2006 Philadelphia Annual Meeting (22–25 October 2006)

Paper No. 1
Presentation Time: 8:00 AM

OBSERVED RELATIONSHIPS BETWEEN MODERN SOIL CHEMISTRY AND ENVIRONMENTAL HEAT TRANSFER AND ITS APPLICATION TO SOIL ECOSYSTEMS UPON A GREENHOUSE WORLD


TABOR, Neil J., Roy M. Huffington Department of Earth Sciences, Southern Methodist University, Dallas, TX 75275 and RASMUSSEN, Craig, Soil, Water, and Environmental Science, University of Arizona, 429 Shantz Building, University of Arizona, Tucson, AZ, AZ 85721, ntabor@mail.smu.edu

We consider bulk soil chemistry to be a function of environmental heat transfer, or energy input (EIN) to the soil, which is related to mean annual precipitation (MAP) and temperature (MAT), according to the following empirical relationship that is derived from the IAEA global climate database: (1) EIN(KJ/m2yr) = 347,135e-0.5[((MAT-21.5)/-10)^2+((MAP-4,413)/1704)^2] (R2 = 0.96; P<0.0001). Chemical Index of Alteration minus Potassium (CIA-K = [Al2O3/(Al2O3+MgO+CaO+Na2O)*100]) values of B-horizons from 18 soil profiles sampled along four soil climosequences on parent material compositions ranging from granitic to basaltic in the western United States and Mexico exhibit a high degree of linear correlation with EIN values: (2) EIN= 422*(CIA-K) -7982 (R2 = 0.81, P < 0.0001), suggesting (i) the chemical composition of soil B-horizons does proceed according to environmental heat transfer that is expressed in a manner similar to Eqn (1) above, (ii) the CIA-K values of paleosol B horizons might be used to estimate environmental heat transfer in ancient ecosystems and (iii) CIA-K values may be used in conjunction with independent estimates of MAT from stable isotope geochemistry in order to provide quantitative estimates of MAP (using Eqn 1 above). Paleosol B-horizon samples from Paleocene through Miocene-age laterite profiles that formed at paleolatitudes ranging from ~65°N to ~60°S have CIA-K values >90%, which correspond to EINvalues >30,000 kJ/m2yr. Such high EIN values are typical of highly weathered soils such as Ultisols, Oxisols and Spodosols in modern climate regimes. Therefore, the higher-latitude paleosol CIA-K and EIN data might represent paleoecosystems characterized by more vigorous weathering and greater environmental energy transfer than is typically recorded in modern high-latitude soil ecosystems. Indeed, oxygen and hydrogen isotope compositions of kaolinites from the paleosol B horizons range from 15.4 to 19.0‰ and –71 to -100‰, respectively, which corresponds to kaolinite crystallization temperatures ranging from 21±3° to 29±3°C – temperatures that are much higher than any modern high-latitude soil-forming environments. These paleotemperature and CIA-K estimates of paleo- EIN will be used to provide new paleoprecipitation estimates within the context of Eqn (1) above.