North-Central Section - 39th Annual Meeting (May 19–20, 2005)

Paper No. 2
Presentation Time: 1:40 PM

RECONCILING THE STABLE ISOTOPIC PALEOHYDROLOGY OF PEDOGENIC SIDERITES AND CALCITES


LUDVIGSON, Greg A., Iowa Geological Survey, Iowa Dept. Nat Rscs, 109 Trowbridge Hall, Iowa City, IA 52242-1319, UFNAR, David F., Geology, Univ of Southern Mississippi, Hattiesburg, MS 39406, GONZÁLEZ, Luis A., Department of Geology, Univ of Kansas, Lawrence, KS 66045-7613, WITZKE, Brian J., Iowa Dept of Nat Res, Geol Survey, 109 Trowbridge Hall, Iowa City, IA 52242-1379 and BRENNER, Robert L., Geoscience, Univ of Iowa, 121 Trowbridge Hall, Iowa City, IA 52242, gregory-ludvigson@uiowa.edu

Pedogenic carbonates occur in zonal belts controlled by regional precipitation-evaporation balances. Pedogenic siderites (FeCO3) accumulate in saturated soil groundwaters in regions of precipitation excess, and form along the equatorial humid belt, and at latitudes greater than 30°. Pedogenic calcites (CaCO3) accumulate as soluble salts in vadose soils influenced by evaporation, and form at latitudes between 10° to 30°, but also at other latitudes in orographic rain shadows. Accumulation in phreatic and vadose groundwaters dictates that comparisons of isotope paleohydrology between these proxies must account for differing processes during formation, and how they are encoded during early diagenesis. Paleohydrologic processes can be distinguished by distinct diagenetic trends in C & O isotope space that are unique to each pedogenic carbonate. Pedogenic siderites produce diagenetic trends of meteoric sphaerosiderite lines (MSLs; sensu Ludvigson et al., 1998, Geology 26) that integrate time-averaged soil mean annual temperature (MAT) and groundwater δ18O recording paleoprecipitation. Pedogenic calcites produce diagenetic trends of positive linear covariant trends (PLCTs) that integrate variable 18O enrichments through evaporation, and variable 13C enrichments through changing soil respiration rates and kinetic effects from CO2 degassing. Direct comparisons of isotopic paleohydrology between pedogenic siderites and calcites are complicated by the need for quantifying extents of vadose 18O enrichment in calcites. This problem is frequently overcome in ancient buried calcic paleosols, because of partial recrystallization of unstable CaCO3 polymorphs, as ancient water tables ascended through the column with landscape aggradation. Phreatic overprinting of calcic paleosols produces diagenetic trends of meteoric calcite lines (MCLs; sensu Lohmann, 1988, Paleokarst) that integrate time-averaged MAT and δ18O of paleoprecipitation. Cretaceous paleoclimate studies show that MSL and MCL trends from 25-34 °N paleolatitude produce compatible groundwater δ18O estimates, but that PLCT trends in pedogenic calcites can produce 18O enrichments of up to 7 ‰ over that of coeval MCL trends. Failure to account for diverging MCL & PLCT trends can lead to erroneous paleoclimatic interpretations.