Your search keyword '"Yoo, Kyungsoo"' showing total 5 results

1. Trace element and Pb isotope analyses highlight decentralized inter-island exchange in American Sāmoa (Polynesia)

Author

Quintus, Seth, Mills, Peter, Konter, Jasper, Day, Stephanie, Gilreath, Darr, Kekuewa Lincoln, Noa, Lundblad, Steven, Vonderhaar, Denys, and Yoo, Kyungsoo

Published

2022

2. The geochemical transformation of soils by agriculture and its dependence on soil erosion: An application of the geochemical mass balance approach.

Author

Yoo, Kyungsoo, Fisher, Beth, Ji, Junling, Aufdenkampe, Anthony, and Klaminder, Jonatan

Subjects

*GEOCHEMISTRY, *SOIL erosion, *MASS budget (Geophysics), *FOOD production, *SOIL formation

Abstract

Agricultural activities alter elemental budgets of soils and thus their long-term geochemical development and suitability for food production. This study examined the utility of a geochemical mass balance approach that has been frequently used for understanding geochemical aspect of soil formation, but has not previously been applied to agricultural settings. Protected forest served as a reference to quantify the cumulative fluxes of Ca, P, K, and Pb at a nearby tilled crop land. This comparison was made at two sites with contrasting erosional environments: relatively flat Coastal Plain in Delaware vs. hilly Piedmont in Pennsylvania. Mass balance calculations suggested that liming not only replenished the Ca lost prior to agricultural practice but also added substantial surplus at both sites. At the relatively slowly eroding Coastal Plain site, the agricultural soil exhibited enrichment of P and less depletion of K, while both elements were depleted in the forest soil. At the rapidly eroding Piedmont site, erosion inhibited P enrichment. In similar, agricultural Pb contamination appeared to have resulted in Pb enrichment in the relatively slowly eroding Coastal Plain agricultural soil, while not in the rapidly eroding Piedmont soils. We conclude that agricultural practices transform soils into a new geochemical state where current levels of Ca, P, and Pb exceed those provided by the local soil minerals, but such impacts are significantly offset by soil erosion. [ABSTRACT FROM AUTHOR]

Published

2015

3. Spatial patterns and controls of soil chemical weathering rates along a transient hillslope

Author

Yoo, Kyungsoo, Mudd, Simon Marius, Sanderman, Jonathan, Amundson, Ronald, and Blum, Alex

Subjects

*CHEMICAL weathering, *SOIL chemistry, *SLOPES (Physical geography), *EROSION, *SEDIMENT transport, *GEOCHEMISTRY, *GEOLOGICAL modeling, *GEOMORPHOLOGISTS

Abstract

Abstract: Hillslopes have been intensively studied by both geomorphologists and soil scientists. Whereas geomorphologists have focused on the physical soil production and transport on hillslopes, soil scientists have been concerned with the topographic variation of soil geochemical properties. We combined these differing approaches and quantified soil chemical weathering rates along a grass covered hillslope in Coastal California. The hillslope is comprised of both erosional and depositional sections. In the upper eroding section, soil production is balanced by physical erosion and chemical weathering. The hillslope then transitions to a depositional slope where soil accumulates due to a historical reduction of channel incision at the hillslope''s base. Measurements of hillslope morphology and soil thickness were combined with the elemental composition of the soil and saprolite, and interpreted through a process-based model that accounts for both chemical weathering and sediment transport. Chemical weathering of the minerals as they moved downslope via sediment transport imparted spatial variation in the geochemical properties of the soil. Inverse modeling of the field and laboratory data revealed that the long-term soil chemical weathering rates peak at 5gm− 2 yr−1 at the downslope end of the eroding section and decrease to 1.5gm− 2 yr−1 within the depositional section. In the eroding section, soil chemical weathering rates appear to be primarily controlled by the rate of mineral supply via colluvial input from upslope. In the depositional slope, geochemical equilibrium between soil water and minerals appeared to limit the chemical weathering rate. Soil chemical weathering was responsible for removing 6% of the soil production in the eroding section and 5% of colluvial influx in the depositional slope. These were among the lowest weathering rates reported for actively eroding watersheds, which was attributed to the parent material with low amount of weatherable minerals and intense coating of the primary minerals by secondary clay and iron oxides. We showed that both the morphologic disequilibrium of the hillslope and the spatial heterogeneity of soil properties are due to spatial variations in the physical and chemical processes that removed mass from the soil. [Copyright &y& Elsevier]

Published

2009

4. Toward process-based modeling of geochemical soil formation across diverse landforms: A new mathematical framework

Author

Yoo, Kyungsoo and Mudd, Simon Marius

Subjects

*SOIL formation, *MATHEMATICAL models, *LANDFORMS, *GEOCHEMISTRY, *GEOMORPHOLOGY, *CHEMICAL weathering, *SIMULATION methods & models, *SURFACE of the earth, *SOIL science

Abstract

Abstract: We present a mathematical model that integrates geochemical and geomorphic processes responsible for soils'' elemental and mineralogical evolution on diverse landforms: eroding to depositional to level grounds. This new model combines a hillslope sediment mass balance and a soil geochemical mass balance. We model soils as the sum of a physically disturbed zone (PDZ) and the underlying physically undisturbed but chemically altered zone (CAZ). The model considers processes including the production of PDZ, weathering front propagation, mineral-specific dissolution, colloidal translocation, and colluvial transport. Thus this study serves to (1) review preexisting models of pedogenic processes and to (2) offer a framework to integrate the geochemical and geomorphic processes active in soils. We further discuss the implications of our model in (1) scaling chemical weathering reactions from mineral grains to pedons to soil catenas, (2) understanding the emergence of geochemical soil catenas, and (3) coupling physical and chemical weathering processes. [Copyright &y& Elsevier]

Published

2008

5. Evolution of hillslope soils: The geomorphic theater and the geochemical play

Author

Yoo, Kyungsoo, Weinman, Beth, Mudd, Simon Marius, Hurst, Martin, Attal, Mikael, and Maher, Kate

Subjects

*GEOMORPHOLOGY, *GEOCHEMISTRY, *CHEMICAL denudation, *SOIL erosion, *SOIL depth, *COSMOGENIC nuclides, *LANDSCAPES, *OPTICAL radar

Abstract

Abstract: How and how fast do hillslope soils form as the landscape’s morphology changes over time? Here results are shown from an ongoing study that simultaneously examines the morphologic and geochemical evolution of soil mantled hillslopes that have been exposed to distinctively different denudation history. In Northern Sierra Nevada, California, the authors are investigating a tributary basin to the Middle Fork Feather River. A major incision signal from the river is well marked in a knickpoint within the tributary basin which stretches from its mouth to the Feather River at an elevation of ∼700m to the plateau at an elevation of ∼1500m. Hillslopes are significantly steeper below the knickpoint. The area’s total denudation rates are currently being constrained using cosmogenic radio nuclides, but a previous study suggested an order of magnitude difference in total denudation rates below and above the knickpoint. When compared with topographic attributes calculated from LIDAR data, physical erosion rates can be modeled as a linear function of ridge top curvature. Surprisingly, over the wide range of total denudation rates, soil thicknesses do not vary significantly until a threshold point where soil mantled landscapes abruptly shift to bedrock dominated landscapes. Bioturbation by tree falls appear to buffer soil thickness over the wide range of physical soil erosion rates. From three hillslopes with different physical erosion rates, the concentrations of Zr, which were considered conserved during dissolution and leaching, were determined and used as a proxy for the degree of mass losses via chemical denudation. There is a general trend that colluvial soils along the hillslopes with lower physical erosion rates are enriched in fine size fractions, Zr, and pedogenic crystalline Fe oxides. Likewise, the saprolites show greater degrees of chemical denudation at the sites above the knickpoint, presumably because of the saprolites’ longer turnover time in the slowly eroding landscapes. In the two steep hillslopes below the knickpoint, no significant or systematic topgraphic trends were found for soil geochemistry. However, soils show increasing Zr enrichment in the downslope direction in the hillslope above the knickpoint, which suggests a critical denudation rate beyond which soils’ turnover time is too short to develop a geochemical catena. As detailed CRN-based soil production rates and catchment scale denudation rates are acquired, the data will be combined with a mass balance model to calculate the rates of chemical denudation and weathering in soils and saprolites along the denudation gradient. [Copyright &y& Elsevier]

Published

2011