H41K-05
Upland Reticulate Mottling Reveals Soil Biophysical Processes across Scales: Development of Structured Heterogeneity in a Marine Terrace Chronosequence

Thursday, 17 December 2015: 09:00
3024 (Moscone West)
David A Stonestrom1, Marjorie S Schulz1, Corey R Lawrence2, Thomas D Bullen1, John Fitzpatrick1, Emily Kyker-Snowman3, Jane E Manning4 and Meagan Mnich1, (1)USGS, Menlo Park, CA, United States, (2)USGS, Denver, CO, United States, (3)University of New Hampshire, Soil Biogeochemistry & Fertility Lab, Durham, NH, United States, (4)San Jose State University, Department of Biology, San Jose, CA, United States
Abstract:
Soils of the Santa Cruz (California, USA) marine terrace chronosequence display an evolving sequence of reticulate mottling from the youngest soil (65 ka) without mottles to the oldest soil (225 ka) with well-developed mottles. Mottles develop in soils forming from relatively uniform shoreline sediments, below the depth of bioturbation. Mottles consist of an interconnected network of low-chroma clay-and-carbon enriched central regions (gray; 2.5Y 6/1) bordered by bleached parent material (white; 2.5Y 8/1) within a diminishing matrix of high-chroma oxidized parent material (orange; 7.5YR 5/8). To explore the nature of mottle development, physical and chemical characteristics of mottle separates (orange, gray, and white) were compared through the deep time represented by the chronosequence. Mineralogical, isotopic, and surface-area differences among mottle separates indicate that centimeter-scale mass-transfer acting across millennia is an integral part of pedogenesis, weathering-front propagation, and carbon and nutrient transfer. Elemental analysis, electron microscopy, and iron-isotope systematics indicate that mottle development is driven by deep roots together with their fungal and microbial symbionts. The current work extends the known realm of upland mottling and shows that such features may be more common than previously recognized in semi-humid to arid regions. Deep soil horizons on old stable landforms develop reticulate mottling as the long-term imprint of rhizospheric processes that control pedogenesis, plant-community sustenance, and sequestration of carbon at depth in unsaturated zones.