Hydrogeology, Chemical Weathering, and Soil Formation. Allen Hunt

Hydrogeology, Chemical Weathering, and Soil Formation - Allen Hunt


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agents in providing nutrients and water to plants. Egli and Mirabella discuss the evolution of clay minerals in alpine soils also in the light of kinetic limitation and percolation. Lukens and Norton depict the role of aeolian deposition in soil formation, as not only water and carbon are transported through the atmosphere, but dust as well. Related to this topic is the chapter of Finke and coauthors in the next section, where loess records are shown to be important climate indicators.

      Weathering rinds are indicative of the exposure age of a rock (Sak). In fact, rinds can be considered as microsoils and obey the same weathering principles that also depend on climate. Soil trajectories related to compression from agriculture are discussed in the chapter of Horn and Lal. The role of pedogenesis in geomorphology is discussed in the example of landsliding (Temme). Finally, a cross‐section of integrative field studies is presented with results from several critical zone observatories (CZOs). These include the contribution of Lyons and coauthors on soil formation in the Antarctic dry valleys, Rasmussen and coauthors on the impacts of land‐use change on soils in the southeastern piedmont of the USA, and Suzanne Anderson and coauthors’ discussion of Gordon Gulch from the Boulder Creek CZO. The book closes with a summary of the current state of affairs.

      Allen Hunt

       Wright State University, USA

      Markus Egli

       University of Zürich, Switzerland

      Boris Faybishenko

       Lawrence Berkeley National Laboratory, USA

      1 Berner, R. A. (1992). Weathering, plants, and the long‐term carbon‐cycle. Geochimica et Cosmochimica Acta, 56, 3225–3231.

      2 Blättler, C. L., & Higgins, J. A. (2017). Testing Urey’s carbonate–silicate cycle using the calcium isotopic composition of sedimentary carbonates. Earth and Planetary Science Letters, 479, 241–251. https://doi.org/10.1016/j.epsl.2017.09.033

      3 Darwin, C. (1881). The formation of vegetable mould through the action of worms, with observations on their habits. London: John Murray. (Source: http://darwin‐online.org.uk/converted/pdf/1881_Worms_F1357.pdf)

      4 Dokuchaev, V. V. (1883/1948/1967). Russian Chernozem. In Selected works of V. V. Dokuchaev, Moscow, 1948 (vol. 1, pp. 14–419). Jerusalem: Israel Program for Scientific Translations Ltd. (for USDA‐NSF), Publ. by S. Monson, 1967. (Transl. into English by N. Kaner).

      5 Frings, P. J. (2019). Palaeoweathering: How do weathering rates vary with climate? Elements, 15, 259–265. DOI: 10.2138/gselements.15.4.259

      6 Frings, P. J., & Buss, H. L. (2019). The central role of weathering in the geosciences. Elements, 15, 229–234. DOI: 10.2138/gselements.15.4.229

      7 Maher, K. (2010). The dependence of chemical weathering rates on fluid residence time. Earth Planetary Science Letters, 294, 101–110. DOI: 10.1016/j.epsl.2010.03.010

      8 White, A. F., & Brantley, S. L. (2003). The effect of time on the weathering rates of silicate minerals. Why do weathering rates differ in the lab and in the field? Chemical Geology, 202, 479–506. https://doi.org/10.1016/j.chemgeo.2003.03.001

Part I Soil Definition

       Richard J. Huggett

       School of Environment, Education, and Development, University of Manchester, Manchester, UK

      ABSTRACT

      The idea of soil as a system is not yet a hundred years old. Its origins lie in Dokuchaev’s view of soil as an independent object, an idea promoted so successfully and eloquently by Hans Jenny. It was Jenny who first thought of soil as a system. His CLORPT equation focused on state factors (external drivers) of the soil system and, later, ecosystems. His approach was largely statistical and empirical. Later, a few researchers investigated energy as a soil‐system driver. A different line of investigation, spurred by Milne’s catena concept, saw soil as a spatial system. Research in this field began in earnest with Simonson’s concept of soil as an open system, which at first involved one‐dimensional soil profiles but was later extended to catenas and three‐dimensional soil landscapes, all researched using a rich variety of statistical and deterministic models. Last came the recognition that soil is part of an interdependent system. This line of enquiry began with conceptual models of the ecosphere. Since the millennium it has made big advances from cross‐disciplinary enquiries focusing on the Earth’s critical zone and interactions between soils and geomorphology, soils and hydrology, soils and life, and soils and humans.

      Ideas about soil have a long and rich history. It is perhaps easy to dismiss older notions as outmoded, but the foundations of soil science laid down by the creators of the subject still have currency, even though later thinkers have refined them and added new elements. Expanding a metaphor, if Isaac Newton could see further by standing on the shoulders of giants, then modern soil scientists can see further by standing in the soil pits of their predecessors. This chapter will explore the view taken by Hans Jenny, a veritable giant among soil scientists, that soil may be regarded as a system. Jenny mooted this idea in 1930, but soil concepts developed in the five decades before that date provide an essential background and they will be discussed first, before considering soil as a system, soil as a spatial system, and soil as an interdependent system. The chapter will end with a brief look at prospects for the systems approach in pedology.

      Source. Partly inspired by discussion in Hoosbeek and Bryant (1992) and discussion and tables in Minasny et al. (2008).


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Subject of Model Type of Model
Qualitative Quantitative
Conceptual Statistical and Empirical Deterministic
Soil as an independent system