SOIL GEOMORPHOLOGY FIELD STUDY
Geography 408

Fall Semester, 2001


Instructor: Dr. Randall Schaetzl
Office: 413 Natural Science
schaetzl@msu.edu
Office Hours: Tu, W 9:00-11:00, and immediately after class for as long as you wish, and by appt.
Mailbox: 314 Natural Science
Contacts, emergency or otherwise: Ph. 353-7726 (office)
347-0164 (home)

Texts: Birkeland, P.W. 1999. Soils and Geomorphology. 3rd edition. Oxford Univ. Press. (Required)

Schoeneberger, P.J., Wysocki, D.A., Benham, E.C., and W.D. Broderson. 1998. Field Book for Describing and Sampling Soils. Natural Resources Conservation Service, USDA, National Soil Survey Center, Lincoln, NE.

This book is out of print but can be downloaded from:
http://www.statlab.iastate.edu/soils/nssc/field_gd/field_gd.htm
I suggest downloading it and printing it out, laminating each page, and binding them together in a 3-ring or spiral binder. This is a great resource book.

Lectures: 7:00 - 8:50 W

Prerequisites (and they will be enforced): a grade of 2.0 or higher in any ONE or more of the following: CSS 210 or GEO 306 or GLG 201 or GLG 412 or ISP 203. This class is not open to freshmen or sophomores.

Course Goals: This course is intended for those students who have a basic background in physical geography, geology and/or soils, and who wish to advance their knowledge of soils, geomorphology and soil-environment interactions, especially in a field-based setting. The major goal of GEO 408 is to provide students with the ability to differentiate soils as they view them on the landscape, and to be able to propose scientifically sound reasons for these differences in morphology and chemistry, based primarily on landform-soil, stratigraphy-soil, and sediment-soil relationships. The course is designed to include a weekly lecture and several required field trips; the field trips will be discontinued by late October to allow time for work on individual field projects. Topics to be examined in GEO 408 include: (1) soil profile concepts and horizonation, (2) soil stratigraphy, (3) soil genesis, (4) soil geomorphology, (5) paleopedology and landscape evolution, (6) soil classification and taxonomy, and (7) soil mapping and the use of soil surveys. The course has a regional focus on Michigan and the midwest. The student is reminded that, because lectures provide important background information on the upcoming trip AND summarize important concepts from the previous trip, missing even one lecture unnecessarily can be very detrimental. Therefore, regular attendance at lecture is absolutely essential.

Field trips: Four trips are required. The field trips are the most essential and important part of any field course. They are invigorating, vital learning experiences. Missing a field trip will result in a loss of exposure to vital course material, which will come back to haunt you on the exams. Missing the 4-day trip will result in an automatic loss of 0.5 in the student's final grade. The trips are time-consuming and tiring, but remain the best (perhaps the only) way to really learn this material. Hence, you have the potential to get a great deal out of them; do not waste this opportunity by missing trips, partying at night such that you are dragging the next day, or by maintaining a negative or slip-shod attitude. MSU will cover most but not all of the cost of the trips; at the end of the semester the students will be notified of the amount they must contribute to defray the remaining expenses. Likely amount: $125 per person.

Grading: A total of 500 points can be earned in this course. Final grades are based on a curve of the student's overall point total. Points are assigned as follows:

Midterm exam 100 pts
Final exam 120 pts
Three quizzes 60 pts
Final field project 120 pts
Attitude, class and field trip participation, effort, brownie points, etc. 100 pts
TOTAL 500 points

Exams: There will be a midterm and final exam in GEO 408. The midterm will stress essential concepts covered in the field, with a small component of material from lecture. On the final exam only, students will have access to information they choose to write on one side of a 4x6 inch notecard. The final exam is cumulative. Both exams will be of essay/short answer format, with some objective questions or definitions. Exams will include material from the readings.

Quizzes: Three quizzes will be given during the semester. The quizzes will be announced at lecture of the previous week. Each will occur at the beginning of class, and will cover the outside readings assigned for that particular lecture or material previously assigned.

Readings: Most readings will come from Birkeland (B). Additionally, several research papers will be read during the term; these will be made available on the table outside my office (Rm. 413). Please do not remove these papers from the table area except to photocopy them! Generally, I expect everyone to have read the papers and text pages BEFORE the lectyure for which they are assigned. Overachievers are especially invited to read regularly and repeatedly from the text and the papers.(1)

General FIELD TRIP "RULES" for GEO 408:

1. Stay positive. Keep smiling despite rain, cold, mud, wet feet, cold feet, smelly feet, (apparently) dense, ditty, know-it-all, or obnoxious classmates, long drive-times, boredom, impatience, etc. No sourpusses or fussbudgets. Adhering to the above instructions will not only make the course more enjoyable, but you will learn more and earn more brownie points (see Grading above). Participation and discussion is an important part of this class/field experience. Questions are not only encouraged----they are expected.

2. Take diligent notes. Taking good field notes is a talent that is easy to acquire; it does not take a 160 IQ, only hard work. It will require you to work in the vehicle, rather than chit-chat with your classmates, sleep, or munch on Fritos. If you think you can write your notes when you return to Lansing, or at night after the trip is over, you are mistaken. I strongly encourage everyone to take notes in an weatherproof field book, obtainable from most book stores. The notebook might, for example, contain notes on soils, soil profile descriptions, stratigraphy, summary tables and other items. Within the notebook, basic soils data will be recorded. For example, soil series and taxonomic classification, topographic position (Ruhe nomenclature) and drainage class, field textures of major soil horizons, depth to carbonates where appropriate, moist color of major horizons, including mottling where applicable, soil structure, evidence of erosion, current land use practice, landform, and other pertinent information. It is suggested that the student compile the views of the group regarding the genesis of the soil, and how the soil relates to similar soils (as in a catena or development sequence).

3. Prepare for the worst possible weather conditions, without bringing undue amounts of clothing. Better to have rain gear and not need it. Better to wear heavy shoes and stay dry than to take a chance with your Reeboks and regret it. Bring a hat. When conditions are at their worst and you have NOT prepared adequately, refer back to rule #1.

4. Brownie and attitude points (see Grading above) can be earned by:

always being on time (or early) for field trips, both at the main departure from Natural Science and at each individual stop, paying for the field trips well before the stated deadline, volunteering to dig or turn the auger, drive (where appropriate), navigate, or pack and load the vehicle, maintaining a serious attitude about the field learning experience, cheerfully awakening in the morning and not being the last one to be ready to depart, not being so hung over that you are a liability to the class and yourself, assisting the professor in picking up or dropping off the van, etc.

5. Equipment. Field notebook, pen/pencil are required. If you have a non-folding pocket knife, bring it. (Some will be provided.) Cameras are OK.

Final field project: Each student will do a final project an a topic of their choice. The most likely project will consist of (1) intensive mapping and interpretation of the soils and sediments of a small area, (2) a detailed analysis of soil survey maps and data in relations to landscape evolution and geomorphology, or (3) effects of some type of land use change on soils. Any good idea will be considered. Thesis/dissertation-related projects are acceptable, as long as they beyond what you would have normally done for your thesis research. Each student must receive approval of the topic by the professor prior to intensive field work, but some field work may be required before the topic is "broached" with the professor, and/or before final approval is given. Students that do not have access to transportation will find this component of the course more difficult to satisfy. The projects will be graded based on a short (generally < 6 pages of text, not including data tables, references and maps if appropriate) written report. Working with a GEO 408 partner is acceptable; such projects will be expected to be substantially larger in scope than individual ones. All units in the paper must be in the metric or SI system. Spelling and grammar count! References need not be abundant, but some indication of a knowledge of the literature on the topic should be evidenced. Papers are due at the final exam.


LECTURE AND FIELD TRIP OUTLINE

DATE TOPICS READINGS

Aug 29 Introduction, soil characteristics and concepts, soil horizons; Functional-factorial model of soil development B: 1-13; 141-145; Paper 1
Sep 5 Process-systems model of soil development, soil horizonation B: Ch. 6; Papers 2 & 9
Sep 12 Melanization and leucinization, profile acidification
TRIP 1: Organic vs mineral soils; horizonation concepts; catena concepts; soil texture and structure; soil drainage classes (Friday Sep 14)
B: Ch. 6; 107-108
Sep 19 Lessivage and Bt horizon formation
TRIP 2: Soils of extreme SW Michigan and the SW Michigan interlobate area (Sunday Sep 23)
B: 112-120; Papers 6 & 16
Sep 26 Podzolization, review of Michigan's geomorphic history B: 108-112; Papers 3, 4, 7, 18 & 19
Oct 3 Gleization, ferrolysis, hydroconsolidation and fragpian formation
TRIP 3: Podzolization, soil geomorphology of northern lower Michigan (Thursday through Sunday, Oct 4-7)
B: 121; 134-137; Papers 13 &14
Oct 10 Pedogenic processes in dry environments B: 127-134; Paper 20
Oct 17 Midterm exam  
Oct 24 Soil development and soil chronosequences
TRIP 4: Soil-landform relationships on and near the Saginaw lake Plain (Saturday and Sunday Oct 27-28)
B: 178-182; 200-208; 214-221; Paper 8
Oct 31 Models of soil and landscape evolution B: 145-147; 226-229; Papers 5 & 11
Nov 7 Catenas and the effects of topography on soil development B: Ch. 9
Nov 14 Soil classification and mapping B: Ch. 2
Nov 21 Use and interpretation of NRCS Soil Surveys  
Nov 28 Pedoturbation and lithologic discontinuities Papers 10, 12 & 16
Dec 5 Soil gemorphology and paleopedology B: 24-28; 253-257; 339-346; Paper 15
Dec 12 FINAL EXAM (8:00 pm, in Rm 409)
Research papers due!
 

REQUIRED PAPERS

Paper 1: Hole, F.D. 1997. The Earth beneath our feet: Explorations in community. Soil Survey Hor. 38:40-53.

Paper 2: Richter, D.D. and D. Markewitz. 1995. How deep is soil? Bioscience 45:600-609.

Paper 3: Farrand, W.R. 1988. The Glacial Lakes around Michigan. Mich. DNR, Geol. Survey Div. Bulletin 4. 17 pp.

Paper 4: Freeland, J.A. and C.V. Evans. 1993. Genesis and profile development of Success soils, northern New Hampshire. Soil Sci. Soc. Am. J. 57:183-191.

Paper 5: Johnson, D.L. and D. Watson-Stegner. 1987. Evolution model of pedogenesis. Soil Sci. 143:349-366.

Paper 6: Rostad, H.P.W., Smeck, N.E., and L.P. Wilding. 1976. Genesis of argillic horizons in soils derived from coarse-textured calcareous gravels. Soil Sci. Soc. Am. J. 40:739-744.

Paper 7: Schaetzl, R.J. and S.A. Isard. 1991. The distribution of Spodosol soils in southern Michigan: a climatic interpretation. Annals Assoc. Am. Geogs. 81:425-442.

Paper 8: Arbogast, A.F., Scull, P., Schaetzl, R.J., Harrison, J., Jameson, T.P., and S. Crozier. 1997. Concurrent stabilization of some interior dune fields in Michigan. Phys. Geog. 18:63-79.

Paper 9: Simonson, R.W. 1959. Outline of a generalized theory of soil genesis. Soil Sci. Soc. Am. Proc. 23:152-156.

Paper 10: Johnson, D.L., Watson-Stegner, D., Johnson, D.N., and R.J. Schaetzl. 1987. Proisotropic and proanisotropic processes of pedoturbation. Soil Sci. 143:278-292.

Paper 11: Huggett, R.J. 1998. Soil chronosequences, soil development, and soil evolution: a critical review. Catena 32:155-172.

Paper 12: Schaetzl, R.J. 1998. Lithologic discontinuities in some soils on drumlins: Theory, detection, and application. Soil Sci. 163:570-590.

Paper 13: Smeck, N.E., Thompson, M.L., Norton, L.D., and M.J. Shipitalo. 1989. Weathering discontinuities: A key to fragipan formation. In: Fragipans: Their Occurrence, Classification, and Genesis. Soil Sci. Soc. Am. Spec. Publ. 24:99-112.

Paper 14: Bryant, R.B. 1989. Physical processes of fragipan formation. In Fragipans Their Occurrence, Classification, and Genesis. N.E. Smeck and E.J. Ciolkosz (eds.). Soil Sci. Soc. Am. Spec. Publ. 24:141-150.

Paper 15: Olson, C.G. 1989. Soil geomorphic research and the importance of paleosol stratigraphy to Quaternary investigations, midwestern USA. Catena Suppl. 16:129-142.

Paper 16: Schaetzl, R.J. 1996. Spodosol-Alfisol intergrades: bisequal soils in NE Michigan, USA. Geoderma 74:23-47.

Paper 18: Schaetzl, R.J., Krist, F., Rindfleisch, P., Liebens, J., and T. Williams. 2000. Postglacial landscape evolution of northeastern lower Michigan, interpreted from soils and sediments. Annals Assoc. Am.. Geog. 90:443-466.

Paper 19: Buurman, P. and L.P. van Reeuwijk. 1984. Proto-imogolite and the process of podzol formation: A critical note. J. Soil Sci. 35:447-452.

Paper 20: Gile, L.H., Peterson, F.F., and R.B. Grossman. 1966. Morphological and genetic sequences of carbonate accumulation in desert soils. Soil Sci. 101:347-360.