fbpx
Wikipedia

Tuff

December 15, 2023

For other uses, see Tuff (disambiguation).
Not to be confused with Tufa.

Tuff is a type of rock made of volcanic ash ejected from a vent during a volcanic eruption. Following ejection and deposition, the ash is lithified into a solid rock.[1][2] Rock that contains greater than 75% ash is considered tuff, while rock containing 25% to 75% ash is described as tuffaceous (for example, tuffaceous sandstone).[3] Tuff composed of sandy volcanic material can be referred to as volcanic sandstone.[4]

Cliff face of welded tuff pockmarked with holes — some natural, some man-made from Bandelier National Monument, New Mexico
Etruscan tuff blocks from a tomb at Banditaccia
A house constructed of tuff blocks in Germany

Tuff is a relatively soft rock, so it has been used for construction since ancient times.[5] Because it is common in Italy, the Romans used it often for construction.[6] The Rapa Nui people used it to make most of the moai statues on Easter Island.[7]

Tuff can be classified as either igneous or sedimentary rock. It is usually studied in the context of igneous petrology, although it is sometimes described using sedimentological terms.

Tuff is often erroneously called tufa in guidebooks and in television programs but tufa is a form of travertine.

Volcanic ash edit

The material that is expelled in a volcanic eruption can be classified into three types:

  1. Volcanic gases, a mixture made mostly of steam, carbon dioxide, and a sulfur compound (either sulfur dioxide, SO2, or hydrogen sulfide, H2S, depending on the temperature)
  2. Lava, the name of magma when it emerges and flows over the surface
  3. Tephra, particles of solid material of all shapes and sizes ejected and thrown through the air
 
Light-microscope image of tuff as seen in thin section (long dimension is several mm): The curved shapes of altered glass shards (ash fragments) are well preserved, although the glass is partly altered. The shapes were formed about bubbles of expanding, water-rich gas.

Tephra is made when magma inside the volcano is blown apart by the rapid expansion of hot volcanic gases. Magma commonly explodes as the gas dissolved in it comes out of solution as the pressure decreases when it flows to the surface. These violent explosions produce particles of material that can then fly from the volcano. Solid particles smaller than 2 mm in diameter (sand-sized or smaller) are called volcanic ash.[8][3]

Volcanic ash is further divided into fine ash, with particle sizes smaller than 0.0625 mm in diameter, and coarse ash, with particle sizes between 0.0625 mm and 2 mm in diameter. Tuff is correspondingly divided into coarse tuff (coarse ash tuff) and fine tuff (fine ash tuff or dust tuff). Consolidated tephra composed mostly of coarser particles is called lapillistone (particles 2 mm to 64 mm in diameter) or agglomerate or pyroclastic breccia (particles over 64 mm in diameter) rather than tuff.[3]

Volcanic ash can vary greatly in composition, and so tuffs are further classified by the composition of the ash from which they formed. Ash from high-silica volcanism, particularly in ash flows, consists mainly of shards of volcanic glass,[9][10] and tuff formed predominantly from glass shards is described as vitric tuff.[11] The glass shards are typically either irregular in shape or are roughly triangular with convex sides. They are the shattered walls of countless small bubbles that formed in the magma as dissolved gases rapidly came out of solution.[12]

Tuffs formed from ash consisting predominantly of individual crystals are described as crystal tuffs, while those formed from ash consisting predominantly of pulverized rock fragments are described as lithic tuffs.[11]

The chemical composition of volcanic ash reflects the entire range of volcanic rock chemistry, from high-silica rhyolitic ash to low-silica basaltic ash, and tuffs are likewise described as rhyolitic, andesitic, basaltic, and so on.[13]

Transport and lithification edit

The most straightforward way for volcanic ash to move away from the vent is as ash clouds that are part of an eruption column. These fall to the surface as fallout deposits that are characteristically well-sorted and tend to form a blanket of uniform thickness across terrain. Column collapse results in a more spectacular and destructive form of transport, which takes the form of pyroclastic flows and surges that characteristically are poorly sorted and pool in low terrain. Surge deposits sometimes show sedimentary structures typical of high-velocity flow, such as dunes and antidunes.[14] Volcanic ash already deposited on the surface can be transported as mud flows (lahars) when mingled with water from rainfall or through eruption into a body of water or ice.[15]

Particles of volcanic ash that are sufficiently hot will weld together after settling to the surface, producing a welded tuff. Welding requires temperatures in excess of 600 °C (1,100 °F). If the rock contains scattered, pea-sized fragments or fiamme in it, it is called a welded lapilli-tuff. Welded tuffs (and welded lapilli-tuffs) can be of fallout origin, or deposited from ash flows, as in the case of ignimbrites.[16] During welding, the glass shards and pumice fragments adhere together (necking at point contacts), deform, and compact together, resulting in a eutaxitic fabric.[17] Welded tuff is commonly rhyolitic in composition, but examples of all compositions are known.[18][19]

A sequence of ash flows may consist of multiple cooling units. These can be distinguished by the degree of welding. The base of a cooling unit is typically unwelded due to chilling from the underlying cold surface, and the degree of welding and of secondary reactions from fluids in the flow increases upwards towards the center of the flow. Welding decreases towards the top of the cooling unit, where the unit cools more rapidly. The intensity of welding may also decrease towards areas in which the deposit is thinner, and with distance from source.[20]

Cooler pyroclastic flows are unwelded and the ash sheets deposited by them are relatively unconsolidated.[17] However, cooled volcanic ash can quickly become lithified because it usually has a high content of volcanic glass. This is a thermodynamically unstable material that reacts rapidly with ground water or sea water, which leaches alkali metals and calcium from the glass. New minerals, such as zeolites, clays, and calcite, crystallize from the dissolved substances and cement the tuff.[21]

Tuffs are further classified by their depositional environment, such as lacustrine tuff, subaerial tuff, or submarine tuff, or by the mechanism by which the ash was transported, such as fallout tuff or ash flow tuff. Reworked tuffs, formed by erosion and redeposition of ash deposits, are usually described by the transport agent, such as aeolian tuff or fluvial tuff.[22]

  •  

    Layers of fallout tuff in Japan

  •  

    Rocks from the Bishop tuff in California, unwelded with pumice on left, welded with fiamme on right

  •  

    Bandelier Tuff at San Diego Canyon, New Mexico, USA. The lower Otowi Member is a single massive cooling unit, while the upper Tshirege Member is composed of multiple cooling units.

Occurrences edit

Tuffs have the potential to be deposited wherever explosive volcanism takes place, and so have a wide distribution in location and age.[23]

High-silica volcanism edit

Rhyolite tuffs contain pumiceous, glassy fragments and small scoriae with quartz, alkali feldspar, biotite, etc. Iceland,[24] Lipari,[25] Hungary,[26] the Basin and Range of the American southwest, and New Zealand[27] are among the areas where such tuffs are prominent. In the ancient rocks of Wales,[28] Charnwood,[29] etc., similar tuffs are known, but in all cases, they are greatly changed by silicification (which has filled them with opal, chalcedony, and quartz) and by devitrification.[30] The frequent presence of rounded corroded quartz crystals, such as occur in rhyolitic lavas, helps to demonstrate their real nature.[8]

Welded ignimbrites can be highly voluminous, such as the Lava Creek Tuff erupted from Yellowstone Caldera in Wyoming 631,000 years ago. This tuff had an original volume of at least 1,000 cubic kilometers (240 cu mi).[31] Lava Creek tuff is known to be at least 1000 times as large as the deposits of the 1980 eruption of Mount St. Helens, and it had a Volcanic Explosivity Index (VEI) of 8, greater than any eruption known in the last 10,000 years.[32] Ash flow tuffs cover 7,000 square kilometers (2,700 sq mi) of the North Island of New Zealand and about 100,000 square kilometers (39,000 sq mi) of Nevada. Ash flow tuffs are the only volcanic product with volumes rivaling those of flood basalts.[27]

The Tioga Bentonite of the northeastern United States varies in composition from crystal tuff to tuffaceous shale. It was deposited as ash carried by wind that fell out over the sea and settled to the bottom. It is Devonian in age and likely came from a vent in central Virginia, where the tuff reaches its maximum thickness of about 40 meters (130 ft).[33]

Alkaline volcanism edit

Trachyte tuffs contain little or no quartz, but much sanidine or anorthoclase and sometimes oligoclase feldspar, with occasional biotite, augite, and hornblende. In weathering, they often change to soft red or yellow claystones, rich in kaolin with secondary quartz.[8] Recent trachyte tuffs are found on the Rhine (at Siebengebirge),[34] in Ischia[35] and near Naples.[36] Trachyte-carbonatite tuffs have been identified in the East African Rift.[37] Alkaline crystal tuffs have been reported from Rio de Janeiro.[38]

Intermediate volcanism edit

Andesitic tuffs are exceedingly common. They occur along the whole chain of the Cordilleras[39][40] and Andes,[41] in the West Indies, New Zealand,[42] Japan,[43] etc. In the Lake District,[44] North Wales, Lorne, the Pentland Hills, the Cheviots, and many other districts of Great Britain, ancient rocks of exactly similar nature are abundant. In color, they are red or brown; their scoriae fragments are of all sizes from huge blocks down to minute granular dust. The cavities are filled with many secondary minerals, such as calcite, chlorite, quartz, epidote, or chalcedony; in microscopic sections, though, the nature of the original lava can nearly always be made out from the shapes and properties of the little crystals which occur in the decomposed glassy base. Even in the smallest details, these ancient tuffs have a complete resemblance to the modern ash beds of Cotopaxi, Krakatoa, and Mont Pelé.[8]

Mafic volcanism edit

 
Diamond Head, a tuff cone
 
Most of the moais in Easter Island are carved out of tholeiite basalt tuff.

Mafic volcanism typically takes the form of Hawaiian eruptions that are nonexplosive and produce little ash.[45] However, interaction between basaltic magma and groundwater or sea water results in hydromagmatic explosions that produce abundant ash. These deposit ash cones that subsequently can become cemented into tuff cones. Diamond Head, Hawaii, is an example of a tuff cone, as is the island of Ka'ula. The glassy basaltic ash produced in such eruptions rapidly alters to palagonite as part of the process of lithification.[46]

Although conventional mafic volcanism produce little ash, such ash as is formed may accumulate locally as significant deposits. An example is the Pahala ash of Hawaii island, which locally is as thick as 15 meters (49 ft). These deposits also rapidly alter to palagonite, and eventually weather to laterite.[47]

Basaltic tuffs are also found in Skye, Mull, Antrim, and other places, where Paleogene volcanic rocks are found; in Scotland, Derbyshire, and Ireland among the Carboniferous strata, and among the still older rocks of the Lake District, the southern uplands of Scotland, and Wales. They are black, dark green, or red in colour; vary greatly in coarseness, some being full of round spongy bombs a foot or more in diameter; and being often submarine, may contain shale, sandstone, grit, and other sedimentary material, and are occasionally fossiliferous. Recent basaltic tuffs are found in Iceland, the Faroe Islands, Jan Mayen, Sicily, the Hawaiian Islands, Samoa, etc. When weathered, they are filled with calcite, chlorite, serpentine, and especially where the lavas contain nepheline or leucite, are often rich in zeolites, such as analcite, prehnite, natrolite, scolecite, chabazite, heulandite, etc.[8]

Ultramafic volcanism edit

Ultramafic tuffs are extremely rare; their characteristic is the abundance of olivine or serpentine and the scarcity or absence of feldspar and quartz.[48]

Kimberlites edit

Occurrences of ultramafic tuff include surface deposits of kimberlite at maars in the diamond-fields of southern Africa and other regions. The principal variety of kimberlite is a dark bluish-green, serpentine-rich breccia (blue-ground) which, when thoroughly oxidized and weathered, becomes a friable brown or yellow mass (the "yellow-ground").[8] These breccias were emplaced as gas–solid mixtures and are typically preserved and mined in diatremes that form intrusive pipe-like structures. At depth, some kimberlite breccias grade into root zones of dikes made of unfragmented rock. At the surface, ultramafic tuffs may occur in maar deposits. Because kimberlites are the most common igneous source of diamonds, the transitions from maar to diatreme to root-zone dikes have been studied in detail. Diatreme-facies kimberlite is more properly called an ultramafic breccia rather than a tuff.

Komatiites edit

Komatiite tuffs are found, for example, in the greenstone belts of Canada and South Africa.[49][50]

Folding and metamorphism edit

 
Remains of the ancient Servian Walls in Rome, made of tuff blocks
 
19th century embankment wall built of Brisbane tuff, City of Brisbane

In course of time, changes other than weathering may overtake tuff deposits. Sometimes, they are involved in folding and become sheared and cleaved. Many of the green slates of the English Lake District are finely cleaved ashes. In Charnwood Forest also, the tuffs are slaty and cleaved. The green color is due to the large development of chlorite. Among the crystalline schists of many regions, green beds or green schists occur, which consist of quartz, hornblende, chlorite or biotite, iron oxides, feldspar, etc., and are probably recrystallized or metamorphosed tuffs. They often accompany masses of epidiorite and hornblende – schists which are the corresponding lavas and sills. Some chlorite-schists also are probably altered beds of volcanic tuff. The "Schalsteins" of Devon and Germany include many cleaved and partly recrystallized ash-beds, some of which still retain their fragmental structure, though their lapilli are flattened and drawn out. Their steam cavities are usually filled with calcite, but sometimes with quartz. The more completely altered forms of these rocks are platy, green chloritic schists; in these, however, structures indicating their original volcanic nature only sparingly occur. These are intermediate stages between cleaved tuffs and crystalline schists.[8]

Importance edit

The primary economic value of tuff is as a building material. In the ancient world, tuff's relative softness meant that it was commonly used for construction where it was available.[5] Tuff is common in Italy, and the Romans used it for many buildings and bridges.[6] For example, the whole port of the island of Ventotene (still in use), was carved from tuff. The Servian Wall, built to defend the city of Rome in the fourth century BC, is also built almost entirely from tuff.[51] The Romans also cut tuff into small, rectangular stones that they used to create walls in a pattern known as opus reticulatum.[52]

The peperino, much used at Rome and Naples as a building stone, is a trachyte tuff. Pozzolana also is a decomposed tuff, but of basic character, originally obtained near Naples and used as a cement, but this name is now applied to a number of substances not always of identical character. In the Eifel region of Germany, a trachytic, pumiceous tuff called trass has been extensively worked as a hydraulic mortar.[8]

Tuff of the Eifel region of Germany has been widely used for construction of railroad stations and other buildings in Frankfurt, Hamburg, and other large cities.[53] Construction using the Rochlitz Porphyr, can be seen in the Mannerist-style sculpted portal outside the chapel entrance in Colditz Castle.[54] The trade name Rochlitz Porphyr is the traditional designation for a dimension stone of Saxony with an architectural history over 1,000 years in Germany. The quarries are located near Rochlitz.[55]

Yucca Mountain nuclear waste repository, a U.S. Department of Energy terminal storage facility for spent nuclear reactor and other radioactive waste, is in tuff and ignimbrite in the Basin and Range Province in Nevada.[56] In Napa Valley and Sonoma Valley, California, areas made of tuff are routinely excavated for storage of wine barrels.[57]

Tuff from Rano Raraku was used by the Rapa Nui people of Easter Island to make the vast majority of their famous moai statues.[7]

In Armenia edit

Tuff is used extensively in Armenia and Armenian architecture.[58] It is the dominant type of stone used in construction in Armenia's capital Yerevan,[59][60] Gyumri, Armenia's second largest city, and Ani, the country's medieval capital, now in Turkey.[61] A small village in Armenia was renamed Tufashen (literally "village of tuff") in 1946.[62]

Tephrochronology edit

Main article: Tephrochronology
 
Pilar Formation outcrop showing metatuff beds used for radiometric dating

Tuffs are deposited geologically instantaneously and often over a large region. This makes them highly useful as time-stratigraphic markers. The use of tuffs and other tephra deposits in this manner is known as tephrochronology and is particularly useful for Quaternary chronostratigraphy. Individual tuff beds can be "fingerprinted" by their chemical composition and phenocryst assemblages.[64] Absolute ages for tuff beds can be determined by K-Ar, Ar-Ar, or carbon-14 dating.[65] Zircon grains found in many tuffs are highly durable and can survive even metamorphism of the host tuff to schist, allowing absolute ages to be assigned to ancient metamorphic rocks. For example, dating of zircons in a metamorphosed tuff bed in the Pilar Formation provided some of the first evidence for the Picuris orogeny.[66]

Etymology edit

The word tuff is derived from the Italian tufo.[67]

See also edit

  • Bentonite – Rock type or absorbent swelling clay
  • Brisbane tuff
  • Eutaxitic texture – Layered or banded texture in some extrusive rock bodies
  • Sillar – Variety of rhyolite containing fragments of andesite
  • Tuffite – Tuff containing both pyroclastic and detrital materials

References edit

  1. ^ Fisher, Richard V.; Schmincke, H.-U. (1984). Pyroclastic rocks. Berlin: Springer-Verlag. pp. 89–90. ISBN 3-540-12756-9.
  2. ^ Schmincke, Hans-Ulrich (2003). Volcanism. Berlin: Springer. p. 138. ISBN 978-3-540-43650-8.
  3. ^ a b c Schmidt, R. (1981). "Descriptive nomenclature and classification of pyroclastic deposits and fragments: recommendations of the IUGS Subcommission on the Systematics of Igneous Rocks". Geology. 9: 41–43. doi:10.1007/BF01822152. S2CID 128375559. Retrieved 27 September 2020.
  4. ^ Poole, W. H.; Neuman, Robert B. (2003). "Arenig volcanic and sedimentary strata, central New Brunswick and eastern Maine". Atlantic Geology. 38 (2/3). doi:10.4138/1257. Retrieved 2022-09-24.
  5. ^ a b Dolan, S.G.; Cates, K.M.; Conrad, C.N.; Copeland, S.R. (14 March 2019). "Home Away from Home: Ancestral Pueblo Fieldhouses in the Northern Rio Grande". Lanl-Ur. 19–21132: 96. Retrieved 29 September 2020.
  6. ^ a b Jackson, M. D.; Marra, F.; Hay, R. L.; et al. (2005). "The Judicious Selection and Preservation of Tuff and Travertine Building Stone in Ancient Rome*". Archaeometry. 47 (3): 485–510. doi:10.1111/j.1475-4754.2005.00215.x.
  7. ^ a b Richards, Colin (2016). "Making Moai: Reconsidering concepts of riskin the construction of megalithic architecture in Rapa Nui (Easter Island)". Rapa Nui: Easter Island Cultural and Historical Perspectives. Berlin [Germany]. pp. 160–161. ISBN 978-3-7329-0265-1. Retrieved 29 July 2021.{{cite book}}: CS1 maint: location missing publisher (link)
  8. ^ a b c d e f g h   One or more of the preceding sentences incorporates text from a publication now in the public domainChisholm, Hugh, ed. (1911). "Tuff". Encyclopædia Britannica (11th ed.). Cambridge University Press.
  9. ^ Fisher & Schmincke 1984, p. 96.
  10. ^ Blatt, Harvey; Tracy, Robert J. (1996). Petrology: Igneous, Sedimentary, and Metamorphic (2nd ed.). New York: W. H. Freeman. pp. 27–29. ISBN 0-7167-2438-3.
  11. ^ a b O'Brien, R. T. (1 March 1963). "Classification of tuffs". Journal of Sedimentary Research. 33 (1): 234–235. Bibcode:1963JSedR..33..234O. doi:10.1306/74D70E20-2B21-11D7-8648000102C1865D.
  12. ^ Blatt & Tracy 1996, pp. 27–29.
  13. ^ Fisher & Schmincke 1984, pp. 98–99.
  14. ^ Philpotts, Anthony R.; Ague, Jay J. (2009). Principles of igneous and metamorphic petrology (2nd ed.). Cambridge, UK: Cambridge University Press. p. 73. ISBN 978-0-521-88006-0.
  15. ^ Schmincke 2003, pp. 138–157.
  16. ^ Fisher & Schmincke 1984, p. 215.
  17. ^ a b Schmincke 2003, pp. 186–187.
  18. ^ Fisher & Schmincke 1984, p. 209.
  19. ^ Blatt & Tracy 1996, p. 29.
  20. ^ Ross, Clarence S.; Smith, Robert L. (1961). "Ash-flow tuffs: Their origin, geologic relations, and identification". USGS Profession Paper Series. Professional Paper (366): 19. doi:10.3133/pp366.
  21. ^ Schmincke 2003, p. 138.
  22. ^ Fisher & Schmincke 1984, pp. 89–90.
  23. ^ Philpotts & Ague 2009, p. 73.
  24. ^ Jónasson, K. (December 1994). "Rhyolite volcanism in the Krafla central volcano, north-east Iceland". Bulletin of Volcanology. 56 (6–7): 516–528. Bibcode:1994BVol...56..516J. doi:10.1007/BF00302832. S2CID 129012636.
  25. ^ Crisci, G. M.; Rosa, R.; Lanzafame, G.; et al. (September 1981). "Monte guardia sequence: a late-pleistocene eruptive cycle on Lipari (Italy)". Bulletin Volcanologique. 44 (3): 241–255. Bibcode:1981BVol...44..241C. doi:10.1007/BF02600562. S2CID 128627430.
  26. ^ Zelenka, Tibor; Balázs, Endre; Balogh, Kadosa; Kiss, János (December 2004). "Buried Neogene volcanic structures in Hungary" (PDF). Acta Geologica Hungarica. 47 (2–3): 177–219. doi:10.1556/ageol.47.2004.2-3.6.
  27. ^ a b Philpotts & Ague 2009, p. 77.
  28. ^ Howells, M. F.; Reedman, A. J.; Campbell, S. D. G. (May 1986). "The submarine eruption and emplacement of the Lower Rhyolitic Tuff Formation (Ordovician), N Wales". Journal of the Geological Society. 143 (3): 411–423. Bibcode:1986JGSoc.143..411H. doi:10.1144/gsjgs.143.3.0411. S2CID 129147300.
  29. ^ Carney, John (2000). "Igneous processes within late Precambrian volcanic centres near Whitwick, northwestern Charnwood Forest" (PDF). Mercian Geologist. 15 (1): 7–28. Retrieved 1 October 2020.
  30. ^ McArthur, A. N.; Cas, R. A. F.; Orton, G. J. (30 November 1998). "Distribution and significance of crystalline, perlitic and vesicular textures in the Ordovician Garth Tuff (Wales)". Bulletin of Volcanology. 60 (4): 260–285. Bibcode:1998BVol...60..260M. doi:10.1007/s004450050232. S2CID 128474768.
  31. ^ Matthews, Naomi E.; Vazquez, Jorge A.; Calvert, Andrew T. (August 2015). "Age of the Lava Creek supereruption and magma chamber assembly at Yellowstone based on 40 Ar/ 39 Ar and U-Pb dating of sanidine and zircon crystals: AGE OF THE LAVA CREEK SUPERERUPTION". Geochemistry, Geophysics, Geosystems. 16 (8): 2508–2528. doi:10.1002/2015GC005881. S2CID 131340369.
  32. ^ "What is a supervolcano? What is a supereruption?". Natural Hazards. United States Geological Survey. Retrieved 30 September 2020.
  33. ^ Dennison, J. M.; Textoris, D. A. (March 1970). "Devonian tioga tuff in Northeastern United States". Bulletin Volcanologique. 34 (1): 289–294. Bibcode:1970BVol...34..289D. doi:10.1007/BF02597791. S2CID 129708915.
  34. ^ Lippolt, H. J. (1983). "Distribution of Volcanic Activity in Space and Time". Plateau Uplift. pp. 112–120. doi:10.1007/978-3-642-69219-2_15. ISBN 978-3-642-69221-5.
  35. ^ Gillot, P-Y.; Chiesa, S.; Pasquaré, G.; Vezzoli, L. (September 1982). "<33,000-yr K–Ar dating of the volcano–tectonic horst of the Isle of Ischia, Gulf of Naples". Nature. 299 (5880): 242–245. Bibcode:1982Natur.299..242G. doi:10.1038/299242a0. S2CID 4332634.
  36. ^ Giannetti, Bernardino; De Casa, Giancarlo (March 2000). "Stratigraphy, chronology, and sedimentology of ignimbrites from the white trachytic tuff, Roccamonfina Volcano, Italy". Journal of Volcanology and Geothermal Research. 96 (3–4): 243–295. Bibcode:2000JVGR...96..243G. doi:10.1016/S0377-0273(99)00144-4.
  37. ^ Macdonald, R.; Kjarsgaard, B. A.; Skilling, I. P.; Davies, G. R.; Hamilton, D. L.; Black, S. (June 1993). "Liquid immiscibility between trachyte and carbonate in ash flow tuffs from Kenya". Contributions to Mineralogy and Petrology. 114 (2): 276–287. Bibcode:1993CoMP..114..276M. doi:10.1007/BF00307762. S2CID 128821707.
  38. ^ Motoki, Akihisa; Geraldes, Mauro Cesar; Iwanuch, Woldemar; Vargas, Thais; Motoki, Kenji Freire; Balmant, Alex; Ramos, Marina Nascimento (March 2012). "The pyroclastic dyke and welded crystal tuff of the Morro dos Gatos alkaline intrusive complex, State of Rio de Janeiro, Brazil". Rem: Revista Escola de Minas. 65 (1): 35–45. doi:10.1590/S0370-44672012000100006.
  39. ^ Donnelly-Nolan, Julie M.; Nolan, K. Michael (1 October 1986). "Catastrophic flooding and eruption of ash-flow tuff at Medicine Lake volcano, California". Geology. 14 (10): 875–878. Bibcode:1986Geo....14..875D. doi:10.1130/0091-7613(1986)14<875:CFAEOA>2.0.CO;2.
  40. ^ Nokleberg, Warren J.; Jones, David L.; Silberling, Norman J. (1 October 1985). "Origin and tectonic evolution of the Maclaren and Wrangellia terranes, eastern Alaska Range, Alaska". GSA Bulletin. 96 (10): 1251–1270. Bibcode:1985GSAB...96.1251N. doi:10.1130/0016-7606(1985)96<1251:OATEOT>2.0.CO;2.
  41. ^ Grunder, Anita L. (1987). "Low ?18O silicic volcanic rocks at the Calabozos caldera complex, southern Andes: Evidence for upper-crustal contamination". Contributions to Mineralogy and Petrology. 95 (1): 71–81. doi:10.1007/BF00518031. S2CID 128952431.
  42. ^ Cronin, Shane J.; Neall, Vincent E.; Palmer, Alan S. (January 1996). "Geological history of the north-eastern ring plain of Ruapehu volcano, New Zealand". Quaternary International. 34–36: 21–28. Bibcode:1996QuInt..34...21C. doi:10.1016/1040-6182(95)00066-6.
  43. ^ Tatsumi, Yoshiyuki; Ishizaka, Kyoichi (April 1982). "Magnesian andesite and basalt from Shodo-Shima Island, southwest Japan, and their bearing on the genesis of calc-alkaline andesites". Lithos. 15 (2): 161–172. Bibcode:1982Litho..15..161T. doi:10.1016/0024-4937(82)90007-X.
  44. ^ Oertel, G. (1970). "Deformation of a Slaty, Lapillar Tuff in the Lake District, England". Geological Society of America Bulletin. 81 (4): 1173. Bibcode:1970GSAB...81.1173O. doi:10.1130/0016-7606(1970)81[1173:DOASLT]2.0.CO;2.
  45. ^ Macdonald, Gordon A. (1983). Volcanoes in the sea: the geology of Hawaii (2nd ed.). Honolulu: University of Hawaii Press. p. 9. ISBN 0-8248-0832-0.
  46. ^ Macdonald 1983, pp. 17–20.
  47. ^ Macdonald 1983, pp. 349–353.
  48. ^ Milidragovic, D.; Joyce, N.L.; Zagorevski, A.; Chapman, J.B. (2015). "Petrology of explosive Middle-Upper Triassic ultramafic rocks in the Mess Creek area, northern Stikine terrane". Geological Fieldwork: 2016–1. Retrieved 27 July 2021.
  49. ^ Richan, Lindsay; Gibson, Harold L.; Houlé, Michel G.; Lesher, C. Michael (2015). "Mode of emplacement of Archean komatiitic tuffs and flows in the Selkirk Bay area, Melville Peninsula, Nunavut, Canada". Precambrian Research. 263: 174–196. Bibcode:2015PreR..263..174R. doi:10.1016/j.precamres.2015.03.004.
  50. ^ Huber, M.S.; Byerly, G.R. (2018). "Volcanological and petrogenetic characteristics of komatiites of the 3.3 Ga Saw Mill Complex, Weltevreden Formation, Barberton Greenstone Belt, South Africa". South African Journal of Geology. 121 (4): 463–486. Bibcode:2018SAJG..121..463H. doi:10.25131/sajg.121.0031. S2CID 56281060.
  51. ^ Panei, Liliana (10 April 2010). "The tuffs of the "Servian Wall" in Rome: Materials from the local quarries and from the conquered territories". ArchéoSciences (34): 39–43. doi:10.4000/archeosciences.2599.
  52. ^ Giavarini, Carlo, A. Samueli Ferretti, and Maria Laura Santarelli. 2006. "Mechanical characteristics of Roman 'opus caementicium'". Fracture and Failure of Natural Building Stones. Applications in the Restoration of Ancient Monuments. pp. 108, 110
  53. ^ Schmincke 2003, pp. 280–281.
  54. ^ Georg Dehio: Handbuch der deutschen Kunstdenkmäler, Sachsen II. Deutscher Kunstverlag, München, Berlin 1998, p. 160
  55. ^ Heiner Siedel: Sächsische „Porphyrtuffe" aus dem Rotliegend als Baugesteine: Vorkommen und Abbau, Anwendung, Eigenschaften und Verwitterung. In: Institut für Steinkonservierung e. V. Bericht Nr. 22, 2006, p. 47-58. (PDF). Archived from the original (PDF) on 2011-06-11. Retrieved 2010-05-09.{{cite web}}: CS1 maint: archived copy as title (link)
  56. ^ Long, Jane C .S.; Ewing, Rodney C. (19 May 2004). "YUCCA MOUNTAIN: Earth-Science Issues at a Geologic Repository for High-Level Nuclear Waste". Annual Review of Earth and Planetary Sciences. 32 (1): 363–401. Bibcode:2004AREPS..32..363L. doi:10.1146/annurev.earth.32.092203.122444.
  57. ^ Kositsky, Andrew; Lewis, Scott (2016). "Seismic Performance of Wine Caves" (PDF). The World Tunnel Conference. Retrieved 1 October 2020.
  58. ^ Holding, N. (2006). Armenia: with Nagorno Karabagh. Bradt Travel Guides. p. 32. ISBN 978-1-84162-163-0. Retrieved May 26, 2010.
  59. ^ Billock, Jennifer (28 December 2016). . Smithsonian. Archived from the original on 9 June 2020. ...pink tuff is rare outside of the region and Yerevan is the only major city built out of this stone.
  60. ^ Lottman, Herbert R. (29 February 1976). "Despite Ages of Captivity, The Armenians Persevere". The New York Times. The city, whose population is now upwards of 800,000, has been rebuilt in the rosy volcanic stone called tufa...
  61. ^ Haviland, William A; Harald, E. L. Prins; Dana, Walrath; McBride, Bunny (2015). The Essence of Anthropology (4th ed.). Cengage Learning. p. 137. ...walls of monumental buildings at Ani (including the fortifications) were built of smoothly dressed blocks of tuff stone...
  62. ^ Hakobian, T. Kh.; Melik-Bakhshian, St. T. [in Armenian]; Barseghian, H. Kh. [in Armenian] (2001). "Տուֆաշեն [Tufashen]". Հայաստանի և հարակից շրջանների տեղանունների բառարան [Dictionary of Toponyms of Armenia and Surrounding Regions] Volume V (in Armenian). Yerevan University Press. p. 147.
  63. ^ Hakobyan, Tadevos Kh. (1988). Անի մայրաքաղաք [Ani the Capital] (in Armenian). Yerevan: Yerevan University Press. p. 118.
  64. ^ Philpotts and Ague 2009, p. 74
  65. ^ Fisher & Schmincke 1984, pp. 352–356.
  66. ^ Daniel, Christopher G.; Pfeifer, Lily S.; Jones, James V III; McFarlane, Christopher M. (2013). "Detrital zircon evidence for non-Laurentian provenance, Mesoproterozoic (ca. 1490–1450 Ma) deposition and orogenesis in a reconstructed orogenic belt, northern New Mexico, USA: Defining the Picuris orogeny". GSA Bulletin. 125 (9–10): 1423–1441. Bibcode:2013GSAB..125.1423D. doi:10.1130/B30804.1. Retrieved 17 April 2020.
  67. ^ "Definition of 'tuff'". Collins English Dictionary. HarperCollins. Retrieved 30 September 2020.

External links edit

  •   Media related to Tuff at Wikimedia Commons

December 15, 2023
tuff, other, uses, disambiguation, confused, with, tufa, type, rock, made, volcanic, ejected, from, vent, during, volcanic, eruption, following, ejection, deposition, lithified, into, solid, rock, rock, that, contains, greater, than, considered, tuff, while, r. For other uses see Tuff disambiguation Not to be confused with Tufa Tuff is a type of rock made of volcanic ash ejected from a vent during a volcanic eruption Following ejection and deposition the ash is lithified into a solid rock 1 2 Rock that contains greater than 75 ash is considered tuff while rock containing 25 to 75 ash is described as tuffaceous for example tuffaceous sandstone 3 Tuff composed of sandy volcanic material can be referred to as volcanic sandstone 4 Cliff face of welded tuff pockmarked with holes some natural some man made from Bandelier National Monument New MexicoEtruscan tuff blocks from a tomb at BanditacciaA house constructed of tuff blocks in GermanyTuff is a relatively soft rock so it has been used for construction since ancient times 5 Because it is common in Italy the Romans used it often for construction 6 The Rapa Nui people used it to make most of the moai statues on Easter Island 7 Tuff can be classified as either igneous or sedimentary rock It is usually studied in the context of igneous petrology although it is sometimes described using sedimentological terms Tuff is often erroneously called tufa in guidebooks and in television programs but tufa is a form of travertine Contents 1 Volcanic ash 2 Transport and lithification 3 Occurrences 3 1 High silica volcanism 3 2 Alkaline volcanism 3 3 Intermediate volcanism 3 4 Mafic volcanism 3 5 Ultramafic volcanism 3 5 1 Kimberlites 3 5 2 Komatiites 3 6 Folding and metamorphism 4 Importance 4 1 In Armenia 4 2 Tephrochronology 5 Etymology 6 See also 7 References 8 External linksVolcanic ash editThe material that is expelled in a volcanic eruption can be classified into three types Volcanic gases a mixture made mostly of steam carbon dioxide and a sulfur compound either sulfur dioxide SO2 or hydrogen sulfide H2S depending on the temperature Lava the name of magma when it emerges and flows over the surface Tephra particles of solid material of all shapes and sizes ejected and thrown through the air nbsp Light microscope image of tuff as seen in thin section long dimension is several mm The curved shapes of altered glass shards ash fragments are well preserved although the glass is partly altered The shapes were formed about bubbles of expanding water rich gas Tephra is made when magma inside the volcano is blown apart by the rapid expansion of hot volcanic gases Magma commonly explodes as the gas dissolved in it comes out of solution as the pressure decreases when it flows to the surface These violent explosions produce particles of material that can then fly from the volcano Solid particles smaller than 2 mm in diameter sand sized or smaller are called volcanic ash 8 3 Volcanic ash is further divided into fine ash with particle sizes smaller than 0 0625 mm in diameter and coarse ash with particle sizes between 0 0625 mm and 2 mm in diameter Tuff is correspondingly divided into coarse tuff coarse ash tuff and fine tuff fine ash tuff or dust tuff Consolidated tephra composed mostly of coarser particles is called lapillistone particles 2 mm to 64 mm in diameter or agglomerate or pyroclastic breccia particles over 64 mm in diameter rather than tuff 3 Volcanic ash can vary greatly in composition and so tuffs are further classified by the composition of the ash from which they formed Ash from high silica volcanism particularly in ash flows consists mainly of shards of volcanic glass 9 10 and tuff formed predominantly from glass shards is described as vitric tuff 11 The glass shards are typically either irregular in shape or are roughly triangular with convex sides They are the shattered walls of countless small bubbles that formed in the magma as dissolved gases rapidly came out of solution 12 Tuffs formed from ash consisting predominantly of individual crystals are described as crystal tuffs while those formed from ash consisting predominantly of pulverized rock fragments are described as lithic tuffs 11 The chemical composition of volcanic ash reflects the entire range of volcanic rock chemistry from high silica rhyolitic ash to low silica basaltic ash and tuffs are likewise described as rhyolitic andesitic basaltic and so on 13 Transport and lithification editThe most straightforward way for volcanic ash to move away from the vent is as ash clouds that are part of an eruption column These fall to the surface as fallout deposits that are characteristically well sorted and tend to form a blanket of uniform thickness across terrain Column collapse results in a more spectacular and destructive form of transport which takes the form of pyroclastic flows and surges that characteristically are poorly sorted and pool in low terrain Surge deposits sometimes show sedimentary structures typical of high velocity flow such as dunes and antidunes 14 Volcanic ash already deposited on the surface can be transported as mud flows lahars when mingled with water from rainfall or through eruption into a body of water or ice 15 Particles of volcanic ash that are sufficiently hot will weld together after settling to the surface producing a welded tuff Welding requires temperatures in excess of 600 C 1 100 F If the rock contains scattered pea sized fragments or fiamme in it it is called a welded lapilli tuff Welded tuffs and welded lapilli tuffs can be of fallout origin or deposited from ash flows as in the case of ignimbrites 16 During welding the glass shards and pumice fragments adhere together necking at point contacts deform and compact together resulting in a eutaxitic fabric 17 Welded tuff is commonly rhyolitic in composition but examples of all compositions are known 18 19 A sequence of ash flows may consist of multiple cooling units These can be distinguished by the degree of welding The base of a cooling unit is typically unwelded due to chilling from the underlying cold surface and the degree of welding and of secondary reactions from fluids in the flow increases upwards towards the center of the flow Welding decreases towards the top of the cooling unit where the unit cools more rapidly The intensity of welding may also decrease towards areas in which the deposit is thinner and with distance from source 20 Cooler pyroclastic flows are unwelded and the ash sheets deposited by them are relatively unconsolidated 17 However cooled volcanic ash can quickly become lithified because it usually has a high content of volcanic glass This is a thermodynamically unstable material that reacts rapidly with ground water or sea water which leaches alkali metals and calcium from the glass New minerals such as zeolites clays and calcite crystallize from the dissolved substances and cement the tuff 21 Tuffs are further classified by their depositional environment such as lacustrine tuff subaerial tuff or submarine tuff or by the mechanism by which the ash was transported such as fallout tuff or ash flow tuff Reworked tuffs formed by erosion and redeposition of ash deposits are usually described by the transport agent such as aeolian tuff or fluvial tuff 22 nbsp Layers of fallout tuff in Japan nbsp Rocks from the Bishop tuff in California unwelded with pumice on left welded with fiamme on right nbsp Bandelier Tuff at San Diego Canyon New Mexico USA The lower Otowi Member is a single massive cooling unit while the upper Tshirege Member is composed of multiple cooling units Occurrences editTuffs have the potential to be deposited wherever explosive volcanism takes place and so have a wide distribution in location and age 23 High silica volcanism edit Rhyolite tuffs contain pumiceous glassy fragments and small scoriae with quartz alkali feldspar biotite etc Iceland 24 Lipari 25 Hungary 26 the Basin and Range of the American southwest and New Zealand 27 are among the areas where such tuffs are prominent In the ancient rocks of Wales 28 Charnwood 29 etc similar tuffs are known but in all cases they are greatly changed by silicification which has filled them with opal chalcedony and quartz and by devitrification 30 The frequent presence of rounded corroded quartz crystals such as occur in rhyolitic lavas helps to demonstrate their real nature 8 Welded ignimbrites can be highly voluminous such as the Lava Creek Tuff erupted from Yellowstone Caldera in Wyoming 631 000 years ago This tuff had an original volume of at least 1 000 cubic kilometers 240 cu mi 31 Lava Creek tuff is known to be at least 1000 times as large as the deposits of the 1980 eruption of Mount St Helens and it had a Volcanic Explosivity Index VEI of 8 greater than any eruption known in the last 10 000 years 32 Ash flow tuffs cover 7 000 square kilometers 2 700 sq mi of the North Island of New Zealand and about 100 000 square kilometers 39 000 sq mi of Nevada Ash flow tuffs are the only volcanic product with volumes rivaling those of flood basalts 27 The Tioga Bentonite of the northeastern United States varies in composition from crystal tuff to tuffaceous shale It was deposited as ash carried by wind that fell out over the sea and settled to the bottom It is Devonian in age and likely came from a vent in central Virginia where the tuff reaches its maximum thickness of about 40 meters 130 ft 33 Alkaline volcanism edit Trachyte tuffs contain little or no quartz but much sanidine or anorthoclase and sometimes oligoclase feldspar with occasional biotite augite and hornblende In weathering they often change to soft red or yellow claystones rich in kaolin with secondary quartz 8 Recent trachyte tuffs are found on the Rhine at Siebengebirge 34 in Ischia 35 and near Naples 36 Trachyte carbonatite tuffs have been identified in the East African Rift 37 Alkaline crystal tuffs have been reported from Rio de Janeiro 38 Intermediate volcanism edit Andesitic tuffs are exceedingly common They occur along the whole chain of the Cordilleras 39 40 and Andes 41 in the West Indies New Zealand 42 Japan 43 etc In the Lake District 44 North Wales Lorne the Pentland Hills the Cheviots and many other districts of Great Britain ancient rocks of exactly similar nature are abundant In color they are red or brown their scoriae fragments are of all sizes from huge blocks down to minute granular dust The cavities are filled with many secondary minerals such as calcite chlorite quartz epidote or chalcedony in microscopic sections though the nature of the original lava can nearly always be made out from the shapes and properties of the little crystals which occur in the decomposed glassy base Even in the smallest details these ancient tuffs have a complete resemblance to the modern ash beds of Cotopaxi Krakatoa and Mont Pele 8 Mafic volcanism edit nbsp Diamond Head a tuff cone nbsp Most of the moais in Easter Island are carved out of tholeiite basalt tuff Mafic volcanism typically takes the form of Hawaiian eruptions that are nonexplosive and produce little ash 45 However interaction between basaltic magma and groundwater or sea water results in hydromagmatic explosions that produce abundant ash These deposit ash cones that subsequently can become cemented into tuff cones Diamond Head Hawaii is an example of a tuff cone as is the island of Ka ula The glassy basaltic ash produced in such eruptions rapidly alters to palagonite as part of the process of lithification 46 Although conventional mafic volcanism produce little ash such ash as is formed may accumulate locally as significant deposits An example is the Pahala ash of Hawaii island which locally is as thick as 15 meters 49 ft These deposits also rapidly alter to palagonite and eventually weather to laterite 47 Basaltic tuffs are also found in Skye Mull Antrim and other places where Paleogene volcanic rocks are found in Scotland Derbyshire and Ireland among the Carboniferous strata and among the still older rocks of the Lake District the southern uplands of Scotland and Wales They are black dark green or red in colour vary greatly in coarseness some being full of round spongy bombs a foot or more in diameter and being often submarine may contain shale sandstone grit and other sedimentary material and are occasionally fossiliferous Recent basaltic tuffs are found in Iceland the Faroe Islands Jan Mayen Sicily the Hawaiian Islands Samoa etc When weathered they are filled with calcite chlorite serpentine and especially where the lavas contain nepheline or leucite are often rich in zeolites such as analcite prehnite natrolite scolecite chabazite heulandite etc 8 Ultramafic volcanism edit Ultramafic tuffs are extremely rare their characteristic is the abundance of olivine or serpentine and the scarcity or absence of feldspar and quartz 48 Kimberlites edit Occurrences of ultramafic tuff include surface deposits of kimberlite at maars in the diamond fields of southern Africa and other regions The principal variety of kimberlite is a dark bluish green serpentine rich breccia blue ground which when thoroughly oxidized and weathered becomes a friable brown or yellow mass the yellow ground 8 These breccias were emplaced as gas solid mixtures and are typically preserved and mined in diatremes that form intrusive pipe like structures At depth some kimberlite breccias grade into root zones of dikes made of unfragmented rock At the surface ultramafic tuffs may occur in maar deposits Because kimberlites are the most common igneous source of diamonds the transitions from maar to diatreme to root zone dikes have been studied in detail Diatreme facies kimberlite is more properly called an ultramafic breccia rather than a tuff Komatiites edit Komatiite tuffs are found for example in the greenstone belts of Canada and South Africa 49 50 Folding and metamorphism edit nbsp Remains of the ancient Servian Walls in Rome made of tuff blocks nbsp 19th century embankment wall built of Brisbane tuff City of BrisbaneIn course of time changes other than weathering may overtake tuff deposits Sometimes they are involved in folding and become sheared and cleaved Many of the green slates of the English Lake District are finely cleaved ashes In Charnwood Forest also the tuffs are slaty and cleaved The green color is due to the large development of chlorite Among the crystalline schists of many regions green beds or green schists occur which consist of quartz hornblende chlorite or biotite iron oxides feldspar etc and are probably recrystallized or metamorphosed tuffs They often accompany masses of epidiorite and hornblende schists which are the corresponding lavas and sills Some chlorite schists also are probably altered beds of volcanic tuff The Schalsteins of Devon and Germany include many cleaved and partly recrystallized ash beds some of which still retain their fragmental structure though their lapilli are flattened and drawn out Their steam cavities are usually filled with calcite but sometimes with quartz The more completely altered forms of these rocks are platy green chloritic schists in these however structures indicating their original volcanic nature only sparingly occur These are intermediate stages between cleaved tuffs and crystalline schists 8 Importance editThe primary economic value of tuff is as a building material In the ancient world tuff s relative softness meant that it was commonly used for construction where it was available 5 Tuff is common in Italy and the Romans used it for many buildings and bridges 6 For example the whole port of the island of Ventotene still in use was carved from tuff The Servian Wall built to defend the city of Rome in the fourth century BC is also built almost entirely from tuff 51 The Romans also cut tuff into small rectangular stones that they used to create walls in a pattern known as opus reticulatum 52 The peperino much used at Rome and Naples as a building stone is a trachyte tuff Pozzolana also is a decomposed tuff but of basic character originally obtained near Naples and used as a cement but this name is now applied to a number of substances not always of identical character In the Eifel region of Germany a trachytic pumiceous tuff called trass has been extensively worked as a hydraulic mortar 8 Tuff of the Eifel region of Germany has been widely used for construction of railroad stations and other buildings in Frankfurt Hamburg and other large cities 53 Construction using the Rochlitz Porphyr can be seen in the Mannerist style sculpted portal outside the chapel entrance in Colditz Castle 54 The trade name Rochlitz Porphyr is the traditional designation for a dimension stone of Saxony with an architectural history over 1 000 years in Germany The quarries are located near Rochlitz 55 Yucca Mountain nuclear waste repository a U S Department of Energy terminal storage facility for spent nuclear reactor and other radioactive waste is in tuff and ignimbrite in the Basin and Range Province in Nevada 56 In Napa Valley and Sonoma Valley California areas made of tuff are routinely excavated for storage of wine barrels 57 Tuff from Rano Raraku was used by the Rapa Nui people of Easter Island to make the vast majority of their famous moai statues 7 nbsp Ahu Tongariki on Easter Island with 15 moai made of tuff from Rano Raraku crater The second moai from the right has a Pukao topknot which is made of red scoria nbsp The rhyolitic tuff portal of the church house at Colditz Castle Saxony designed by Andreas Walther II 1584 In Armenia edit Tuff is used extensively in Armenia and Armenian architecture 58 It is the dominant type of stone used in construction in Armenia s capital Yerevan 59 60 Gyumri Armenia s second largest city and Ani the country s medieval capital now in Turkey 61 A small village in Armenia was renamed Tufashen literally village of tuff in 1946 62 nbsp Armenia s Government House in Yerevan s Republic Square built of yellow tuff nbsp Holy Saviour s Church in Gyumri built mainly of black tuff nbsp Cathedral of Ani early 11th century in the medieval Armenian capital of Ani modern day Turkey was built in tuff 63 Tephrochronology edit Main article Tephrochronology nbsp Pilar Formation outcrop showing metatuff beds used for radiometric datingTuffs are deposited geologically instantaneously and often over a large region This makes them highly useful as time stratigraphic markers The use of tuffs and other tephra deposits in this manner is known as tephrochronology and is particularly useful for Quaternary chronostratigraphy Individual tuff beds can be fingerprinted by their chemical composition and phenocryst assemblages 64 Absolute ages for tuff beds can be determined by K Ar Ar Ar or carbon 14 dating 65 Zircon grains found in many tuffs are highly durable and can survive even metamorphism of the host tuff to schist allowing absolute ages to be assigned to ancient metamorphic rocks For example dating of zircons in a metamorphosed tuff bed in the Pilar Formation provided some of the first evidence for the Picuris orogeny 66 Etymology editThe word tuff is derived from the Italian tufo 67 See also editBentonite Rock type or absorbent swelling clay Brisbane tuff Eutaxitic texture Layered or banded texture in some extrusive rock bodies Sillar Variety of rhyolite containing fragments of andesite Tuffite Tuff containing both pyroclastic and detrital materialsReferences edit Fisher Richard V Schmincke H U 1984 Pyroclastic rocks Berlin Springer Verlag pp 89 90 ISBN 3 540 12756 9 Schmincke Hans Ulrich 2003 Volcanism Berlin Springer p 138 ISBN 978 3 540 43650 8 a b c Schmidt R 1981 Descriptive nomenclature and classification of pyroclastic deposits and fragments recommendations of the IUGS Subcommission on the Systematics of Igneous Rocks Geology 9 41 43 doi 10 1007 BF01822152 S2CID 128375559 Retrieved 27 September 2020 Poole W H Neuman Robert B 2003 Arenig volcanic and sedimentary strata central New Brunswick and eastern Maine Atlantic Geology 38 2 3 doi 10 4138 1257 Retrieved 2022 09 24 a b Dolan S G Cates K M Conrad C N Copeland S R 14 March 2019 Home Away from Home Ancestral Pueblo Fieldhouses in the Northern Rio Grande Lanl Ur 19 21132 96 Retrieved 29 September 2020 a b Jackson M D Marra F Hay R L et al 2005 The Judicious Selection and Preservation of Tuff and Travertine Building Stone in Ancient Rome Archaeometry 47 3 485 510 doi 10 1111 j 1475 4754 2005 00215 x a b Richards Colin 2016 Making Moai Reconsidering concepts of riskin the construction of megalithic architecture in Rapa Nui Easter Island Rapa Nui Easter Island Cultural and Historical Perspectives Berlin Germany pp 160 161 ISBN 978 3 7329 0265 1 Retrieved 29 July 2021 a href Template Cite book html title Template Cite book cite book a CS1 maint location missing publisher link a b c d e f g h nbsp One or more of the preceding sentences incorporates text from a publication now in the public domain Chisholm Hugh ed 1911 Tuff Encyclopaedia Britannica 11th ed Cambridge University Press Fisher amp Schmincke 1984 p 96 Blatt Harvey Tracy Robert J 1996 Petrology Igneous Sedimentary and Metamorphic 2nd ed New York W H Freeman pp 27 29 ISBN 0 7167 2438 3 a b O Brien R T 1 March 1963 Classification of tuffs Journal of Sedimentary Research 33 1 234 235 Bibcode 1963JSedR 33 234O doi 10 1306 74D70E20 2B21 11D7 8648000102C1865D Blatt amp Tracy 1996 pp 27 29 Fisher amp Schmincke 1984 pp 98 99 Philpotts Anthony R Ague Jay J 2009 Principles of igneous and metamorphic petrology 2nd ed Cambridge UK Cambridge University Press p 73 ISBN 978 0 521 88006 0 Schmincke 2003 pp 138 157 Fisher amp Schmincke 1984 p 215 a b Schmincke 2003 pp 186 187 Fisher amp Schmincke 1984 p 209 Blatt amp Tracy 1996 p 29 Ross Clarence S Smith Robert L 1961 Ash flow tuffs Their origin geologic relations and identification USGS Profession Paper Series Professional Paper 366 19 doi 10 3133 pp366 Schmincke 2003 p 138 Fisher amp Schmincke 1984 pp 89 90 Philpotts amp Ague 2009 p 73 Jonasson K December 1994 Rhyolite volcanism in the Krafla central volcano north east Iceland Bulletin of Volcanology 56 6 7 516 528 Bibcode 1994BVol 56 516J doi 10 1007 BF00302832 S2CID 129012636 Crisci G M Rosa R Lanzafame G et al September 1981 Monte guardia sequence a late pleistocene eruptive cycle on Lipari Italy Bulletin Volcanologique 44 3 241 255 Bibcode 1981BVol 44 241C doi 10 1007 BF02600562 S2CID 128627430 Zelenka Tibor Balazs Endre Balogh Kadosa Kiss Janos December 2004 Buried Neogene volcanic structures in Hungary PDF Acta Geologica Hungarica 47 2 3 177 219 doi 10 1556 ageol 47 2004 2 3 6 a b Philpotts amp Ague 2009 p 77 Howells M F Reedman A J Campbell S D G May 1986 The submarine eruption and emplacement of the Lower Rhyolitic Tuff Formation Ordovician N Wales Journal of the Geological Society 143 3 411 423 Bibcode 1986JGSoc 143 411H doi 10 1144 gsjgs 143 3 0411 S2CID 129147300 Carney John 2000 Igneous processes within late Precambrian volcanic centres near Whitwick northwestern Charnwood Forest PDF Mercian Geologist 15 1 7 28 Retrieved 1 October 2020 McArthur A N Cas R A F Orton G J 30 November 1998 Distribution and significance of crystalline perlitic and vesicular textures in the Ordovician Garth Tuff Wales Bulletin of Volcanology 60 4 260 285 Bibcode 1998BVol 60 260M doi 10 1007 s004450050232 S2CID 128474768 Matthews Naomi E Vazquez Jorge A Calvert Andrew T August 2015 Age of the Lava Creek supereruption and magma chamber assembly at Yellowstone based on 40 Ar 39 Ar and U Pb dating of sanidine and zircon crystals AGE OF THE LAVA CREEK SUPERERUPTION Geochemistry Geophysics Geosystems 16 8 2508 2528 doi 10 1002 2015GC005881 S2CID 131340369 What is a supervolcano What is a supereruption Natural Hazards United States Geological Survey Retrieved 30 September 2020 Dennison J M Textoris D A March 1970 Devonian tioga tuff in Northeastern United States Bulletin Volcanologique 34 1 289 294 Bibcode 1970BVol 34 289D doi 10 1007 BF02597791 S2CID 129708915 Lippolt H J 1983 Distribution of Volcanic Activity in Space and Time Plateau Uplift pp 112 120 doi 10 1007 978 3 642 69219 2 15 ISBN 978 3 642 69221 5 Gillot P Y Chiesa S Pasquare G Vezzoli L September 1982 lt 33 000 yr K Ar dating of the volcano tectonic horst of the Isle of Ischia Gulf of Naples Nature 299 5880 242 245 Bibcode 1982Natur 299 242G doi 10 1038 299242a0 S2CID 4332634 Giannetti Bernardino De Casa Giancarlo March 2000 Stratigraphy chronology and sedimentology of ignimbrites from the white trachytic tuff Roccamonfina Volcano Italy Journal of Volcanology and Geothermal Research 96 3 4 243 295 Bibcode 2000JVGR 96 243G doi 10 1016 S0377 0273 99 00144 4 Macdonald R Kjarsgaard B A Skilling I P Davies G R Hamilton D L Black S June 1993 Liquid immiscibility between trachyte and carbonate in ash flow tuffs from Kenya Contributions to Mineralogy and Petrology 114 2 276 287 Bibcode 1993CoMP 114 276M doi 10 1007 BF00307762 S2CID 128821707 Motoki Akihisa Geraldes Mauro Cesar Iwanuch Woldemar Vargas Thais Motoki Kenji Freire Balmant Alex Ramos Marina Nascimento March 2012 The pyroclastic dyke and welded crystal tuff of the Morro dos Gatos alkaline intrusive complex State of Rio de Janeiro Brazil Rem Revista Escola de Minas 65 1 35 45 doi 10 1590 S0370 44672012000100006 Donnelly Nolan Julie M Nolan K Michael 1 October 1986 Catastrophic flooding and eruption of ash flow tuff at Medicine Lake volcano California Geology 14 10 875 878 Bibcode 1986Geo 14 875D doi 10 1130 0091 7613 1986 14 lt 875 CFAEOA gt 2 0 CO 2 Nokleberg Warren J Jones David L Silberling Norman J 1 October 1985 Origin and tectonic evolution of the Maclaren and Wrangellia terranes eastern Alaska Range Alaska GSA Bulletin 96 10 1251 1270 Bibcode 1985GSAB 96 1251N doi 10 1130 0016 7606 1985 96 lt 1251 OATEOT gt 2 0 CO 2 Grunder Anita L 1987 Low 18O silicic volcanic rocks at the Calabozos caldera complex southern Andes Evidence for upper crustal contamination Contributions to Mineralogy and Petrology 95 1 71 81 doi 10 1007 BF00518031 S2CID 128952431 Cronin Shane J Neall Vincent E Palmer Alan S January 1996 Geological history of the north eastern ring plain of Ruapehu volcano New Zealand Quaternary International 34 36 21 28 Bibcode 1996QuInt 34 21C doi 10 1016 1040 6182 95 00066 6 Tatsumi Yoshiyuki Ishizaka Kyoichi April 1982 Magnesian andesite and basalt from Shodo Shima Island southwest Japan and their bearing on the genesis of calc alkaline andesites Lithos 15 2 161 172 Bibcode 1982Litho 15 161T doi 10 1016 0024 4937 82 90007 X Oertel G 1970 Deformation of a Slaty Lapillar Tuff in the Lake District England Geological Society of America Bulletin 81 4 1173 Bibcode 1970GSAB 81 1173O doi 10 1130 0016 7606 1970 81 1173 DOASLT 2 0 CO 2 Macdonald Gordon A 1983 Volcanoes in the sea the geology of Hawaii 2nd ed Honolulu University of Hawaii Press p 9 ISBN 0 8248 0832 0 Macdonald 1983 pp 17 20 Macdonald 1983 pp 349 353 Milidragovic D Joyce N L Zagorevski A Chapman J B 2015 Petrology of explosive Middle Upper Triassic ultramafic rocks in the Mess Creek area northern Stikine terrane Geological Fieldwork 2016 1 Retrieved 27 July 2021 Richan Lindsay Gibson Harold L Houle Michel G Lesher C Michael 2015 Mode of emplacement of Archean komatiitic tuffs and flows in the Selkirk Bay area Melville Peninsula Nunavut Canada Precambrian Research 263 174 196 Bibcode 2015PreR 263 174R doi 10 1016 j precamres 2015 03 004 Huber M S Byerly G R 2018 Volcanological and petrogenetic characteristics of komatiites of the 3 3 Ga Saw Mill Complex Weltevreden Formation Barberton Greenstone Belt South Africa South African Journal of Geology 121 4 463 486 Bibcode 2018SAJG 121 463H doi 10 25131 sajg 121 0031 S2CID 56281060 Panei Liliana 10 April 2010 The tuffs of the Servian Wall in Rome Materials from the local quarries and from the conquered territories ArcheoSciences 34 39 43 doi 10 4000 archeosciences 2599 Giavarini Carlo A Samueli Ferretti and Maria Laura Santarelli 2006 Mechanical characteristics of Roman opus caementicium Fracture and Failure of Natural Building Stones Applications in the Restoration of Ancient Monuments pp 108 110 Schmincke 2003 pp 280 281 Georg Dehio Handbuch der deutschen Kunstdenkmaler Sachsen II Deutscher Kunstverlag Munchen Berlin 1998 p 160 Heiner Siedel Sachsische Porphyrtuffe aus dem Rotliegend als Baugesteine Vorkommen und Abbau Anwendung Eigenschaften und Verwitterung In Institut fur Steinkonservierung e V Bericht Nr 22 2006 p 47 58 Archived copy PDF Archived from the original PDF on 2011 06 11 Retrieved 2010 05 09 a href Template Cite web html title Template Cite web cite web a CS1 maint archived copy as title link Long Jane C S Ewing Rodney C 19 May 2004 YUCCA MOUNTAIN Earth Science Issues at a Geologic Repository for High Level Nuclear Waste Annual Review of Earth and Planetary Sciences 32 1 363 401 Bibcode 2004AREPS 32 363L doi 10 1146 annurev earth 32 092203 122444 Kositsky Andrew Lewis Scott 2016 Seismic Performance of Wine Caves PDF The World Tunnel Conference Retrieved 1 October 2020 Holding N 2006 Armenia with Nagorno Karabagh Bradt Travel Guides p 32 ISBN 978 1 84162 163 0 Retrieved May 26 2010 Billock Jennifer 28 December 2016 How Ancient Volcanoes Created Armenia s Pink City Smithsonian Archived from the original on 9 June 2020 pink tuff is rare outside of the region and Yerevan is the only major city built out of this stone Lottman Herbert R 29 February 1976 Despite Ages of Captivity The Armenians Persevere The New York Times The city whose population is now upwards of 800 000 has been rebuilt in the rosy volcanic stone called tufa Haviland William A Harald E L Prins Dana Walrath McBride Bunny 2015 The Essence of Anthropology 4th ed Cengage Learning p 137 walls of monumental buildings at Ani including the fortifications were built of smoothly dressed blocks of tuff stone Hakobian T Kh Melik Bakhshian St T in Armenian Barseghian H Kh in Armenian 2001 Տուֆաշեն Tufashen Հայաստանի և հարակից շրջանների տեղանունների բառարան Dictionary of Toponyms of Armenia and Surrounding Regions Volume V in Armenian Yerevan University Press p 147 Hakobyan Tadevos Kh 1988 Անի մայրաքաղաք Ani the Capital in Armenian Yerevan Yerevan University Press p 118 Philpotts and Ague 2009 p 74 Fisher amp Schmincke 1984 pp 352 356 Daniel Christopher G Pfeifer Lily S Jones James V III McFarlane Christopher M 2013 Detrital zircon evidence for non Laurentian provenance Mesoproterozoic ca 1490 1450 Ma deposition and orogenesis in a reconstructed orogenic belt northern New Mexico USA Defining the Picuris orogeny GSA Bulletin 125 9 10 1423 1441 Bibcode 2013GSAB 125 1423D doi 10 1130 B30804 1 Retrieved 17 April 2020 Definition of tuff Collins English Dictionary HarperCollins Retrieved 30 September 2020 External links edit nbsp Media related to Tuff at Wikimedia Commons Retrieved from https en wikipedia org w index php title Tuff amp oldid 1189368375 Welded tuff, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.