Seatearth is a British coal mining term, which is used in the geological literature. As noted by Jackson,[1] a seatearth is the layer of sedimentary rock underlying a coal seam. Seatearths have also been called seat earth, "seat rock", or "seat stone" in the geologic literature. Depending on its physical characteristics, a number of different names, i.e. underclay, "fireclay", flint clay, and "ganister" can be applied to a specific seatearth.


Underclay is a seatearth composed of soft, dispersible clay, or other fine-grained sediment, either immediately underlying or forming the floor of a coal seam. Underclay typically contains the fossil roots and exhibits noticeable development soil structures. It often has been noticeably altered due to weathering. Underclays, which occur within Carboniferous coal measures, commonly contain Stigmarian roots. Synonyms for underclay included seat clay, root clay, thill, warrant, coal clay, and warrant clay[1]

Underclays typically show considerable evidence of having been altered by plant activity and soil forming processes and are either in whole or part buried soils, called paleosols. As documented in various detailed studies[2][3][4][5] of underclays, underclays and seat earths typically exhibit features characteristics of soil profile development. Depending on the specific underclay, these soil features can include some combination of pedogenic slickensides, pedogenic ped structures, illuviated clay pore fillings, different types of pedogenic microfabrics, rhizocretions, caliche nodules, root molds, and soil horizons. In the better-developed paleosols, significant alteration of the mineralogy, i.e. leaching and translocation of alkali and alkaline earth elements and the kaolinitization of smectites and hydroxy-interlayer vermiculite, will have occurred. In poorly developed paleosols, as seen in the soil profiles of modern poorly developed soils, called "Inceptisols", of modern river deltas and floodplains, there might not exist any noticeable alteration of the underclay. These studies demonstrate that a paleosol, which is either developed in or comprises underclay, largely reflects the effects of plants and other soil forming processes on the underclay while it formed the ground surface prior to being buried by organic sediments. Plant growth, waterlogging, and other processes, which occurred during the development of a mire or swamp, in which a layer of peat accumulated that later became the overlying coal, modified the paleosol to create an underclay[2][6][7]

Fire clay

Underclay, which consists of siliceous refractory clay rich in hydrous aluminium silicates, is also called fireclay. Just as not all underclays are fireclays, not all fireclays are underclays.[1][8] Within Carboniferous and other coal bearing strata, fireclay quite commonly comprises many underclays. In Great Britain underclays, which are 1 to 3 metres ( 3 to 9 feet) thick, are major source of commercial fireclay deposits. The alteration of sediments by weathering, plants, and other soil processes comprising underclay resulted in the formation of vast majority of fireclay that comprises underclay.

Flint clay

Another clay associated with coal beds is a smooth, flintlike refractory clay or mudstone composed dominantly of kaolin, called "flint clay". Flint clay breaks with a pronounced conchoidal fracture and resists slaking in water.[1]

Flint clay can be either detrital or authegenic in origin. Detrital flint clays consist of kaolinite-rich sediments eroded and transported from uplands deeply weathered under tropical climates and redeposited within the coastal plains, in which coal-bearing strata accumulated. Authegenic flint clays consist of sediments altered in place after deposition as beds within acid, organic sediments, i.e. peat, accumulating within swamps and mires.

Flint clays associated with coal typically occur as thin, laterally continuous layers (bands), called "tonsteins", found within coal beds. At least, in case of tonsteins found within coal, the formation of flint clays resulted from the alternation of glass comprising volcanic ash by acid waters after it accumulated as thin beds within peat swamps or mires.[9][10]


In addition to underclays, ganisters also occur as seatearths. Like fireclays, they also found within Carboniferous and other sedimentary strata independent of coal beds. Thus, as in case of fireclays, not all ganisters are seatearths. Ganisters are indurated, fine-grained quartzose sandstones, which can be used in the manufacture of silica brick. It is cemented with secondary silica and has a characteristic splintery fracture.[1][8]

As defined, ganisters can either be created by either the cementation of quartzose by surficial soil-forming processes to form silicrete or by diagenetic cementation within the subsurface. Detailed studies of ganisters, which occur either as seatearths or elsewhere within coal-bearing strata, have found them to be ancient paleosols, which are equivalent in both physical characteristics and origin to modern silica-cemented soils, called silcretes.[11][12][13] The modern equivalent of ganisters have been observed in the process of being formed in the Okavango Delta of Botswana.[14]


  1. 1 2 3 4 5 Jackson, J.A., 1997, Glossary of geology, 4th ed. American Geological Institute, Alexandria. ISBN 0-922152-34-9
  2. 1 2 Driese, S.G., and E.G. Ober, 2005, Paleopedologic and paleohydrologic records of precipitation seasonality from Early Pennsylvanian "underclay" paleosols, U.S.A., Journal of Sedimentary Research. v. 75, no. 6, pp. 997-1010.
  3. Huddle, J.W., and S.H. Patterson, 1961, Origin of Pennsylvanian underclay and related seat rocks, Geological Society of America Bulletin. vo. 72, pp. 1643-1660.
  4. Joeckel, R.N., 1995a, Paleosols below the Ames marine unit (Upper Pennsylvanian, Conemaugh Group) in the Appalachian Basin, U.S.A.: variability on an ancient depositional landscape, Journal of Sedimentary Research. v. A65, no. 2, pp. 393-407.
  5. Joeckel, R.M., 1995b, Tectonic and paleoclimatic significance of a prominent upper Pennsylvanian (Virgilian/Stephanian) weathering profile, Iowa and Nebraska, USA, Palaeogeography, Palaeoeclimatology, Palaeoecology. v. 118, pp. 159-179.
  6. Gardner, T.W., E.G. Williams, and P.W. Holbrook, 1988, Pedogenesis of some Pennsylvanian underclays; ground-water, topography, and tectonic controls in J. Reinhardt and W.R. Sigleo, eds., Paleosols and Weathering Through Geologic Time: principles and Applications. Geological Society of America Special Paper. no. 216, pp. 81-102. ISBN 0-8137-2216-0
  7. Ober, E.G.., and S.G. Driese, 2003, The palehydrologic history of coal underclays based upon Pennsylvanian paleosols in eastern Tennessee. Geological Society of America Abstracts with Programs v. 35, no. 6, p. 601
  8. 1 2 United States Bureau of Mines and American Geological Institute, 1996, Dictionary of mining And mineral-related terms. Mines Bureau Special Publication SP 96-1, 2nd ed, United States Bureau of Mines.
  9. Burger, K., and H.H. Damberger, 1985, Tonsteins in the Coalfields of Western Europe and North America. in Compte Rendu 4:433-448, IXICC International Congress on Carboniferous Stratigraphy and Geology, Southern Illinois University Press.
  10. Outerbridge, W.F., 2003, Isopach map and regional correlations of the Fire Clay tonstein, central Appalachian Basin. Open-File Report 03-351. United States Geological Survey.
  11. Gibling, M.R., and B.P. Rust, 1992, Silica-cemented paleosols (ganisters) in the Pennsylvanian Waddens Cove Formation, Nova Scotia, Canada in K.H. Wolf and G.V. Chilingarian, George, eds., Diagenesis, III. Developments in Sedimentology. v. 47, pp. 621-655 ISBN 0-444-88516-1
  12. Perciveil, C.J., 1982, Paleosols containing an albic horizon: examples from the upper Carboniferous of northern Britain in V.P. Wright, ed., pp. 87-111, Paleosols: Their Recognition and Interpretation. Princeton, Princeton University Press ISBN 0-691-08405-X
  13. Percival, C.J., 1983, The Firestone Sill Ganister, Namurian, northern England—the A2 horizon of a podzol or podzolic palaeosol, Sedimentary Geology. v. 36, no. 1, pp. 41-49.
  14. McCarthy, T.S. and W.N. Ellery, 1995, Sedimentation on the distal reaches of the Okavango Fan, Botswana, and its bearing on calcrete and silcrete (ganister) formation, Journal of Sedimentary Research. vol. A65, no. 1, pp. 77-90.
This article is issued from Wikipedia - version of the 3/31/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.