Abstract
The Tuxtla Volcanic Field (TVF) is located on the coast of the Gulf of Mexico in the southern part of the state of Veracruz, Mexico. Volcanism began about 7 my ago, in the Late Miocene, and continued to recent times with historical eruptions in ad 1664 and 1793. The oldest rocks occur as highly eroded remnants of lava flows in the area surrounding the historically active cone of San Martín Tuxtla. Between about 3 and 1 my ago, four large composite volcanoes were built in the eastern part of the area. Rocks from these structures are hydrothermally altered and covered with lateritic soils, and their northern slopes show extensive erosional dissection that has widened preexisting craters to form erosional calderas. The eastern volcanoes are composed of alkali basalts, hawaiites, mugearites, and benmoreites, with less common calc-alkaline basaltic andesites and andesites. In the western part of the area, San Martín Tuxtla Volcano and its over 250 satellite cinder cones and maars produced about 120 km3 of lava over the last 0.8 my. A ridge of flank cinder cones blocked drainage to the north to form Laguna Catemaco. Lavas erupted from San Martín and its flank vents are restricted to compositions between basanite and alkali basalt. The alignment of major volcanoes and flank vents along a N55°W trend suggests an extensional stress field in the crust with a minimum compressional stress orientation of N35° E. In total, about 800 km3 of lava has been erupted in the TVF in the last 7 my. This gives a magma output rate of about 0.1 km3/1000 year, a value smaller than most composite cones, but similar to cinder cone fields that occur in central Mexico. Individual eruptions over the last 5000 years had volumes on the order of 0.1km3, with average recurrence intervals of 600 years. The alkaline compositions of the TVF lavas contrast markedly with the calc-alkaline compositions erupted in the subduction-related Mexican Volcanic Belt to the west, leading previous workers to suggest that the TVF is not related to subduction. Trace-element signatures of TVF lavas indicate, however, that they are probably related to subduction. We suggest that the alkaline character of the TVF lavas is the result of low degrees of melting of a mantle source coupled with a stress regime that allows these small-volume melts to reach the surface in the TVF.
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References
Akers WH (1979) Planktonic foraminifera and calcareous nanoplankton biostratigraphy of the Neogene of Mexico, Part I —Middle Pliocene. Tulane Studies Geol Paleon 15:1–32
Aguilera-Gómez L (1988) Petrología de las rocas igneas del area de los Tuxtlas, Veracruz. Professional Thesis, Instituto Politécnico Nacional, México DF, México, pp 1–58
Besch T, Negendank JFW, Emmermann R, Tobschall HJ (1988) Geochemical constraints on the origin of calcalkaline and alkaline magmas of the eastern Trans-Mexican Volcanic Belt. Geof Int 7:641–663
Burbach GV, Frohlich C, Pennington WD, Matumoto T (1984) Seismicity and tectonics of the subducted Cocos Plate. J Geophys Res 89:7719–7735
Cantagrel J, Robin C (1979) K-Ar dating on eastern Mexican volcanic rocks — relations between the andesitic and the alkaline provinces. J Volcanol Geotherm Res 5:99–114
Cas RAF, Wright JV (1987) Volcanic successions modern and ancient. Allen & Unwin, London, pp 1–528
Coll de Hurtado A (1970) Carta geomorfológica de la región costera de los Tuxtlas, estado de Veracruz. Bol Inst Geog, Univ Nac Aut México III:23–28
Elías-Herrera M, Rubinovich-Kogan R, Lozano-Santa Cruz R, Sánchez-Zavala JL (1990) Petrología y mineralización de tierra raras del complejo ígneo El Picacho, Sierra de Tamaulipas. Bol Inst Geol Univ Nac Aut México 108:24–97
Friedlaender I, Sonder RA (1923) Über das Vulkangebiet von San Martín Tuxtla in Mexiko. Zeitschrift für Vulkanologie VII:162–187
Gomez-Pompa A (1973) Ecology of the vegetation of Veracruz. In: Graham A (ed) Vegetation and vegetational history of northern Latin America. Elsevier, Amsterdam, pp 1–393
Hasenaka T, Carmichael ISE (1985) The cinder cones of Michoacán-Guanajuato, central Mexico: their age, volume and distribution, and magma discharge rate. J Volcanol Geotherm Res 25:105–124
Hickey RL, Frey FA, Gerlach DC, Lopez-Escobar L (1986) Multiple sources for basaltic arc rocks from the southern volcanic zone of the Andes (34–41°S): trace element and isotopic evidence for contributions from subducted oceanic crust, mantle, and continental crust. J Geophys Res 91:5963–5983
Irvine TN, Baragar WRA (1971) A guide to the chemical classification of the common volcanic rocks. Can J Earth Sci 8:523–548
Kohl B (1980) The lower Pliocene benthic foraminifers from the Isthmus of Tehuantepec, Mexico. Ph D Dissertation, Tulane University, New Orleans, Louisiana, pp 1–475
LeBas MJ, LeMaitre RW, Streckeisen A, Zanettin B (1986) A chemical classification of volcanic rocks based on the total alkali-silica diagram. J Petrol 27:745–750
Lopez-Infanzon M (1991) Petrologic study of the volcanic rocks in the Sierra de Chiconquiaco — Palma Sola area, central Veracruz, Mexico. MS Thesis, Tulane University, New Orleans, Louisiana, pp 1–140
Lopez-Infanzon M, Nelson SA (1990) Geology and K-Ar dating of the Sierra de Chiconquiaco-Palma Sola volcanics, Central Veracruz, Mexico. Geol Soc Am Abs Progs 22:67
Luhr JF, Allan JF, Carmichael ISE, Nelson SA, Hasenaka T (1989) Primitive calc-alkaline and alkaline rock types from the Western Mexican Volcanic Belt. J Geophys Res 94:4515–4530
Moore GW, del Castillo L (1974) Tectonic evolution of the southern Gulf of Mexico. Geol Soc Am Bull 85:607–618
Moziño J (1870) Informe sobre la erupción del Volcán de San Martín Tuxtla (Veracruz) ocurrida el año de 1793. Bol Soc Geograf Estad Repúb Mexicana II:62–72
Nelson SA, Gonzalez-Caver E, Kyser TK (1991) Constraints on the origin of Late Miocene to Recent alkaline and calc-alkaline magmas from the Tuxtla Volcanic Field, Veracruz, Mexico. Geol Soc Am Abst Prog 23:A333
Nixon GT (1982) The relationship between Quaternary volcanism in central Mexico and the seismicity and structure of subducted oceanic lithosphere. Geol Soc Am Bull 93:514–523
Pichler H, Weyl R (1976) Quaternary alkaline volcanic rocks in eastern Mexico and Central America. Munster Forsch Geol Palant 38/39:159–178
Ríos-MacBeth F (1952) Estudio geológico de la región de los Tuxtlas. Bol Asoc Mex Geól Petrol 4:324–376
Robin C (1976) Présence simultanée de magmatismes de significations tectoniques opposées dans l'Est du Mexique. Bull Soc Geol France 18:1637–1645
Robin C, Tournon J (1978) Spatial relations of andesitic and alkaline provinces in Mexico and Central America. Can J Earth Sci 15:1633–1641
Thorpe RS (1977) Tectonic significance of alkaline volcanism in eastern Mexico. Tectonophysics 40:T19-T26
Verma SP, Nelson SA (1989) Isotopic and trace element constraints on the origin and evolution of alkaline and calc-alkaline magmas in the northwestern Mexican Volcanic Belt. J Geophys Res 94:4531–4544
Williams H, Heizer RF (1965) Sources of rocks used in Olmec monuments. Contrib Univ Calif Arch Res Facility 1:1–39
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Nelson, S.A., Gonzalez-Caver, E. Geology and K-Ar dating of the Tuxtla Volcanic Field, Veracruz, Mexico. Bull Volcanol 55, 85–96 (1992). https://doi.org/10.1007/BF00301122
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DOI: https://doi.org/10.1007/BF00301122