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Dynamic Pedogenesis: New Views on Some Key Soil Concepts, and a Model for Interpreting Quaternary Soils

Published online by Cambridge University Press:  20 January 2017

D. L. Johnson
Affiliation:
Department of Geography, University of Illinois, Urbana, Illinois 61801 USA
E. A. Keller
Affiliation:
Department of Geological Sciences, University of California, Santa Barbara, California 93106 USA
T. K. Rockwell
Affiliation:
Department of Geological Sciences, San Diego State University, San Diego, California 92182 USA

Abstract

Inasmuch as soils are open systems and rarely, if ever, achieve equilibrium with their environments, it is philosophically sound to view all soils as expressing varying levels of polygenesis as that term has been redefined. Soil genesis and resultant morphology may then be viewed in a comprehensive framework of soil evolution that consists of two linked pathways, one developmental and the other regressive, that reflect interactions of both exogenous and endogenous vectors (vectors are factors, processes, and conditions of pedogenesis). Following this philosophy, a model of pedogenesis is framed in an evolutional paradigm that emphasizes the integrated effects of dynamic and passive pedogenic vectors in directing pathways and in controlling rates of soil genesis through time. The dynamic vectors include energy and mass fluxes, frequencies of soil wetting and drying, water table dynamics, organisms, feedback processes, and pedoturbation. The passive vectors include parent materials, soil chemical environment, stability of geomorphic surfaces, and various evolved soil properties and conditions (accessions). Both sets of vectors vary spatially, and the dynamic vectors, more so than passive vectors, fluctuate through time. The model is expressed as S=f(D,P,dD/dt,dD/dt) where S is the state of the soil or degree of profile evolution, D is the set of dynamic vectors, P is the set of passive vectors, and dD/dt and dP/dt denote change through time t. The model helps explain the apparent minimal development and regressed character of some old soils and the rapid and strong development of some young ones.

Type
Articles
Copyright
University of Washington

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References

Adam, D. P. West, G. J. Temperature and precipitation estimates through the last glacial cycle from Clear Lake, California, pollen data. Science 219 1983 168 170 CrossRefGoogle ScholarPubMed
Baldwin, M. Kellogg, C. E. Thorp, J. Soil classification Soils and Men. Yearbook of Agriculture, 1938 1938 U.S. Department of Agriculture Washington, DC 979 1001 Google Scholar
Bockheim, J. G. Solution and use of chronofunctions in studying soil development. Geoderma 24 1980 71 85 Google Scholar
Borst, G. The occurrence of crotovinas on some southern Californian soils. Transactions of the 9th International Congress Soil Science, Adelaide 2 1968 19 27 Google Scholar
Bryan, K. Albritton, C. C. Jr. Soil phenomena as evidence of climatic changes. American Journal of Science 241 1943 469 490 CrossRefGoogle Scholar
Bryan, W. H. Teakle, L. J. H. Pedogenic inertia—A concept in soil science. Nature (London) 164 1949 969 Google Scholar
Buol, S. W. Hole, F. D. McCracken, R. J. 2nd ed. Soil Genesis and Classification 1980 Iowa State Univ. Press Ames Google Scholar
Byers, H. G. Kellogg, C. E. Anderson, M. S. Thorp, J. Formation of soil Soils and Men. Yearbook of Agriculture, 1938 1938 U.S. Department of Agriculture Washington, DC 948 978 Google Scholar
Cady, J. G. Daniels, R. B. Genesis of some very old soils—The Paleudults. Transactions 9th International Congress Soil Science, Adelaide 4 1968 103 112 Google Scholar
Catt, J. A. Soils and Quaternary geology in Britain. Journal of Soil Science 30 1979 607 642 Google Scholar
Chesworth, W. The parent rock effect in the genesis of soil. Geoderma 10 1973 215 225 Google Scholar
Chesworth, W. Conceptual models in pedogenesis: A rejoinder. Geoderma 16 1976 257 260 CrossRefGoogle Scholar
Chesworth, W. Conceptual models in pedogenesis: A further rejoinder. Geoderma 16 1976 265 266 CrossRefGoogle Scholar
Cline, M. G. The changing model of soil. Soil Science Society of America Proceedings 25 1961 442 446 Google Scholar
Colman, S. M. Rock-weathering rates as functions of time. Quaternary Research 15 1981 250 264 Google Scholar
Crocker, R. L. Soil genesis and the pedogenic factors. Quarterly Review of Biology 27 1952 139 168 CrossRefGoogle ScholarPubMed
Daniels, R. B. Gamble, E. E. The edge effect in some Ultisols in the North Carolina coastal plain. Geoderma 1 1967 117 124 CrossRefGoogle Scholar
Dansgaard, W. Clausen, H. B. Gundestrup, N. Hammer, C. U. Johnson, S. F. Kristinsdottir, P. M. Rech, N. A new Greenland deep ice core. Science 218 1983 1273 1277 Google Scholar
Dembroff, G. R. Johnson, D. L. Keller, E. A. Rockwell, T. K. The Soil Geomorphology and Neotectonics of the Ventura River and Central Ventura Basin, California: A Fieldguide 1982 71 (Prepared for the Soil Geomorphology Tour Division S-5), Dec. 2–3, 1982 Annual Meetings of the American Society of Agronomy, Crop Science Society of America and Soil Science Society of America Google Scholar
Dokuchaev, V. V. The problem of the reevaluation of the land in European and Asiatic Russia. Moscow 1898 [in Russian] Google Scholar
Drury, W. H. Nisbet, I. C. T. Interrelations between developmental models in geomorphology, plant ecology, and animal ecology. General Systems 16 1971 57 68 Google Scholar
Fenwick, I. Paleosols: Problems of recognition and interpretation Boardman, J. Soils and Quaternary Landscape Evolution 1985 Wiley New York 3 21 Google Scholar
Gerasimov, I. P. Glazovskaya, M. A. Fundamentals of Soil Science and Soil Geography 1960 Israel Program Scientific Translation Jerusalem 382 1965 Google Scholar
Glinka, K. D. The Great Soil Groups of the World and Their Development 1914 Edwards Ann Arbor, MI (Translated from the German by C. F. Marbut, 1927) Google Scholar
Hassett, J. J. Gregg, D. W. Fehrenbacher, J. B. Formation of calcium carbonate concretions in natric horizons of Illinois soils. Soil Science 122 1976 202 205 Google Scholar
Hays, J. D. Imbrie, J. Shackleton, N. D. Variations in the earth's orbit: Pacemaker of the Ice Ages. Science 194 1976 1121 1132 Google Scholar
Heath, G. W. The part played by animals in soil formation Hallsworth, E. G. Crawford, D. V. Experimental Pedology 1965 Butterworths London 236 243 Google Scholar
Hole, F. D. A classification of pedoturbations and some other processes and factors of soil formation in relation to isotropism and anisotropism. Soil Science 91 1961 375 377 CrossRefGoogle Scholar
Horn, H. S. Ecological disequilibria. Science 230 1985 434 435 Google Scholar
Jenny, H. Factors of Soil Formation 1941 McGraw-Hill New York, NY Google Scholar
Jenny, H. The Soil Resource: Origin and Behavior 1980 Springer-Verlag New York 377 (Ecological Studies 37) Google Scholar
Joffe, J. S. Pedology 1936 Rutgers Univ. Press New Brunswick 575 Google Scholar
Joffe, J. S. Pedology 1949 662 Somerset, Somerville, NJ Google Scholar
Johnson, D. L. Report and Analysis on the Beach Fault Trench Soil, LNG Site, Point Conception, California 1981 Analysis of Data: Marine Terrace Studies and Age Dating, Final Geoseismic Investigations, Proposed LNG Terminal, Little Cojo Bay, California, For WLNG Terminal Associates Dames and Moore, Consultants, Appendix A.4. March 1981 Google Scholar
Johnson, D. L. Soil evolution and the flawed concept of the monogenetic soil. Program Abstracts 1984 Association of American Geographers Washington, DC 61 Google Scholar
Johnson, D. L. Soil thickness processes Jungerius, P. D. Soils and Geomorphology Vol. 6 1985 29 40 Catena Supplement, Braunschweig Google Scholar
Johnson, D. L. Keller, E. A. Rockwell, T. K., and Dembroff, G. R. Dynamic pedogenesis: Use of dynamic-rate model to explain strong pedogenesis in the Ventura area, California. Quaternary Research, in review.Google Scholar
Johnson, D. L. Watson-Stegner, D. Evolution model of pedogenesis. Soil Science 143 1987 349 366 Google Scholar
Johnson, D. L. Watson-Stegner, D. Johnson, D. N. Schaetzl, R. J. Proisotropic and proanisotropic processes of pedoturbation. Soil Science 143 1987 278 292 Google Scholar
Kellogg, C. E. Development and significance of the great soil groups of the United States. U.S. Department of Agriculture Miscellaneous Publications No. 229 1936 Google Scholar
Langmaid, K. K. Some effects of earthworm invasion in virgin Podzols. Canadian Journal of Soil Science 44 1964 34 37 Google Scholar
Lavkulich, L. M. Soil dynamics in the interpretation of paleosols Pawluk, S. Pedology and Quaternary Research 1969 University of Alberta Printing Department Edmonton 25 37 Google Scholar
Marbut, C. F. Glinka, K. D. The Great Soil Groups of the World and their Development 1927 Edwards Brothers Ann Arbor Translated from the German Google Scholar
Marbut, C. F. A scheme for soil classification. First International Congress of Soil Science, Proceedings and Papers 4 1927 1 31 Google Scholar
Marbut, C. F. Soils of the United States Baker, E. O. Atlas of American Agriculture. Advance Sheets No. 8 1935 U.S. Department of Agriculture Washington, DC part 3 Google Scholar
Milne, G. A soil reconnaissance journey through parts of Tanganyika Territory December 1935 to February 1936. Journal of Ecology 35 1947 192 265 Google Scholar
Muhs, D. R. A soil chronosequence on Quaternary marine terraces, San Clemente Island, California. Geoderma 28 1982 257 283 Google Scholar
Muhs, D. R. Intrinsic thresholds in soil systems. Physical Geography 5 1984 99 110 CrossRefGoogle Scholar
Neustruev, S. S. Genesis of soils. Russian Pedological Investigations III 1927 Publishing Office of the Academy Leningrad Google Scholar
Nikiforoff, C. C. Hardpan and microrelief in certain soil complexes of California. U.S. Department of Agriculture Technical Bulletin No. 745 1941 Google Scholar
Nikiforoff, C. C. Soil dynamics. American Scientist 30 1942 36 50 Google Scholar
Nikiforoff, C. C. Pedogenic criteria of climatic changes Shapely, H. Climate Change: Evidence, Causes, and Effects 1953 Harvard Univ. Press Cambridge 189 200 Google Scholar
Novak, R. J. Mott, H. L. Douglas, L. A. The effect of time and particle size on mineral alteration in several Quaternary soils in New Jersey and Pennsylvania, U.S.A. Yaalon, D. H. Paleopedology, Origin, Nature and Dating of Paleosols 1971 International Society of Soil Science and Israel Univ. Press Jerusalem 211 224 Google Scholar
Ramann, E. Bodenkunde 2nd ed. 1905 Verlag Julius Springer Berlin Google Scholar
Ramann, E. Bodenkunde 3rd ed. 1911 Verlag Julius Springer Berlin Google Scholar
Ramann, E. The Evolution and Classification of Soils 1928 Heffer London Google Scholar
Robinson, G. W. Soils, Their Origin, Constitution and Classification 1949 Wiley New York Google Scholar
Rockwell, T. K. Keller, E. A. Dembroff, G. R. Quaternary rate of folding of the Ventura Avenue anticline, western Transverse Ranges, southern California. Geological Society of American Bulletin 100 1988 850 858 Google Scholar
Rode, A. A. Volynskaya, V. S. Krynochkina, K. V. The Soil Forming Process and Soil Evolution 1947 Israel Program in Scientific Translation Jerusalem 1961 Google Scholar
Runge, E. C. A. Soil development sequences and energy models. Soil Science 115 1973 183 193 Google Scholar
Shackleton, N. J. Opdyke, N. D. Oxygen isotope and paleomagnetic stratigraphy of equatorial Pacific core V28–238: Oxygen isotope temperatures and ice volumes on a 105 and 106 year scale. Quaternary Research 3 1973 39 55 Google Scholar
Shackleton, N. J. Opdyke, N. D. Oxygen isotope and paleomagnetic stratigraphy of Pacific core V28–239 late Pliocene to latest Pleistocene. Geological Society of America Memoirs 145 1976 449 464 Google Scholar
Simonson, R. W. A multiple-process model of soil genesis Mahaney, W. C. Quaternary Soils 1978 Geo Abstracts Norwich, England 1 25 Google Scholar
Smeck, N. E. Runge, E. C. A. Mackintosh, E. E. Dynamics and genetic modelling of soil systems Wilding, L. P. Smeck, N. E. Hall, G. F. Pedogenesis and Soil Taxonomy. I. Concepts and Interactions 1983 Elsevier Science Amsterdam 51 81 Google Scholar
Thorp, J. Report on a field study of soils of Australia. Science Bulletin No. 1 1957 Earlham College Richmond, Indiana Google Scholar
Thorp, J. The nature of the pedological record in the Quaternary. Soil Science 99 1965 1 8 Google Scholar
Torrent, J. Nettleton, W. D. Feedback processes in soil genesis. Geoderma 20 1978 281 CrossRefGoogle Scholar
Troxell, H. C. Hofmann, W. Hydrology of the Los Angeles region Jahns, R. H. Geology of Southern California Vol. 1 1954 California Division of Mines Geology 5 12 Bulletin 170 Google Scholar
Vilenskii, D. G. Analogous Series in Soil Formation. Tiflis 1924 [in Russian] Google Scholar
Watson-Stegner, D. Soil development in Holocene-age alluvium on the Pomme de Terre River, Missouri. Unpublished M.S. thesis 1980 University of Illinois Urbana Google Scholar
Wilde, S. A. Forest Soils and Forest Growth 1946 Chronica Botanica Co Waltham, MA 242 Google Scholar
Wood, W. R. Johnson, D. L. A survey of disturbance processes in archaeologica site formation Schiffer, M. B. Advances in Archaeological Method and Theory Vol. 1 1978 Academic Press Orlando, FL 315 381 Google Scholar
Yaalon, D. H. Soil forming processes in time and space Yaalon, D. H. Paleopedology-Origin, Nature and Dating of Paleosols 1971 International Society of Soil Science and Israel Univ. Press Jerusalem 19 39 Google Scholar