Data dictionary for file 'pedon01', S3C Database, Version 20040427

[USGS, United States Geological Survey; USDA, United States Department of Agriculture; NRCS, Natural Resources Conservation Service; STATSGO, State Soil Geographic; SSURGO, Soil Survey Geographic; VARIABLE FORMAT--Dw.d, where D=data type (C, character; F, floating point; I, integer), w=field width, d=precision; FIPS, Federal Information Processing Standard; NAD, North American Datum; DMS, degrees, minutes, seconds; DD, decimal degrees; %, weight percent; cm, centimeter; mm, millimeter; g cm-3, grams per cubic centimeter; kg m-2, kilograms per square meter; SU, standard pH unit; kPa, kilopascal.  Where variable names have the italicized suffix hh, there is a separate variable in the database for each of the following depth intervals:  0-10 cm (hh = 01), 0-20 cm (hh = 02), 0-50 cm (hh = 05), 0-100 cm (hh = 10), 10-20 cm (hh = 12), 20-50 cm (hh = 25), 50-100 cm (hh = 51).  The methodology for computing standard-interval values is presented in Buell and Markewich (2004, footnote 8).]

VARIABLE NAME

VARIABLE FORMAT (Dw.d)

DEFINITION

UNITS

pedkey

C16

Combination of 'source' and 'idped'.  Primary key ('pedon01' table) linking pedon and horizon ('horiz01' table) records.

source

C4

Origin of source dataset (danl, feld, lasu, nssc, uark, uiuc)¹.

idfips

C5

Concatenation of two-letter state abbreviation and county FIPS code.

idped

I9

4-digit calendar year the pedon was sampled * 100000 + a unique pedon identifier.

series

C32

Soil series to which the pedon was classified, either by NRCS or by USGS using NRCS soil series data and USDA-NRCS STATSGO⁶/SSURGO⁷ digital soil maps or published USDA-NRCS county soil surveys.  For details on soil-series name assignments, see Buell and Markewich (2003, footnote 8).  Taxonomic link to 'taxon01' table.

year

I4

Year the pedon samples were collected.

county

C32

County in which the pedon samples were collected.

lat

C7

Latitude of pedon location.  Datum NAD27.

DMS

long

C8

Longitude of pedon location.  Datum NAD27.

DMS

dlat

F12.6

Decimal latitude of pedon location.  Datum NAD27.

DD

dlong

F12.6

Decimal longitude of pedon location.  Datum NAD27.

DD

numlayer

I10

Number of mineral horizons in the pedon.

sand_hh

F10.1

Mass-weighted⁸ mean weight percent (2 mm base, air-dried sample) of particles >0.05 mm and <2.0 mm diameter in the hh cm depth interval measuring downward from the mineral surface (USDA system for classification of soils and sample particle-size data)^2,3.

%

silt_hh

F10.1

Mass-weighted⁸ mean weight percent (2 mm base, air-dried sample) of particles >0.002 mm and <0.05 mm diameter in the hh cm depth interval measuring downward from the mineral surface (USDA system for classification of soils and sample particle-size data)^2,3.

%

clay_hh

F10.1

Mass-weighted⁸ mean weight percent (2 mm base, air-dried sample) of particles <0.002 mm diameter in the hh cm depth interval measuring downward from the mineral surface (USDA system for classification of soils and sample particle-size data)^2,3.

%

txclpshh

C8

Texture class of soil based on the mass-weighted⁸ mean particle size data (total sand+silt+clay) in the hh cm depth interval measuring downward from the mineral surface (USDA system for classification of soils and sample particle-size data)^2,3.

bd3_hh

F10.2

Mass-weighted⁸ mean bulk density (2 mm base) of natural clods (desorbed to 1/3 bar [33 kPa] tension water content^2,3) in the hh cm depth interval measuring downward from the mineral surface.

g cm^-3

bdod_hh

F10.2

Mass-weighted⁸ mean bulk density (2 mm base) of natural clods (oven-dried at 105^oC^2,3) in the hh cm depth interval measuring downward from the mineral surface.

g cm^-3

caco3_hh

F10.2

Mass-weighted⁸ mean weight percent carbonate expressed as equivalent CaCO₃ (2 mm base, air-dried sample) in the hh cm depth interval measuring downward from the mineral surface.  Carbonate calculated from manometric measurements of  CO₂ evolved from HCl-treated samples^2,3. 

%

phh2o_hh

F10.1

Mass-weighted⁸ mean pH equivalent (2 mm base, air-dried sample; pH based on mean hydrogen-ion activity) in the hh cm depth interval measuring downward from the mineral surface. pH is measured in a 1:1 mixture of soil and distilled water^2,3.

SU

w15ad_hh

F10.2

Mass-weighted⁸ mean weight percent gravimetric water content (2 mm base, air-dried sample equilibrated at 15 bar [1500 kPa] tension) in the hh cm depth interval measuring downward from the mineral surface^2,3.

%

oc_hh

F10.2

Mass-weighted⁸ mean weight percent organic carbon (2 mm base, air-dried sample) in the hh cm depth interval measuring downward from the mineral surface. Generally, pre-1995 organic-carbon measurements were done by the Walkley-Black method^2,3,4; since 1995 most organic-carbon measurements have been made by dry-combustion to CO² with quantitation by infrared absorption^2,3.

%

ocmc_hhc

F10.2

Mass of organic carbon (2 mm base, 1/3-bar bulk density) in the hh cm depth interval measuring downward from the mineral surface⁸.

kg m^-2

smc_hhc

F10.2

Mass of soil (2 mm base, 1/3-bar bulk density) in the hh cm depth interval measuring downward from the mineral surface⁸.

kg m^-2

svsg_hh

I10

Soil volume (whole-soil base) in the hh cm depth interval in a unit volume of one square meter one centimeter thick (10000 cm³).  This volume is calculated from the coarse-fragment data for each soil series in the USDA-NRCS STATSGO⁶/SSURGO⁷ databases.  When multiple records exist for a series, median values are used⁸.  The calculated soil volume is used to adjust mass storage for the rock volume in the soil profile.

cm³

stempcl

C16

Soil temperature class--soil category based on mean annual or seasonal soil temperatures as defined by the USDA NRCS⁵.

smregime

C16

Soil moisture regime as defined by the USDA NRCS⁵.

calrecl

C12

Calcareous reaction class--soil category based on the presence or absence of carbonate, soil reaction, and aluminum concentration as defined by the USDA NRCS^5.

mincl

C16

Mineral class--soil category based on the mineralogy of one or more of particle-size components of a soil as defined by the USDA NRCS⁵.

soilfam

C132

Soil family--the fifth highest level of soil taxonomic classification (subdivision of soil subgroup) as defined by the USDA NRCS⁵.

  1/ danl, Daniels, W.L., Everett, C.J., and Zelazny, L.W., 1987a, Virgin hardwood forest soils of the southern Appalachian Mountains:  I. Soil morphology and geomorphology:  Soil Science Society of America Journal, v. 51, p. 722-729, or Daniels, W.L., Everett, C.J., and Zelazny, L.W., 1987b, Virgin hardwood forest soils of the southern  Appalachian Mountains:  II. Weathering, mineralogy, and chemical properties:  Soil Science Society of America Journal, v. 51, p. 730-738.

     feld, Feldman, S.B., Zelazny, L.W., and Baker, J.C., 1991a, High-elevation forest soils of the southern Appalachians:  I. Distribution of parent materials and soil-landscape relationships:  Soil Science Society of America Journal, v. 55, p. 1629-1637, or Feldman, S.B., Zelazny, L.W., and Baker, J.C., 1991b, High-elevation forest soils of the southern Appalachians:  II. Geomorphology, pedogenesis, and clay mineralogy:  Soil Science Society of America Journal, v. 55, p. 1782-1791, or Feldman, S.B. 1989, Taxonomy, genesis, and parent material distribution of high elevation forest soils in the southern Appalachians: unpublished M.S. thesis, Virginia Polytechnic Institute and State University, Blacksburg, VA,  Appendix B, or Feldman, S.B., unpublished data, provided to USGS in 2000.

     lasu, Schumacher, B.A., Day, W.J., Amacher, M.C., and Miller, B.J., 1988, Soils of the Mississippi River alluvial plain in Louisiana: Louisiana State University Agricultural Center, Baton Rouge, LA, Louisiana Agricultural Experiment Station Bulletin No. 796, 275 p.

     nssc, U.S. Department of Agriculture, Natural Resources Conservation Service, 2001, National Soil Characterization Database, accessed September 1, 2001, at URL http://ssldata.nrcs.usda.gov/.

     uark, University of Arkansas, 2000, unpublished data, Soil Characterization Laboratory, Fayetteville, AR, provided to USGS, 1999-2000.

     uiuc, University of Illinois, 2001, Soil Characterization Database, Soil Characterization Laboratory, Urbana-Champaign, IL, accessed February 15, 2001, at URL http://www.il.nrcs.usda.gov/technical/soils/soil_lab.html.

  2/ Soil Survey Staff, 1995, Soil survey laboratory information manual:  U.S. Department of Agriculture, Natural Resources Conservation Service, National Soil Survey Center, Lincoln, NE, Soil Survey Investigations Report No 45, version 1, 305 p.

  3/ Soil Survey Staff, 1996, Soil survey laboratory methods manual : U.S. Department of Agriculture, Natural Resources Conservation Service, Soil Survey Investigations Report No. 42, version 3, 693 p.

  4/ Walkley A., 1935, An examination of methods for determination of organic carbon and nitrogen in soils:  Journal of Agricultural Science, v. 25, p. 598-609.

  5/ Soil Survey Staff, 1998, Keys to soil taxonomy, 8th ed.: U.S. Department of Agriculture, Natural Resources Conservation Service, 328 p.

  6/ U.S. Department of Agriculture, Natural Resources Conservation Service, 2001, State Soil Geographic (STATSGO) Database, accessed September 1, 2001, at URL http://www.ncgc.nrcs.usda.gov/branch/ssb/products/statsgo/index.html.

  7/ U.S. Department of Agriculture, Natural Resources Conservation Service, 2001, Soil Survey Geographic (SSURGO) Database, accessed September 1, 2001, at URL http://www.ncgc.nrcs.usda.gov/branch/ssb/products/ssurgo/index.html.

  8/ Buell, G.R. and Markewich, H.W., in press, Data compilation, synthesis, and calculations used for organic-carbon storage and inventory estimates for mineral soils of the Mississippi River basin, chap. A of Markewich, H.M., ed., Soil-carbon storage and inventory for the continental United States:  U.S. Geological Survey Professional Paper 1686.