Book contents
- Frontmatter
- Contents
- List of contributors
- Preface
- Part I Introduction
- Part II Diatoms as indicators of environmental change in flowing waters and lakes
- Part III Diatoms as indicators in Arctic, Antarctic, and alpine lacustrine environments
- Part IV Diatoms as indicators in marine and estuarine environments
- Part V Other applications
- 24 Diatoms of aerial habitats
- 25 Diatoms as indicators of environmental change in wetlands and peatlands
- 26 Tracking fish, seabirds, and wildlife population dynamics with diatoms and other limnological indicators
- 27 Diatoms and archeology
- 28 Diatoms in oil and gas exploration
- 29 Forensic science and diatoms
- 30 Toxic marine diatoms
- 31 Diatoms as markers of atmospheric transport
- 32 Diatoms as non-native species
- 33 Diatomite
- 34 Stable isotopes from diatom silica
- 35 Diatoms and nanotechnology: early history and imagined future as seen through patents
- Part VI Conclusions
- Glossary, acronyms, and abbreviations
- Index
- References
33 - Diatomite
from Part V - Other applications
Published online by Cambridge University Press: 05 June 2012
Book contents
- Frontmatter
- Contents
- List of contributors
- Preface
- Part I Introduction
- Part II Diatoms as indicators of environmental change in flowing waters and lakes
- Part III Diatoms as indicators in Arctic, Antarctic, and alpine lacustrine environments
- Part IV Diatoms as indicators in marine and estuarine environments
- Part V Other applications
- 24 Diatoms of aerial habitats
- 25 Diatoms as indicators of environmental change in wetlands and peatlands
- 26 Tracking fish, seabirds, and wildlife population dynamics with diatoms and other limnological indicators
- 27 Diatoms and archeology
- 28 Diatoms in oil and gas exploration
- 29 Forensic science and diatoms
- 30 Toxic marine diatoms
- 31 Diatoms as markers of atmospheric transport
- 32 Diatoms as non-native species
- 33 Diatomite
- 34 Stable isotopes from diatom silica
- 35 Diatoms and nanotechnology: early history and imagined future as seen through patents
- Part VI Conclusions
- Glossary, acronyms, and abbreviations
- Index
- References
Summary
Introduction
Diatomite, a soft, porous, fine-grained, lightweight, siliceous sedimentary rock, is produced by the accumulation and compaction of diatom (Class Bacillariophyceae) remains. The cell wall of living diatoms is impregnated with silica (amorphous hydrous, or opaline (SiO2.nH2O)), which preserves ornate and highly porous structures (Armbrust, 2009). Upon death of the organism, these siliceous elements become sedimentary particles in a diatomite deposit. The intricate structure of diatom frustules, and packing of the myriad diatom shapes into rock-forming sedimentary layers, gives diatomite deposits properties that are useful in many industrial and commercial applications. Most diatoms are 10 μm to 100 μm in size, although larger species reach more than 1 mm (Tappan, 1980) and smaller ones are <2 μm. This small size results in large concentrations of diatoms; a cubic inch of diatomite may contain 40 to 70 million diatoms (Crespin, 1946). Although the specific gravity (density) of the SiO2 that comprises the diatom particles is nearly twice that of water, perforations and open structures in the frustule renders diatomite a considerably lower effective density (between 0.12 g cm–3 and 0.25 g cm–3) with high porosity (from 75 to 85 percent). This sedimentary rock is able to absorb and hold up to 3.5 times its own weight in liquid (Cleveland, 1966). These properties bring industrial utility and commercial value to rock-forming accumulations of diatom remains.
Diatomite deposits of varying quality are known from freshwater and marine sedimentary environments (Moyle & Dolley, 2003). Other names for diatomite and diatomaceous earth include tripoli, kieselguhr, and infusorial earth.
- Type
- Chapter
- Information
- The DiatomsApplications for the Environmental and Earth Sciences, pp. 570 - 574Publisher: Cambridge University PressPrint publication year: 2010
References
(1839). On fossil infusoria discovered in peat-earth at West Point, N.Y. American Journal of Science, Series I, 35, 118–24.Google Scholar
& (1990). Evolution of biosiliceous sedimentation patterns – Eocene through Quaternary: paleoceanographic response to polar cooling. In Geological History of the Polar Oceans: Arctic versus Antarctic, ed. & , Dordrecht: Kluwer Academic Publishers, pp. 575–607.CrossRefGoogle Scholar
(1987). Diatomite: environmental and geological factors affecting its distribution. In Siliceous Sedimentary Rock-Hosted Ores and Petroleum, ed. , New York: Van Nostrand Reinhold Co., pp. 164–78.Google Scholar
(1970). Biogenous deep-sea sediments – fractionation by deep-sea circulation. Geological Society of America Bulletin, 81, 1385–401.CrossRefGoogle Scholar
(1920). Industrie des silices de infusoires et de diatomees. Revue Ingenieur et Index Technique, 26, 302–25.Google Scholar
(1946). The Monterey Formation of California and the origin of its siliceous rocks, US Geological Survey Professional Paper, 212, 1–57.Google Scholar
(1974). Deposition and diagenesis of silica in marine sediments. Special Publications of the International Association of Sedimentology, 1, 273–99.Google Scholar
& (1897). The diatomaceous earth deposits of New South Wales. Geological Records of New South Wales, 5, 128–48.Google Scholar
, , , & (2008). Thinking outside the zone: high-resolution quantitative diatom biochronology for Antarctic Neogene strata. Palaeogeography, Palaeoclimatology, Palaeoecology, 260, 92–121.CrossRefGoogle Scholar
(1942). Accumulation of diatomaceous deposits. Journal of Sedimentary Petrology, 12, 55–66.Google Scholar
(2008). Diatomite. Mining Engineering, Society for Mining, Metallurgy and Exploration, 60, 27–8.Google Scholar
(1946). Diatomite. Mineral Resources of Australia, Summary Report No. 12, Canberra, Commonwealth Government Printer, pp. 1–31.
(1962). Non-detrital siliceous sediments. US Geological Survey Professional Paper, 440-T, T1–T23.Google Scholar
(1960). Diatomite. In Industrial Minerals and Rocks, 3rd edition, New York, NY: American Institute of Mining, Metallurgical, and Petroleum Engineers, pp. 303–19.Google Scholar
(2008). Diatomite. US Geological Survey Mineral Commodity Summaries, pp. 58–59. See http://minerals.usgs.gov/minerals/pubs/commodity/diatomite/mcs-2008-diato.pdf.
& (2003). History and overview of the U.S. diatomite mining industry, with emphasis on the Western United States. US Geological Survey Bulletin, 2209, E1–E8.Google Scholar
(1928). Diatomite: its occurrence, preparation and uses. Department of Mines, Canada, Publication 691, Ottawa Mines Branch, pp. 1–14.
(1836). Uber Fossile Infusions-thiere. Berichte der Königlichen Preussischen Akademie der Wissenschaften zu Berlin, 1836, 50–4.Google Scholar
(1842). Uber die wie Kork auf Wasser schwimmenden Mauersteine der Alten Griechen und Roemer. Berichte der Königlichen Preussischen Akademie der Wissenschaften zu Berlin, 1842, Bd. 8, 132–7.Google Scholar
(1990). The paleontological significance of fossil diatoms from the high-latitude oceans. In Polar Marine Diatoms, ed. & , Cambridge: British Antarctic Survey, pp. 57–63.Google Scholar
, , & (2007). Cretaceous records of diatom evolution, radiation, and expansion. In From Pond Scum to Carbon Sink: Geological and Environmental Applications of the Diatoms, ed. , Short Courses in Paleontology 13, Knoxville, TN: Paleontological Society, pp. 33–59.Google Scholar
(1930). Diatomite: its analysis and use in Pharmacy. Quarterly Journal of Pharmacy, 3, 390–407.Google Scholar
(1981). Porosity reduction during diagenesis of the Monterey Formation, Santa Barbara Coastal area, California. In The Monterey Formation and Related Siliceous Rocks of California, ed. , & , Los Angeles, CA: Pacific Section, Society of Economic Paleontoloogists and Mineralogists, pp. 257–72.Google Scholar
& (eds.) (2001). The Monterey Formation. From Rocks to Molecules, New York, NY: Columbia University Press.Google Scholar
& (1941 to 1946). Fundamental studies of Japanese diatomaceous earths and their industrial applications. Journal of the Japanese Ceramic Association. Series of 18 parts from Part I (1941) in volume 49, 14–25 to Part XVIII (1946) in volume 54, 52–6.Google Scholar
& (1993). Vast Neogene laminated mat deposits from the eastern equatorial Pacific Ocean. Nature, 362, 141–3.CrossRefGoogle Scholar
(1979). Biogenic silica accumulation in the central equatorial Pacific and its implications for Cenozoic paleoceanography. Geological Society of America Bulletin, 90, 1310–76.CrossRefGoogle Scholar
(1960). The ubiquitous diatom – a brief survey of the present state of knowledge. American Journal of Science, 258-A, 180–91.Google Scholar
(2008). Blood, sweat and beers, filtration minerals reviewed. Industrial Minerals, 484, 34–40.Google Scholar
(1898). Kieselghur and other infusorial earths. Proceedings of the British Pharmaceutical Conference for1898, 337–45.Google Scholar
& (2003). With or without salt – a comparison of marine and continental-lacustrine diatomite deposits. US Geological Survey Bulletin, 2209, D1–D11.Google Scholar
, , , , & (1995). Production and dissolution of biogenic silica in the ocean: revised global estimates, comparison with regional data and relationship to biogenic sedimentation. Global Biogeochemical cycles, 9, 359–72.CrossRefGoogle Scholar
, , & (2007). Methods and Applications of Cenozoic Marine Diatom Biostratigraphy. In From Pond Scum to Carbon Sink: Geological and Environmental Applications of the Diatoms, ed. , Paleontological Society Short Course 13, Knoxville, TN: The Paleontology Society, 61–83.Google Scholar
(1970). Diatomite in mineral facts and figures. US Bureau of Mines Bulletin, 650, 967–75.Google Scholar
(1933). The relation of volcanism to diatomaceous and associated siliceous sediments. California University Publications, Geological Sciences, 23, 1–56Google Scholar
(1876). Infusorial earth and its uses. Quarterly Journal Science, London, New Series, 6, 336–51.Google Scholar
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