and extent o
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The plains in the basins of Amu Dar
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Threat to soil function Soil sealin
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References Acosta, J.A., Faz, A., J
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Inisheva, L.I. (ed.). 2005. Concept
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van Lynden, G.W.J. 1997. Guidelines
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12.1 | Introduction This chapter di
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Figure 12.1 Biomes in Latin America
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Temperate Grasslands, Savannahs and
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humid. The most common soil groups
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12.3.6 | Compaction In LAC there ar
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New regional information has been g
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Primary forests have higher carbon
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Prepared by C. Cruz-Gaistardo Figur
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The salinity of soils on the cultiv
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Figure 12.6 Expansion of the agricu
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Figure 12.7 Percentage of areas aff
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Figure 12.8 Predominant types of la
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Boddey, R.M., Alves, B.J.R, Jantali
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Gardi, C., Angelini, M., Barceló,
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Nogueira, M.A., Albino, U.B., Brand
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Spavorek, G., Bemdes, G., Barreto,
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13 | Regional Assessment of Soil Ch
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The Arab Centre for the Study of Ar
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Poverty within this system is exten
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Wind erosion A review conducted by
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13.3.5 | Soil salinization/sodifica
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13.3.9 | Compaction Soil compaction
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13.4 | Major soil threats in the re
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In Sudan, studies showed that in ar
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2002). There are few studies on the
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Consequences of salinization Salini
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Rates of C change are influenced no
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Figure 13.3 Layout of the project s
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13.5 | Case studies 13.5.1 | Case s
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Studies show that both climatic and
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2 - Land degradation assessment map
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Figure 13.9 Type of ecosystem servi
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References Abahussain, A.A., Abdu,
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Badraoui, M. 1998. Effects of inten
Page 479 and 480:
FAO. 2004. Regional Workshop on Pro
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Mamdouh Nasr. 1999. Assessing Deser
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Yaghi, B. & Abdul-Wahab, S.A. 2004.
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14.1 | Introduction Although Canada
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The area of forested land in Canada
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14.3 | Soil threats This section fo
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Figure 14.2 Map of Superfund sites
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Figure 14.3 Areas in United States
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The drivers for soil sealing in Can
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14.4.1 | Soil erosion Soil erosion
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The relationship between soil prope
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14.4.4 | Soil biodiversity Soil bio
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Figure 14.5 Risk of water erosion i
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Figure 14.7 Soil organic carbon cha
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Figure 14.8 Residual soil N in Cana
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14.6 | Conclusions and recommendati
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Compaction Sealing and land take Sa
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Clearwater, R.L., Martin, T., Hoppe
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Kurz, W.A., Dymond, C.C., White, T.
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USDA. 2011. Resource Conservation A
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15.1 | Introduction The Southwest P
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of the country. The undulating and
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The broad area of Near Oceania (inc
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Country and land-use driver Implica
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15.5 | Threats to soils in the regi
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egenerating soils. The South Island
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New Zealand The importance of soil
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Fertilizers Impurities in fertilize
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The main onsite effects of acidific
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Saltwater intrusion Saltwater intru
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Phosphorus is naturally deficient a
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Canterbury region. There has been a
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Figure 15.3 (a) Trends in winter ra
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Figure 15.5 Agricultural lime sales
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The management of water is also fun
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The DustWatch network Australia has
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Soil sealing and capping Contaminat
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Bui, E.N., Hancock, G.J. & Wilkinso
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Hartemink, A.E. 1998b. Acidificatio
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Moorehead, A. (ed.). 2011. Forests
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Robertson, M.J., George, R.J., O’
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Wilson, B.R. & Lonergan, V.E. 2013.
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16.1 | Antarctic soils and environm
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16.3 | Response All activities in A
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IAATO. 2014. Tourism statistics. In
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Annex | Soil groups, characteristic
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a Photo by C. Tarnocai b Photo by S
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Figure A 2 (a) An Anthrosol (Plagge
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a Photo by P. Charzyński Figure A
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a Photo by A. Filaretova b Photo by
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Figure A 5 (a) A Leptosol profile i
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a Photo by L. Wilding b Photo by L.
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Figure A 7 (a) A Solonetz profile a
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a Photo by T. Toth b Photo by S. Kh
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Figure A 9 (a) A Podzol profile and
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FERRALSOLS (OXISOLS) Ferralsols (Fi
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NITISOLS (Alfisols, Ultisols, Incep
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PLINTHOSOLS (Plinthic sub-groups) P
Page 595 and 596:
PLANOSOLS (Albaqualfs, Albaquults a
Page 597 and 598:
GLEYSOLS (Aquic suborder and Endoaq
Page 599 and 600:
STAGNOSOLS (Aquic Suborders and Epi
Page 601 and 602:
ANDOSOLS (ANDISOLS) Andosols (Figur
Page 603 and 604:
5 | Soils with accumulation of orga
Page 605 and 606:
KASTANOZEMS (Ustolls and Xerolls) K
Page 607 and 608:
PHAEOZEMS (Udolls and Albolls) Phae
Page 609 and 610:
UMBRISOLS (Umbric Great Group in Aq
Page 611 and 612:
6 | Soils with accumulation of mode
Page 613 and 614:
CALCISOLS (Calcids, Argids, Cambids
Page 615 and 616:
GYPSISOLS (Gypsids) Gypsisols are c
Page 617 and 618:
7 | Soils with a clay-enriched subs
Page 619 and 620:
ACRISOLS (Kan- great groups of Ulti
Page 621 and 622:
LIXISOLS (Kan - great groups of Alf
Page 623 and 624:
ALISOLS (Ultisols with an argillic
Page 625 and 626:
LUVISOLS (Alfisols with an argillic
Page 627 and 628:
8 | Soils with little or no profile
Page 629 and 630:
REGOSOLS (Orthents) Regisols are th
Page 631 and 632:
ARENOSOLS (Psamments) Arenosols are
Page 633 and 634:
FLUVISOLS (Fluvents, Fluv-Subroups)
Page 635 and 636:
9 | Permanently flooded soils WASSE
Page 637 and 638:
Kastanozems Histosols Gypsisols Gre
Page 639 and 640:
Jones, A., Breuning-Madsen, H., Bro
Page 641 and 642:
Glossary of technical terms Aerobic
Page 643 and 644:
Topsoil: the upper part of a natura
Page 645 and 646:
Broll, Gabrielle Bruulsma, Tom Bunn
Page 647 and 648:
Leys, John Lobb, David Ma, Lin Maci
Page 649:
Urquiaga Caballero, Segundo Urquiza
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World’s Soil Resources

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