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Holocene loess deposition and soil formation as competing processes, Matanuska Valley, southern Alaska. Presented By: Jason Windingstad. Adapted from a publication by:. Daniel R. Muhs, John P. McGeehin, Jossh Beann, and Eric Fisher. Objectives.
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Holocene loess deposition and soil formation as competing processes, Matanuska Valley, southern Alaska Presented By: Jason Windingstad
Adapted from a publication by: Daniel R. Muhs, John P. McGeehin, Jossh Beann, and Eric Fisher
Objectives • Identify loess sedimentation as a competing factor against soil formation • Show that loess sedimentation was episodic during the Holocene • Show increased soil development with distance from Loess source through chemical and physical data
Introduction Loess is the most widely distributed sediment of Quaternary age in Alaska (Pewe, 1975) Loess-paleosol sequences represent an important record of climate change during the Quaternary
Distribution of Loess in Alaska D.R. Muhs et al. / Quaternary Research 61 (2004)
Active Loess Deposition, Matanuska Valley Photo by Warren Huff. Taken from: tvl1.geo.uc.edu/ ice/Image/propro/32.html
Geographic Setting • Glacial drift and loess mantled trough • MAP = 393mm • APE = 466mm • MAT = 1.9 degrees C • Spruce-dominated boreal forest • Knik and Matanuska Glaciers still active • Summer winds 3.9-5.7 m/s • Winter winds 3.3-4.0 m/s D.R. Muhs et al. / Quaternary Research 61 (2004)
Loess Deposition and Soil Formation in the Matanuska Valley • Previous studies in the mid-continent of North America, show the degree of soil development in loess derived soils increases as a function of distance downwind from the source area. (Ruhe, 1969) • Soils in the Matanuska Valley near the source area are classified as Entisols or Inceptisols while soils at more distal localities are Spodosols.
Spodosols • “White Earths” • Humid boreal climatic zones • Typically coarse textured parent materials • O,A,E,Bs(Bh or Bhs) horizons • Podzolization primary pedogenic process • Fully developed Spodosols have formed within 300 yrs in SE Alaska (Buol et al., 2003) cropandsoil.oregonstate.edu/.../ slides.html
Inceptisol • Weakly expressed profile features • A, Bw, C horizons • Develop in a variety of climates • Common soil in areas of high relief and on younger land forms (Boul et al., 2003) cropandsoil.oregonstate.edu/.../ slides.html
Purpose of Study • Determine when episodes of loess deposition began during the Holocene • Explore the relationship between loess deposition and soil development in an active eolian environment. • Identify loess deposition and soil formation as a competing process
Methods • Loess sections were described from river cut banks, road cuts, and hand dug pits • Charcoal and wood fragments were radiocarbon dated by accelerator mass spectrometry • Soil and Sediment was sampled by horizon for particle size, bulk mineralogy, and geochemistry • Semiquantitative mineralogy was determined by X-ray diffractometry • Concentrations of select major elements of bulk soil samples were determined by energy-dispersive X-ray fluorescence
Stratigraphy and Sedimentology D.R. Muhs et al. / Quaternary Research 61 (2004)
Particle Size vs. Distance From Source D.R. Muhs et al. / Quaternary Research 61 (2004)
Loess Thickness vs. Distance From Source D.R. Muhs et al. / Quaternary Research 61 (2004)
Chemical Weathering • Optical examination along with X-ray diffraction analysis indicate that the dominant minerals of the coarse silt fraction in the unaltered Loess are quartz, plagioclase, mica, chlorite, and hornblende (K-feldspar is also present in small amounts) • Plagioclase, mica, chlorite, and hornblende undergo rapid alteration under low pH conditions with sufficient precipitation
Mobile-to-Immobile Elemental Ratios • Previous studies by Muhs et al., 2001 indicate that certain major elemental ratios in loess-derived soils of the Mississippi River Valley give useful proxies for mineral depletions and thus the degree of chemical weathering that has taken place. • The elemental ratios in the Matanuska valley soils should show a similar trend
Titanium as an Immobile Element • Immobile elements are residually enriched in comparison to the more mobile elements released from soluble mineral phases in leached zones of a soil profile (Stiles et al., 2003). • Ti and Zr are commonly considered immobile due to the insoluble nature of the minerals they are concentrated in e.g. zircon ZrSiO4 and rutile/anatase TiO2 (Stiles et al., 2003)
Elemental Ratios for Matanuska Valley Loess D.R. Muhs et al. / Quaternary Research 61 (2004)
Translocation of Fe vs. Distance From Source • Through the process of Podzolization; Fe, Al, and organic matter under low pH conditions and the presence of chelates migrate from O,A and E horizons into B horizons. • Total Fe2O3 should increase in B horizons with distance from the source
Fe2O3% D.R. Muhs et al. / Quaternary Research 61 (2004)
Pedogenic Pathway D.R. Muhs et al. / Quaternary Research 61 (2004)
Conclusions • Radiocarbon dating suggests loess accumulation began after 6500 C14 yr B.P. • Loess sedimentation was episodic during Holocene • Stratigraphic complexity is at a maximum at intermediate distances from the source • Textures change drastically with distance from the source area • Mobile elements decrease in surface horizons with distance • Systematic increases in chemical weathering and Spodosol formation over the Holocene time scale are unexpected results
References • Muhs, D.R., J.P. McGeehin, J. Beann, and E. Fisher. 2004. Holocene loess deposition and soil formation as competing processes, Matanuska Valley, southern Alaska. Quaternary Research 61:265-276. • Pe´we´, T.L., 1975. Quaternary Geology of Alaska. U.S. Geological Survey Professional Paper, 835. • Muhs, D.R., Bettis III, E.A., Been, J., McGeehin, J., 2001b. Impact of climate and parent material on chemical weathering in loess-derived soils of the Mississippi River Valley. Soil Science Society of America Journal 65, 1761–1777. • Ruhe, R.V., 1969a. Application of pedology to Quaternary research. In: Pawluk, S. (Ed.), Pedology and Quaternary Research. National Research Council of Canada and University of Alberta, Edmonton, pp. 1 –23. • Buol, S. W., R. J. Southard, R. C. Graham, and P. A. McDaniel. 2003. Soil Genesis and Classification, 4th ed. Iowa State Univ. Press, Ames. • Stiles, C.A., C. I. Mora, and S. G. Driese. 2003. Pedogenic processes and domain boundaries in a Vertisol climosequence: evidence from titanium and zirconium distribution and morphology. Geoderma 116: 279-299.