Abstract
Situated in a submerged continental rift, Pantelleria is a volcanic island with a subaerial eruptive history longer than 300 Ka. Its eruptive behavior, edifice morphologies, and complex, multiunit geologic history are representative of strongly peralkaline centers. It is dominated by the 6-km-wide Cinque Denti caldera, which formed ca. 45 Ka ago during eruption of the Green Tuff, a strongly rheomorphic unit zoned from pantellerite to trachyte and consisting of falls, surges, and pyroclastic flows. Soon after collapse, trachyte lava flows from an intracaldera central vent built a broad cone that compensated isostatically for the volume of the caldera and nearly filled it. Progressive chemical evolution of the chamber between 45 and 18 Ka ago is recorded in the increasing peralkalinity of the youngest lava of the intracaldera trachyte cone and the few lavas erupted northwest of the caldera. Beginning about 18 Ka ago, inflation of the chamber opened old ring fractures and new radial fractures, along which recently differentiated pantellerite constructed more than 25 pumice cones and shields. Continued uplift raised the northwest half of the intracaldera trachyte cone 275 m, creating the island's present summit, Montagna Grande, by trapdoor uplift. Pantellerite erupted along the trapdoor faults and their hingeline, forming numerous pumice cones and agglutinate sheets as well as five lava domes. Degassing and drawdown of the upper pantelleritic part of a compositionally and thermally stratified magma chamber during this 18-3-Ka episode led to entrainment of subjacent, crystal-rich, pantelleritic trachyte magma as crenulate inclusions. Progressive mixing between host and inclusions resulted in a secular decrease in the degree of evolution of the 0.82 km3 of magma erupted during the episode.
The 45-Ka-old caldera is nested within the La Vecchia caldera, which is thought to have formed around 114 Ka ago. This older caldera was filled by three widespread welded units erupted 106, 94, and 79 Ka ago. Reactivation of the ring fracture ca. 67 Ka ago is indicated by venting of a large pantellerite centero and a chain of small shields along the ring fault. For each of the two nested calderas, the onset of postcaldera ring-fracture volcanism coincides with a low stand of sea level.
Rates of chemical regeneration within the chamber are rapid, the 3% crystallization/Ka of the post-Green Tuff period being typical. Highly evolved pantellerites are rare, however, because intervals between major eruptions (averaging 13−6 Ka during the last 190 Ka) are short. Benmoreites and mugearites are entirely lacking. Fe-Ti-rich alkalic basalts have erupted peripherally along NW-trending lineaments parallel to the enclosing rift but not within the nested calderas, suggesting that felsic magma persists beneath them. The most recent basaltic eruption (in 1891) took place 4 km northwest of Pantelleria, manifesting the long-term northwestward migration of the volcanic focus. These strongly differentiated basalts reflect low-pressure fractional crystallization of partial melts of garnet peridotite that coalesce in small magma reservoirs replenished only infrequently in this continental rift environment.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Belluomini G, Discendenti A, Malpieri L, Nicoletti M (1970) Studi sulle ossidiane italiane: II Contenuto in40Ar radiogenico e possibilita di datazione. Period Mineral 39: 469–479
Bergeat A (1907) Staukuppen. Neues Jahrbuch Mineral Geol Pal Festband: 310–329
Bigazzi G, Bonadonna F, Belluomini G, Malpieri L (1971) Studi sulle ossidiane italiane: IV Datazione con il metodo delle tracce di fisione. Boll Soc Geol It 90: 469–480
Blake S, Ivey G (1984) Magma mixing and the dynamics of withdrawal from stratified reservoirs. In: Dungan MA, Grove TL, Hildreth W (eds) Proc Conf on Open Magmatic Systems, pp 13–15
Bryan WB (1966) History and mechanism of eruption of soda-rhyolite and alkali basalt, Socorro Island, Mexico. Bull Volcanol 29: 453–480
Butler GW (1892) Abstract of Mr A Ricco's account of the submarine eruption northwest of Pantelleria, October 1891. Nature 45: 584–585
Carapezza M, Ferra P, Mario Nucci P, Valenz M (1979) Caratteri petrologici e geochimici delle vulcaniti dell IsolaFerdinandea. Rend Soc Ital Mineral Petrol 35: 377–388
Civetta L, Cornette Y, Crisci G, Gillot PY, Orsi G, Requejo CS (1984) Geology, geochronology and chemical evolution of the island of telleria. Geol Mag 121: 541–562
Colombi B, Giese P, Luongo G, Morelli C, Riuscetti M, Scarascia S, Schute K, Strowald J, deVisintini G (1973) Preliminary report on the seismic refraction profile Gargano-Salerno-Palermo-Pantelleria (1971). Boll Geof Teor Appl 15: 225–254
Cornette Y, Crisci GM, Gillot PY, Orsi G (1983) Recent volcanic history of Pantelleria: A new interpretation. J Volcanol Geotherm Res 17: 361–373
DiPaola GM (1973) The island of Linosa (Sicily Channel). Bull Volcanol 37: 149–174
Finetti I, Morelli C (1973) Geophysical exploration of the Mediterranean Sea. Boll Geof Teor Appl 15: 263–333
Foerstner H (1881) Nota preliminare sulla geologia dell'isola di Pantelleria, secondo gli studi fatti negli anni 1874 e 1881. Boll R Comit Geol Ital 12: 523–556
Helz RT (1984) In situ fractionation of olivine tholeiite: Kilauea Iki lava lake. Geol. Soc Am Abst Prog 16: 536–537
Johnson RW (1969) Volcanic geology of Mount Suswa, Kenya. Phil Trans R Soc London Ser A 265: 383–412
Keller J, Ryan WBF, Ninkovich D, Altherr R (1978) Explosive volcanic activity in the Mediterranean over the past 200 000 yr. as recorded in deep-sea sediments. Geol Soc Am Bull 89: 591–604
Leat PT, Macdonald R, Smith RL (1984) Geochemical evolution of the Menengai caldera volcano, Kenya. J Geophys Res 89: 8571–8592
Lipman PW (1984) The roots of ash flow calderas in western North America: Windows into the tops of granitic batholiths. J Geophys Res 89: 8801–8841
Macdonald R (1974) Tectonic settings and magma associations. Bull Volcanol 38: 575–593
Mahood GA (1984) Calderas associated with strongly peralkaline volcanic rocks. J Geophys Res 89: 8540–8552
Mahood GA, Baker D (1986) Experimental constraints on depths of fractionation of mildly alkalic basalts and associated felsic rocks: Pantelleria, Strait of Sicily. Contrib Mineral Petrol 93: 251–264
Mahood GA, Drake RE (1982) K-Ar dating young rhyolitic rocks: A case study of the Sierra La Primavera, Jalisco, Mexico. Geol Soc Am Bull 93: 1232–1241
Mahood GA, Hildreth W (1983) Nested calderas and trapdoor uplift at Pantelleria, Strait of Sicily. Geology 11: 103–106
Mahood G, Wallmann P (1985) Correlation of eruptions at an island volcano with glacial sea level drawdown: Pantelleria, Italy. Eos, Trans Am Geophys Union 66: 1141
Marshall P (1935) Acid rocks of Taupo-Rotorua volcanic district. R Soc New Zealand Trans 64: 323–366
McCall GJH (1967–1969) The five caldera volcanoes of the Central Rift Valley, Kenya. Proc Geol Soc London 1646–1652: 54–59
McGetchin TR, Ulrich WG (1973) Xenoliths in maars and diatremes with inferences for the Moon, Mars, and Venus. J Geophys Res 78: 1833–1853
Morelli C, Gantar C, Pisani M (1975) Bathymetry, gravity, and magnetism in the Strait of Sicily and in the Ionian Sea. Boll Geof Teor Appl 17
Nicholls J, Carmichael ISE (1969) Peralkaline acid liquids: A petrological study. Contrib Mineral Petrol 20: 268–294
Noble DC (1968) Kane Springs Wash volcanic center, Lincoln County, Nevada. Geol Soc Am Mem 110: 109–116
Orsi G, Sheridan MF (1986) The Green Tuff of Pantelleria: an example of rheoignimbrite. Abstr Intl Volcanol Cong, New Zealand: 67
Rittmann A (1967) Studio geovulcanologico e magmato dell'Isola di Pantelleria. Riv Min Sicil 106–108: 147–182
Schmincke H-U (1974) Volcanological aspects of peralkaline silicic welded ash flow-tuffs. Bull Volcanol 38: 594–636
Shackleton JC, vanAndel TH, Runnels CN (1984) Coastal paleography of the central and western Mediterranean during the last 125 000 years and its archaeological implications. J Field Arch 11: 308–314
Smith RL, Bailey RA (1968) Resurgent cauldrons. Geol Soc Am Mem 116: 613–662
Sparks RSJ (1978) The dynamics of bubble formation and growth in magmas: A review and analysis. J Volcanol Geotherm Res 3: 1–37
Sparks RSJ, Wilson L (1976) A model for the formation of ignimbrite by gravitational column collapse. J Geol Soc London 132: 441–451
Sparks RSJ, Wright JV (1979) Welded air-fall tuffs. Geol Soc Am Spec Pap 180: 155–166
Stacey JS, Sherrill ND, Dalrymple GB, Lanphyre MA, Carpenter NV (1981) A five-collector system for the simultaneous measurement of argon isotope ratios in a static mass spectrometer. Int J Mass Spectrom Ion Phys 39: 167–180
Thorarinsson S (1954) The eruption of Hekla, 1947–1948, Part II 3. The tephra-fall from Hekla on March 29th, 1947. Visindafelag Islendinga, 68 pp
Villari L (1968) On the geovolcanological and morphological evolution of an endogenous dome (Pantelleria, Mt Gelkhamar). Geol Rundsch 57: 784–794
Villari L (1969) On particular ignimbrites of the island of Pantelleria (Channel of Sicily). Bull Volcanol 33: 828–839
Villari L (1970a) The caldera of Pantelleria. Bull Volcanol 34: 758–766
Villari L (1970b) Studio petrologico di alcuni campioni dei pozzi Bagno dell'Acqua e Gadir. Rend Soc Ital Mineral Petrol 26: 353–376
Villari L (1974) The Island of Pantelleria. Bull Volcanol 38: 680–724
Vincent PM (1963) Les volcans Tertiaires et Quaternaires du Tibesti occidental et central, Sahara du Tchad. Bur Rech Geol Mineral Mem 23: 1–307
Walker GPL (1973) Explosive volcanic eruptions—a new classification scheme. Geol Rundsch 62: 431–446
Walker GPL, Heming RF, Wilson CJN (1980) Low-aspect ratio ignimbrites. Nature 283: 286–287
Washington HS (1907) The titaniferous basalts of the western Mediterraneath: a preliminary notice. Qu J Geol Soc London 63: 69–79
Washington HS (1909) The submarine eruptions of 1831 and 1891 near Pantelleria. Am J Sci 27: 131–150
Washington HS (1913–1914) The volcanoes and rocks of Pantelleria: I, II, and III. J Geol 21: 653–670; 21:683–713; 22: 16–27
Williams H (1941) Calderas and their origin. Univ Calif Berkeley Publ Geol Sci 25: 239–346
Williams H, Goles G (1968) Volume of the Mazama ash-fall and the origin of Crater Lake caldera. Oregon State Dept Geol Mineral Indust Bull 62: 37–41
Williams H, McBirney AR (1979) Volcanology. Freeman San Francisco, pp 1–391
Williams LAJ, Macdonald R, Chapman GR (1984) Late Quaternary caldera volcanoes of the Kenya Rift Valley. J Geophys Res 89: 8553–8570
Wilson L, Sparks RSJ, Walker GPL (1980) Explosive volcanic eruptions, IV. The control of magma properties and conduit geometry on eruption column behavior. Geophys J R Astron Soc 63: 117–148
Wolff JA, Wright JV (1981a) Rheomorphism of welded tuffs. J Volcanol Geotherm Res 10: 13–34
Wolff JA, Wright JV (1981b) Formation of the Green Tuff, Pantelleria. Bull Volcanol 44: 681–690
Wright JV (1980) Stratigraphy and geology of the welded air-fall tuffs of Pantelleria, Italy. Geol Rundsch 69: 263–291
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Mahood, G.A., Hildreth, W. Geology of the peralkaline volcano at Pantelleria, Strait of Sicily. Bull Volcanol 48, 143–172 (1986). https://doi.org/10.1007/BF01046548
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF01046548