Abstract
Cerro Pinto is a Pleistocene rhyolite tuff ring-dome complex located in the eastern Trans-Mexican Volcanic Belt. The complex is composed of four tuff rings and four domes that were emplaced in three eruptive stages marked by changes in vent location and eruptive character. During Stage I, vent clearing produced a 1.5-km-diameter tuff ring that was then followed by emplacement of two domes of approximately 0.2 km3 each. With no apparent hiatus in activity, Stage II began with the explosive formation of a tuff ring ~2 km in diameter adjacent to and north of the earlier ring. Subsequent Stage II eruptions produced two smaller tuff rings within the northern tuff ring as well as a small dome that was mostly destroyed by explosions during its growth. Stage III involved the emplacement of a 0.04 km3 dome within the southern tuff ring. Cerro Pinto’s eruptive history includes sequences that follow simple rhyolite-dome models, in which a pyroclastic phase is followed immediately by effusive dome emplacement. Some aspects of the eruption, however, such as the explosive reactivation of the system and explosive dome destruction, are more complex. These events are commonly associated with polygenetic structures, such as stratovolcanoes or calderas, in which multiple pulses of magma initiate reactivation. A comparison of major and trace element geochemistry with nearby Pleistocene silicic centers does not show indication of any co-genetic relationship, suggesting that Cerro Pinto was produced by a small, isolated magma chamber. The compositional variation of the erupted material at Cerro Pinto is minimal, suggesting that there were not multiple pulses of magma responsible for the complex behavior of the volcano and that the volcanic system was formed in a short time period. The variety of eruptive style observed at Cerro Pinto reflects the influence of quickly exhaustible water sources on a short-lived eruption. The rising magma encountered small amounts of groundwater that initiated eruption phases. Once a critical magma:water ratio was exceeded, the eruptions became dry and sub-plinian to plinian. The primary characteristic of Cerro Pinto is the predominance of fall deposits, suggesting that the level at which rising magma encountered water was deep enough to allow substantial fragmentation after the water source was exhausted. Isolated rhyolite domes are rare and are not currently viewed as prominent volcanic hazards, but the evolution of Cerro Pinto demonstrates that individual domes may have complex cycles, and such complexity must be taken into account when making hazard risk assessments.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Abrams MJ, Siebe C (1994) Cerro Xalapaxco: an unusual tuff cone with multiple explosion craters, in central Mexico (Puebla). J Volcanol Geotherm Res 63:183–199
Austin-Erickson A (2007) Phreatomagmatic eruptions of rhyolitic magma: A case study of Tepexitl tuff ring, Serdan-Oriental basin, Mexico. MS thesis, Northern Arizona University, Flagstaff
Austin-Erickson A, Büttner R, Dellino P, Ort MH, Zimanowski B (2008) Phreatomagmatic explosions of rhyolite magma: experimental and field evidence. J Geophys Res 113:B11201. doi:10.1029/2008JB005731
Blake S, Fink JH (1987) The dynamics of magma withdrawal from a density stratified dyke. Earth Planet Sci Lett 85:516–524
Brooker MR, Houghton BF, Wilson CJN, Gamble JA (1993) Pyroclastic phases of a rhyolitic dome-building eruption: Puketarata tuff ring, Taupo Volcanic Zone, New Zealand. Bull Volcanol 55:395–406
Campos-Enriquez JO, Garduno Monroy VH (1987) The shallow structure of Los Humeros and Las Derrumbadas geothermal fields, Mexico. Geothermics 16:539–554
Carrasco-Núñez G, Ort M, Romero C (2007) Evolution and hydrological conditions of a maar volcano (Atexcac crater, Eastern Mexico). J Volcanol Geotherm Res 159:179–197
Carrasco-Núñez G, Riggs NR (2008) Polygenetic nature of a rhyolitic dome and implications for hazard assessment: Cerro Pizarro volcano, Mexico. J Volcanol Geotherm Res 171:307–315
Chough SK, Sohn YK (1990) Depositional mechanics and sequences of base surges, Songaksan tuff ring, Cheju Island, Korea. Sedimentology 37:1115–1135
Duffield WA, Richter DH, Priest SS (1995) Physical volcanology of silicic lava domes as exemplified by the Taylor Creek Rhyolite, Catron and Sierra Counties, New Mexico. US Geol Surv Map I-2399, scale 1:50,000
Ferriz H, Mahood G (1984) Eruprion rates and compositional trends at Los Humeros volcanic center, Puebla, Mexico. J Geophys Res 89:8511–8524. doi:10.1029/JB089iB10p08511
Fisher RV, Schmincke H-U (1984) Pyroclastic rocks. Springer-Verlag, Berlin
Garcia-Banda R (1984) Geology, geochemistry, and petrology of the Pizarro and Pinto domes and the Tepeyahualco flows related to the Los Humeros caldera complex, Puebla, Mexico. MSc thesis, McGill University, Montreal
Heiken GH, Wohletz K (1987) Tephra deposits associated with silicic domes and lava flows. Geol Soc Am Spec Pap 212:55–76
Hildreth W (2004) Volcanological perspectives on Long Valley, Mammoth Mountain, and Mono Craters: several contiguous but discrete systems. J Volcanol Geotherm Res 136:169–198
Hildreth W, Fierstein J (2000) Katmai volcanic cluster and the great eruption of 1912. Geol Soc Am Bull 112:1594–1620
Houghton BF, Wilson CJN, Fierstein J, Hildreth W (2004) Complex proximal deposition during the Plinian eruptions of 1912 at Novarupta, Alaska. Bull Volcanol 66:95–133
Lozano-Santa Cruz R, Verma SP, Girón P, Velasco F, Morán D, Viera F, Chávez G (1995) Calibración preliminar de fluorescencia de rayos-X para análisis cuantitativo de elementos mayores en rocas ígneas. Acta INAGEQ 1:203–208
Macias JL, Sheridan MF (1995) Products of the 1907 eruption of Shtyubel’ Volcano, Ksudach Caldera, Kamchatka, Russia. Geol Soc Am Bull 107:969–985
Miller CD (1985) Holocene eruptions at the Inyo volcanic chain, California: implications for possible eruptions in the Long Valley caldera. Geology 13:14–17
Ort M, Carrasco-Núñez G (2009) Lateral vent migration during phreatomagmatic and magmatic eruptions at Tecuitlapa maar, east-central Mexico. J Volcanol Geotherm Res 181:67–77
Reches Z, Fink JH (1988) The mechanism of intrusion of the Inyo dike, Long Valley Caldera, California. J Geophys Res 93:4321–4334. doi:10.1029/JB093iB05p04321
Riggs NR, Carrasco-Núñez G (2004) Evolution of a complex, isolated dome system, Cerro Pizarro, central México. Bull Volcanol 66:322–335
Sampson DE, Cameron KL (1987) The geochemistry of the Inyo volcanic chain: multiple magma systems in the Long Valley region, eastern California. J Geophys Res 92:10403–10421. doi:10.1029/JB092iB10p10403
Sheridan MF, Updike RG (1975) Sugarloaf Mountain Tephra—A Pleistocene rhyolitic deposit of base-surge origin in northern Arizona. Geol Soc Am Bull 86:571–581
Siebe C, Verma SP (1988) Major element geochemistry and tectonic setting of Las Derrumbadas rhyolitic domes, Puebla, Mexico. Chem Erde 48:177–189
Siebe C, Macías JL, Abrams M, Rodríguez S, Castro R, Delgado H (1995) Quaternary explosive volcanism and pyroclastic deposits in east central Mexico: implications for future hazards. Geol Soc Am Field Guide, pp 1–47
Siebert L, Carrasco-Nuñez G (2002) Late-Pleistocene to precolumbian behind-the-arc mafic volcanism in the eastern Mexican Volcanic Belt; implications for future hazards. J Volcanol Geotherm Res 115:179–205
Steiger RH, Jäger E (1977) Subcommission on geochronology: convention on the use of decay constants in geo- and cosmochronology. Earth Planet Sci Lett 36:359–362
Sun S, McDonough WF, (1989) Chemical and isotopic systematics of ocean basalt: Implications for mantle composition and processes. In: Saunders AD, Norry MJ (eds) Magmatism in ocean basins. Geol Soc London Spec Pub 42:313–345
Swanson SE, Naney MT, Westrich HR, Eichelberger JC (1989) Crystallization history of Obsidian Dome, Inyo Domes, California. Bull Volcanol 51:161–176
Taylor JR (1982) An introduction to error analysis: The study of uncertainties in physical measurements. Univ Sci Books, Mill Valley
White JDL, Houghton BF (2000) Surtseyan and related phreatomagmatic eruptions. In: Sigurdsson H, Houghton B, McNutt S, Rymer H, Stix J (eds) Encyclopedia of volcanoes. Academic, San Diego, pp 617–626
Yañez C, García S (1982) Exploración geotérmica de la region geotérmica Los Humeros-Las Derrumbadas, estados de Puebla y Veracruz. C.F.E. 96
Acknowledgements
This manuscript benefited greatly from reviews by J Fink, G Sottili, and H Delgado Granados. Additional comments were graciously provided by W Duffield. M Ketterer performed ICP-MS analyses, R Lozano ran the XRF, and L Peters (New Mexico Bureau of Mines and Mineral Resources) provided the 40Ar /39Ar dates. Financial assistance and XRF analyses were generously provided by Universidad Nacional Autónoma de México (UNAM); PAPIIT IN107907 and the Friday Lunch Clubbe of Northern Arizona University. We would also like to thank C Melendez, M Branney, G Aguirre, F Cedillo, M Ort, C Bonamici, and A Austin for fruitful discussions in the field.
Author information
Authors and Affiliations
Corresponding author
Additional information
Editorial responsibility: H. Delgado
Rights and permissions
About this article
Cite this article
Zimmer, B.W., Riggs, N.R. & Carrasco-Núñez, G. Evolution of tuff ring-dome complex: the case study of Cerro Pinto, eastern Trans-Mexican Volcanic Belt. Bull Volcanol 72, 1223–1240 (2010). https://doi.org/10.1007/s00445-010-0391-6
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00445-010-0391-6