Blockfield

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Felsenmeer in Lautertal-Reichenbach (Odenwald)
Felsenmeer on the Kalmit in the Palatine Forest
Boulder stream of the Kaser Steinstube near Triftern
A photo of a single eastern white pine in the nearly barren Boulder Field, Hickory Run State Park, PA.
Felsenmeer, painting by Egbert Schaap (1912). Rijksmuseum Amsterdam

A blockfield[1] (also spelt block field[2]), felsenmeer,[1] boulder field[1][2] or stone field[2] is a surface covered by boulder- or block-sized rocks usually associated with a history of volcanic activity, alpine and subpolar climates and periglaciation. Blockfields differ from screes and talus slope in that blockfields do not apparently originate from mass wastings. They are believed to be formed by frost weathering below the surface.[3][4] An alternative theory that modern blockfields may have originated from chemical weathering that occurred in the Neogene when the climate was relatively warmer. Following this thought the blockfields would then have been reworked by periglacial action.[4][5]

Most known blockfields are located in the northern hemisphere. Examples can be found in Abisko National Park in Sweden, Snowdonia National Park in Wales, the Great End-Scafell Pike ridge in England , and Hickory Run Boulder Field and River of Rocks in the Appalachian Mountains of the United States . All examples except the first one are outside present day subpolar climate areas, and have thus traditionally been seen as relict landforms from past times when these areas were under periglaciation.

The term "felsenmeer" comes from the German meaning "sea of rock". In a felsenmeer or blockfield, freeze-thaw weathering has broken up the top layer of the rock, covering the underlying rock formation with jagged, angular boulders. Freeze-thaw or frost weathering occurs when water that is trapped along microcracks in rock expands and contracts due to fluctuations in temperature above and below the freezing point. Felsenmeers are formed in situ, meaning that they are not transported during or after their creation.

Characteristics

Surface

Felsenmeers only form on slopes of 25° or lower. A steeper angle results in transport of the blocks due to gravity. This creates a talus slope, rather than a felsenmeer.[6] Crude sorting with boulder imbrication can occasionally be seen on the surface of felsenmeers.

Profile

The depth of the boulder field depends on the slope angle, rock types, age, and erosional history. However, a reasonable average for felsenmeer depth is approximately 1m. Ballantyne (1998)[7] defines three types of felsenmeer profiles: Type 1 consists of boulders overlying a matrix of fines at some depth below the surface. Type 2 consists of boulders supported by a cohesionless sandy matrix that continues from the surface down through the profile. Type 3 also consists of boulders supported by a matrix, but differs from Type 2 in that the matrix consists of silt and/or clay rather than sand.

Occurrence

Due to the slope requirements they are most commonly found on plateaus.[8] Basalt and sedimentary rocks often produce larger, more numerous felsenmeers than other types of rock.[9] Blockfields are most often found in high mountain periglacial regions near the Arctic Circle, especially in Iceland, the Canada arctic and Norway and are still active in parts of Central Europe that were not covered by ice sheets.[2] In the Southern Hemisphere inactive blockfields can be found in the Lesotho Highlands,[10] and the Prince Edward Islands.[11]

Age

Felsenmeers are, typically, relatively young geomorphological features. Most felsenmeers formed during or since the last ice age (approximately 20,000 years ago). Others may be pre-glacial features that survived glaciation beneath cold-based glaciers.[12] Their specific age can be determined using surface exposure dating, a technique that works best on materials which have been exposed to cosmic rays with little interference from trees or soils.

See also

References

  1. 1.0 1.1 1.2 Whittow, John (1984). Dictionary of Physical Geography. London: Penguin, 1984, pp. 66 and 190. ISBN:0-14-051094-X.
  2. 2.0 2.1 2.2 2.3 Leser, Hartmut, ed. (2005). Wörterbuch Allgemeine Geographie, 13th ed., dtv, Munich, pp. 107 and 221. ISBN:978-3-423-03422-7.
  3. Thomas, David S.G. and Andrew Goudie (eds.), The Dictionary of Physical Geography, 3rd edn., Oxford: Blackwell, 2000, p. 215. ISBN:0-631-20473-3.
  4. 4.0 4.1 Goodfellow, B.W.; Stroeven, A.P.; Fabel, D.; Fredin, O.; M.-H., Derron; Bintnja, R.; Caffee, M.W. (2014). "Arctic–alpine blockfields in the northern Swedish Scandes: late Quaternary – not Neogene". Earth Surface Dynamics 2 (2): 383–401. doi:10.5194/esurf-2-383-2014. Bibcode2014ESuD....2..383G. http://www.earth-surf-dynam.net/2/383/2014/. Retrieved 11 July 2016. 
  5. Boelhouwers, Jan (2004). "New Perspectives on Autochthonous Blockfield Development". Polar Geography 28 (2): 133–146. doi:10.1080/789610122. 
  6. Dahl, R. (1966) Block fields, weathering pits and tor-like forms in the Narvik Mountains, Nordland, Norway. Geografiska Annaler A 48, 55-85.
  7. Ballantyne, C.K. (1998). Age and significance of mountain-top detritus. Permafrost and Periglacial Processes 9, 327-345
  8. Huggett, John Richard. Fundamentals of Geomorphology, 3rd edn., Routledge, 2011, p. 147.
  9. The New Encyclopædia Britannica, Volume 8; Volume 14, 1998.
  10. "Geomorphic and climatic implications of relict openwork block accumulations near Thabana-Ntlenyana, Lesotho". Geografiska Annaler: Series A, Physical Geography 86 (3): 289–302. 2004. doi:10.1111/j.0435-3676.2004.00232.x. 
  11. Boelhouwers, Jan; Holness, Steve; Sumner, Paul (2003). "The maritime Subantarctic: a distinct periglacial environment". Geomorphology (Elsevier) 52 (1): 39–55. doi:10.1016/S0169-555X(02)00247-7. Bibcode2003Geomo..52...39B. 
  12. Matthews, John A. (ed.), Encyclopedia of Environmental Change, 3-volume set, Swansea: Sage, 2014.




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