Abstract
A number of hypotheses and conceptual models, particularly those emphasizing nonlinear dynamics and self-organization, postulate increases or decreases in complexity in the evolution of drainage basins, topography, soils, ecosystems, and other earth surface systems. Accordingly, it is important to determine under what circumstances and at what scales either trend might occur. This paper is concerned with changes in soil landscape complexity due to redistribution of sediment by fluvial, aeolian, and tillage processes at historical time scales in an agricultural field system near Grifton, North Carolina. Soil mapping and soil stratigraphic investigations were used to identify and map soil changes associated with erosion and deposition by water, wind, and tillage; reconstruct the pre-agricultural soil pattern; and identify transformations between soil types. The Kolmogorov entropy of the pre- and post- agricultural landscapes was then compared. The soil transformations associated with erosion and deposition created four distinct new soils and made possible new transformations among soil series, increasing the number of soil types from seven to 11 and the number of possible transformations from 14 to 22. However, the entropy and complexity of the soil landscape decreased, with associated increases in information and redundancy. The mass redistributions created a lower-entropy landscape by concentrating particular soils and soil transformations in specific landscape settings. This result is contrary to studies showing a trend toward increasing pedological complexity at comparable spatial scales, but over much longer time scales. These results point to the importance of temporal scale, and to the fact that environmental complexity is influenced by factors other than the number of different landscape units present.
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References
Brooks, D.R. and Wiley, E.O. 1988. Evolution as Entropy. 2nd Edition. University of Chicago Press, Chicago.
Burrough, P.A. 1983. Multiscale sources of spatial variation in soils. J Soil Sci 34: 577–620.
Campbell, J.B. 1979. Spatial variability of soils. Ann. Assoc Am Geog 69: 544–556.
Carter, R.W.G. and Orford, J. 1991. The sedimentary organisation and behavior of drift-aligned barriers. In Coastal Sediments' 91. pp. 934–948. American Society of Civil Engineers, New York.
Culling, W.E.H. 1988. Dimension and entropy in the soil-covered landscape. Earth Surface Proc Landforms 13: 619–648.
Fullen, M.A. & Brandsma, R.T. 1995. Property changes by erosion of loamy sand soils in East Shropshire, U.K. Soil Technol 8: 1–15.
Hallet, B. 1990. Spatial self-organization in geomorphology: From periodic bedforms and patterned ground to scale-invariant topography. Earth-Science Rev 29: 57–75.
Huggett, R.J. 1995. Geoecology: An Evolutionary Approach. Routledge, London.
Ibánez, J.J. 1994. Evolution of fluvial dissection landscapes in mediterranean environments: quantitative estimates and geomorphic, pedologic, and phytocenotic repercussions. Z Geomorp 38: 105–119.
Ibánez, J.J., Ballexta, R.J. and Alvarez, A.G. 1990. Soil landscapes and drainage basins in mediterranean mountain areas. Catena 17: 573–583.
Ibánez, J.J., De-Alba, S., Bermudez, F.-F., and Garcia-Alvarez, A. 1995. Pedodiversity: concepts and measures. Catena 24: 215–232.
Johnson, D.L., Keller, E.A. and Rockwell, T.K. 1990. Dynamic pedogenesis: New views on some key soil concepts, and a model for interpreting Quaternary soils. Quat Res 33: 306–319.
Johnson, D.L. and Watson-Stegner, D. 1987. Evolution model of pedogenesis. Soil Sci 143, 349–366.
Kauffman, S.A. 1993. The Origins of Order. Self-Organization and Selection in Evolution. Oxford University Press, Oxford.
Kay, J.J. 1991. A nonequilibrium thermodynamic framework for discussing ecosystem integrity. Env Manage 15: 483–495.
King, G.J., Acton, D.F. and St. Arnaud, R.J. 1983. Soil-landscape analysis in relation to soil distribution and mapping at a site within the Weyburn Association. Can. J Soil Sci 63: 657–670.
Kleiss, H.J. 1994. Relationships between geomorphic surfaces and low activity clay on the North Carolina Coastal Plain. Soil Sci 157: 373–378.
Kreznor, W.R., Olson, K.R., Banwart, W.L. & Johnson, D.L. 1989. Soil, landscape, and erosion relationships in a northwest Illinois watershed. Soil Sci Soc Am J 53: 1763–1771.
Li, M. & Vitányi, P. 1997. An Introduction to Kolmogorov Complexity and its Applications. Springer-Verlag, Berlin.
McBratney, A.B. 1992. On variation, uncertainty, and informatics in environmental soil management. Austr J of Soil Res 30: 913–936.
McRae, S.G. 1988. Practical Pedology. Halsted, London.
Mokma, D.L., Fenton, T.E. & Olson, K.R. 1996. Effect of erosion on morphology and classification of soils in the north central United States. J Soil Water Cons 51: 171–175.
Nahon, D.B. 1991. Self-organization in chemical lateritic weathering. Geoderma 51: 5–13.
Pahl-Wostl, C. 1995. The Dynamic Nature of Ecosystems. Chaos and Order Entwined. John Wiley, Chichester, U.K.
Phillips, J.D. 1993. Chaotic evolution of some coastal plain soils. Phys Geog 14: 566–580.
Phillips, J.D. 1994. Deterministic uncertainty in landscapes. Earth Surface Proc Landforms 19: 389–401.
Phillips, J.D. 1995a. Nonlinear dynamics and the evolution of relief. Geomorphology 14: 57–64.
Phillips, J.D. 1995b. Self-organization and landscape evolution. Prog Phys Geog 19: 309–21.
Phillips, J.D. 1996. Deterministic complexity, explanation, and predictability in geomorphic systems. In The Scientific Nature of Geomorphology, Proceedings of the 27th Binghamton Geomorphology Symposium. pp. 315–336. Edited by B. Rhoads and C. Thorn. John Wiley, New York.
Phillips, J.D. 1997a. Simplexity and the reinvention of equifinality. Geog Analysis 29: 1–15.
Phillips, J.D. 1997b. A short history of a flat place: Three centuries of geomorphic change in the Croatan. Ann Assoc Am Geograph 87: 197–216.
Phillips, J.D., Golden, H., Cappiella, K., Andrews, B., Middleton, T., Downer, D., Kelli, D. and Padrick, L. 1988. Soil redistribution and pedologic transformations in coastal plain croplands. Earth Surface Proc Landforms 23: 481–492.
Phillips, J.D., Perry, D., Carey, K., Garbee, A.R., Stein, D., Morde, M.B. & Sheehy, J. 1996. Deterministic uncertainty and complex pedogenesis in some Pleistocene dune soils. Geoderma 73: 147–164.
Rigon, R., Rinaldo, A., and Rodriguez-Iturbe, I. 1994. On landscape self-organization. J Geophys Res 99B: 11971–11993.
Soil Survey Division Staff. 1993. Soil survey manual. U.S. Department of Agriculture, Washington.
Ulanowicz, R.E. 1980. An hypothesis on the development of natural communities. J Theor Biol 85: 223–45.
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Phillips, J.D., Gares, P.A. & Slattery, M.C. Agricultural soil redistribution and landscape complexity. Landscape Ecology 14, 197–211 (1999). https://doi.org/10.1023/A:1008024213440
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DOI: https://doi.org/10.1023/A:1008024213440