Silica Phytolith
This is from an environmental tapelift collected outside near a sugarcane field burn. Some of the water of hydration has been volatilized, leaving gaps in the structure that result in light scatter. The size of this particle can be measured in a number of ways. The diameter of the circle with the same area is 32.9 micrometers. The diameter of the circule with the same perimeter is 43.9 micrometers. An aerodynamic index is the diameter of the circle with the same diameter divided by the diameter of the circle with the same perimeter, 0.75. The diameter of a sphere with equivelent volume, assuming the cross-section diameter is the same as the shortest diameter, is 30.43 micrometers. The equivalent aerodynamic diameter is 22.8 micrometers (30.43 micrometers X 0.75).
Definition/Function:
Phytoliths are mineral deposits formed by plant tissue. They may be hydrated silicon dioxide (opal), calcium oxalate monohydrate calcium oxalate dihydrate, calcium phosphate, or calcium carbonate. These structures have distinctive shapes and often can help identify the plant of origin when found free in an environmental sample. They are very common airborne particles in arid environments and were identified in the dust captured on the sails of the HMS Beagle in 1833, as reported by Charles Darwin. The calcium oxalate phytoliths from cacti contribute to the calcareous aerosols of the Southwest United States.
The characterization of phytoliths and the identification of their plant of origin is progressing as a result of their value in determining ancient environments from soil samples. They have also been used to identify the beginnings of agriculture at archeological sites. These studies all fall under the general discipline of Palaeobotany. In palaeobotany the term is generally limited to the silicon dioxide type of phytolith because they are the most persistent in the environment.
Significance in the Environment:
These particles are left behind when plant materials degrade or are burned. The siliceous phytoliths typically become amorphous, transparent particles of distinctive shape. When burned they often become coated with a layer of carbon and appear black or gray. Calcareous phytoliths may remain intact as the plant degrades but they often go through a series of chemical reactions that ultimately result in the formation of a calcium carbonate. When burned they convert to calcium oxide, which then reacts with water and carbon dioxide to form aragonite (calcium carbonate). Cubical calcium oxide and hydroxide particles are common in the plume from the combustion of wood, often showing surface modification to the carbonate. The surface modification is evident as a birefringent film over part of the particle.Characteristic Features:
The silica phytoliths are characterized by their low refractive index, less than 1.48, their cell related morphology (see Madella, Alexandre, and Ball; 2005), and by their lack of birefringence. The other phytoliths are dominated by their crystalline structure rather than cell morphology. The crystalline habit manifested by these phytoliths will vary from plant species to plant species and from cell type to cell type within a species. The two types of calcium oxalate phytoliths from the leaves of Rhubarb are an example of variation between cell types in a single species.Associated Particles:
References:
1. Blinnikov, Mikhail, "Phytoliths in plants and soils of the interior Pacific Northwest, USA", REVIEW OF PALAEOBOTANY & PALYNOLOGY, vol. 135, pp. 71-98, 20052. Franceschi, Vincent R. and Harry T. Horner Jr., "Calcium oxalate crystals in plants", THE BOTANICAL REVIEW, vol. 46, No. 4, Oct-Dec 1980, pp. 361-427.
3. Piperno, Dolores R., PHYTOLITHS, AltaMira Press, 2006.
4. Rapp, George Jr. and Susan C. Mulholland (eds), PHYTOLITH SYSTEMATICS, Plenum Press, 1992.
5. Madella, M., A. Alexandre, and T Ball, "International Code for Phytolith nomenclature 1.0", ANNALS OF BOTANY, 2005,available on line at http://aob.oxfordjournals.org/cgi/reprint/mci172v1
6. http://en.wikipedia.org/wiki/Phytoliths
