Phytolith

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Image of a Phytolith (bulliform)
Image of a Phytolith (bulliform)

A phytolith ("Plant stone") is a rigid microscopic body that occurs in many plants. The most common type of phytolith is the silicon phytolith, also called opal phytolith. Silicon phytoliths vary in size and shape depending on the plant taxon and plant part (stem, leaf, root) in which they (naturally) occur. Grasses, including rice, wild rice, maize, wheat, and other various grains); crop plants such as beans, squashes, gourds, manioc, canna, and arrowroot; palms; as well as numerous tree species are just some of the plants which contain phytoliths. Calcium oxalate phytoliths are another common type, occurring in the stems of cacti and baobabs. Phytoliths are mentioned in the writings of Charles Darwin.

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[edit] Function

These objects serve a variety of purposes. In many cases, they appear to lend the plant structure and support, much like the spicules in sponges and leather corals. Others serve to make plants distasteful, lending the plant's tissues a grainy or prickly texture. Finally, calcium oxalate phytoliths serve as a reserve of carbon dioxide. Cacti use these as a reserve for photosynthesis during the day when they close their pores to avoid water loss, while baobabs use this property to make their trunks more flame-resistant.

[edit] Archaeology

Phytoliths are very robust in nature, and are useful in archaeology, since they can be used to reconstruct the plants present at a site or an area within a site even though the rest of the plant parts have been burned up or dissolved. Because they are made of the inorganic substances silica or calcium oxalate, phytoliths don't decay when the rest of the plant decays over time and can survive in conditions that would destroy organic residues. Phytoliths can provide evidence of both economically important plants and those that are indicative of the environment at a particular time period.

Phytoliths may be extracted from residue on many sources: dental calculus (buildup on teeth); food preparation tools like rocks, grinders, and scrapers; cooking or storage containers; ritual offerings; and garden areas.


[edit] Palaeontology

Phytoliths are abundant in the fossil record,[1] and have been reported from the late Devonian onwards.[1] They can be used to identify palaeoenvironments and track vegetational change.[1]

Occasionally, paleontologists find and identify phytoliths associated with extinct plant-eating animals (e.g., herbivores). Findings such as these reveal useful information about the diet of these extinct animals, and also shed light on the evolutionary history of many different types of plants. Paleontologists in India have recently identified grass phytoliths in dinosaur dung, strongly suggesting that the evolution of grasses began earlier than previously thought. [2]

Japanese and Korean archaeologists refer to grass and crop plant phytoliths as 'plant opal' in archaeological literature.

[edit] Carbon sequestration

Recent work in 2007 has shown that carbon can be accumulated in many phytoliths, and as such could provide a long term option to sequester carbon in soil in the plant residual silicon. [3]

[edit] Notes

  1. ^ a b c Carter, J.A. (1999). "Late Devonian, Permian and Triassic phytoliths from Antarctica". Micropaleontology 45 (1): 56-61. 
  2. ^ Fossil dung reveals dinosaurs did graze grass Hecht, Jeff, New Scientist Magazine , 17 November 2005. Accessed January 2008
  3. ^ Plantstones could help lock away carbon ,Nowak, Rachel, New Scientist Magazine issue 2637, January 5 2008, Accessed January 2008]

[edit] References

  • Thorn, V. C. 2004. An annotated bibliography of phytolith analysis and atlas of selected New Zealand subantarctic and subalphine phytoliths.
  • Meunier, J. D. 2001. Phytoliths: applications in earth sciences and human history.
  • Kealhofer, L. 1998. Opal phytoliths in Southeast Asian flora.
  • Rapp, G. R. 1992. Phytolith systematics: emerging issues.
  • Ciochon, R. L., Piperno, D. R. and Thompson, R. G. 1990. Opal phytoliths found on the teeth of the extinct ape Gigantopithecus blacki: Implications for paleodietary studies. Proc. Nat. Acad. Sci. 87: 8120-8124.
  • Piperno, D. R. 1988. Phytolith analysis: an archaeological and geological perspective.
  • Twiss, P. C., Suess, E., & Smith, R. M. 1969. Morphological classification of grass phytoliths. Proc. Soil Sci. Soc. America.
  • Pearsall, D. M. 2004. Plants and People in Ancient Ecuador: The Ethnobotany of the Jama River Valley. Wadsworth/Thomson Learning, Case Studies in Archaeology Series, Belmont , CA 180 pp.
  • Pearsall, D. M. 2000. Paleoethnobotany. A Handbook of Procedures. Second Edition. Academic Press, San Diego. 700 pp.
  • Piperno, D. R. and D. M. Pearsall. 1998. The Origins of Agriculture in the Lowland Neotropics. Academic Press, San Diego. 400 pp.
  • Pearsall, D. M., K. Chandler-Ezell, and J. A. Zeidler. 2004. Maize in ancient Ecuador: Results of residue analysis of stone tools from the Real Alto site. Journal of Archaeological Science 31:423-442.
  • Darwin, C. R. 1846. "An Account of the Fine Dust Which Often Falls on Vessels in the Atlantic Ocean," Quarterly Journal of the Geological Society of London 2 (Read 4 June 1845): 26-30. (http://darwin-online.org.uk/content/frameset?itemID=F1672&viewtype=text&pageseq=3).

[edit] External links