1. Soil Under the Microscope: A Micromorphology Primer Steve Driese, Baylor University

2. Introduction What is soil “micromorphology”? Why is it useful for interpreting genesis of soils? Integrate in undergraduate sedimentary petrology class, or as part of a soils course? Can be applied interpreting soil drainage, soil maturity, hydrogeology, and contaminant fate and transport.

3. What is “Micromorphology”? Application of basic geologic thin-section petrography to the study of soils and paleosols Terminology differences can seem daunting! Pledger series Vertisol on 6,000 yr-old floodplain surface, Dance Bayou, Brazoria County, TX

4. You may feel like it’s too much to swallow!....... But just hang in there.

5. Basic Terminology At the very basic level soil consists of: 1. Soil matrix, termed “S-matrix” by soil scientists. 2. Pedological features with origins related to soil-forming processes.

6. Example from Brewer’s (1976) Micromorphology textbook

7. From Brewer (1976): Soil Matrix 1. Plasma, mainly fine clay-sized mineral particles, but also including organic material of colloid size, which may be soluble, 2. Skeleton grains, chiefly silicate sand and silt grains embedded in the plasma, which are generally stable, and 3. Soil voids, which are pore spaces occupied by air or water, and include: (A) Macropores (>1-2 µm) such as root pores, animal burrows, interpedal and fracture pores, and (B) Micropores (< 1-2 µm).

8. Pedological Features 1.Inherited Features: lithorelicts (pieces of parent material), saprorelicts (saprolitized parent material) and pedorelicts (reworked soils). 5.5 mm, XPL 1.5 mm, PPL

9. Pedological Features 2. Features due to plasma concentrations: nodules (non-banded and layered) and concretions (banded and layered), 1.5 mm, XPL

10. Pedological Features 3. Features due to plasma separations: cutans (coatings in voids or on grain surfaces), sepic-plasmic fabrics (bright- or flecked clays) and crystic plasmic fabrics (crystals showing displacive growth), 1.5 mm, PPL XPL

11. Pedological Features 3. Features due to plasma separations: cutans (coatings in voids or on grain surfaces), sepic-plasmic fabrics (bright- or flecked clays) and crystic plasmic fabrics (crystals showing displacive growth), XPL

12. Pedological Features 3. Features due to plasma separations: cutans (coatings in voids or on grain surfaces), sepic-plasmic fabrics (bright- or flecked clays) and crystic plasmic fabrics (crystals showing displacive growth), 0.5 mm, XPL 1.5 mm, XPL

13. Pedological Features 3. Features due to plasma separations: cutans (coatings in voids or on grain surfaces), sepic-plasmic fabrics (bright- or flecked clays) and crystic plasmic fabrics (crystals showing displacive growth), 1.5 mm, XPL 0.5 mm, XPL 1.5 mm, XPL

14. Pedological Features 4. Features due to biological activity: (biotic tubules filled with various kinds of soil materials, including fecal materials), PPL UV Fluorescence

15. Pedological Features 4. Features due to biological activity: (biotic tubules filled with various kinds of soil materials, including fecal materials), 1.5 mm, XPL

16. Pedological Features 4. Features due to biological activity: (biotic tubules filled with various kinds of soil materials, including fecal materials), 1.5 mm, PPL

17. Pedological Features: Paleosol Examples – Illuviated clays XPL

18. Pedological Features: Paleosol Examples – Rhizolith PPL

19. Pedological Features: Paleosol Examples – Carbonized roots XPL

20. Pedological Features: Paleosol Examples – Fe-depletion root PPL

21. Pedological Features: Paleosol Examples – Rhizolith + Fe depletion root trace 7 cm, PPL Calcite rhizolith around silt- and clay- infilled root trace Redox-depletion and enrichment quasi-coatings with root trace 5.5 mm, PPL

22. Pedological Features: Paleosol Examples – Sepic-plasmic fabrics 0.5 mm, XPL

23. Pedological Features: Paleosol Examples – Fe-Mn concretions 1.5 mm, PPL 1.5 mm, XPL

24. Pedological Features: Paleosol Examples – Calcite nodule XPL

25. Pedological Features: Paleosol Examples – Meniscate burrow PPL

26. Pedological Features: Paleosol Examples – Thecate amoebae UV Fluorescence

27. A Hierarchical Approach to Thin-Section Description (after Bullock et al., 1985)

28. Micromorphology 1. Useful, for evaluating soil mineralogy, genesis, and diagenetic processes (Cady et al., 1986). 2. Inexpensive, simple: the cost of a thin- section and a petrographic microscope. 3. Essential precursor for followup analytical procedures (e.g., geochemistry, isotopes).

29. Questions?

30. References Cited Brewer, R., 1976, Fabric and Mineral Analysis of Soils, 2nd edition: Huntington, New York, Robert E. Krieger Publishing Co., 482 p. Bullock, P, Fédoroff, N., Jungerius, A., Stoops, G., Tursina, T., and Babel, U., 1985, Handbook for Soil Thin Section Description: Wolverhampton, UK, Waine Research Publications, 152 p. Cady, J.G., Wilding, L.P., and Drees, L.R., 1986, Petrographic microscope techniques, in Methods of Soil Analysis, Part I. Physical and Mineralogical Methods: Soil Science Society of America, Monograph No. 9, p. 185-218. Stoops, G., 2003, Guidelines for Analysis and Description of Soil and Regolith Thin Sections: Madison, WI, Soil Science Society of America, 184 p. + CD w/images. Stoops, G., Marcelino, V., and Mees, F. (eds.), 2010, Interpretation of Micromorphological Features of Soils and Regoliths: Amsterdam, Elsevier Pub. Co., 720 p.