2008 Joint Meeting of The Geological Society of America, Soil Science Society of America, American Society of Agronomy, Crop Science Society of America, Gulf Coast Association of Geological Societies with the Gulf Coast Section of SEPM

Paper No. 11
Presentation Time: 10:45 AM

Opposing Effects of Rainfall and Aerosol Washout on Soil Silicon Isotope Ratios


BERN, Carleton R.1, BRZEZINSKI, Mark2, BEUCHER, Charlotte2 and CHADWICK, Oliver A.3, (1)Dept. of Geography, UC Santa Barbara, Santa Barbara, CA 93106, (2)Dept. of Ecology, Evolution & Marine Biology, UC Santa Barbara, Santa Barbara, CA 93106, (3)Univ California - Santa Barbara, 3611 Ellison Hall, Santa Barbara, CA 93106, cbern@usgs.gov

Secondary mineral precipitation in soils fractionates silicon isotopes relative to soil solution. Increasing secondary mineral prevalence, in conjunction with overall loss of Si from soil, drives bulk soil d30Si values lower with progressive soil development. Here we report the net effect of two opposing processes on bulk soil d30Si: climate driven weathering and washout of mineral aerosols. The study utilizes a climosequence located on a 170 ka lava flow on Kohala Mountain in Hawaii. Rainfall ranges from 160 to 2500 mm yr-1 and is a primary driver for weathering and soil development. Total mineral dust addition to soil also increases with rainfall, from approximately 25 to 200 kg m-2. A climatic rainfall threshold of 1400 mm yr-1, corresponding to the point at which annual soil water balance becomes positive, divides the soils into two categories with regards to d30Si evolution. On the drier side of the threshold, net soil Si loss is associated with secondary mineral precipitation fractionating Si. Bulk soil d30Si declines from -0.6 to -2.4‰ with Si loss from 35% to 80% depletion relative to lava. On the wetter side of the threshold, dissolution consumes both primary and secondary minerals, driving more extensive Si loss from 77% to 90% depletion relative to lava. These losses, combined with greater dust inputs with increased rainfall, increase the contribution of weathering resistant, dust-derived quartz and mica to the Si pool. The d30Si of dust minerals is similar to lava (-0.5‰), causing soil d30Si to increase from -2.5 to -0.8‰ with extreme weathering. These results highlight another role for dust in rejuvenating weathered soils. Further, while quartz and mica strongly constrain the evolution of bulk soil d30Si, more easily weathered dust minerals (e.g. plagioclase) are likely to dominate the evolution of the d30Si supplied from soils to rivers and ultimately the oceans.