Integration of the zircon U-Pb ages available on the Toquepala Group, La Caldera batholith (s.l.), and porphyry Cu systems, in combination with geochemical data, unravels the evolution of the magmatic arc of southernmost Peru during the Late Cretaceous and Early Paleogene. Arc magmatic production increased starting ~90 Ma, and culminated between ~74 and ~62 Ma through a flare-up characterized by large plutonic and volcanic
(especially ignimbritic) volumes. This long process resulted in the thickening of the arc crust, to a state of overthickening that triggered its extensional collapse, starting diachronously 61–59 Ma, during which giant porphyry Cu systems were emplaced
between ~60 and ~53 Ma. Our empirical reconstruction of this protracted evolution provides simple guides for exploration of giant porphyry Cu deposits in southern Peru, as well as a magmatotectonic theoretical framework

Acosta Ale, Jorge Gilberto

Marchena Campos, Alonso Arturo

Martínez Valladares, William

Paquette, Jean-Louis

Sempere, Thierry

English

Repositorio Institucional INGEMMET

XII CONGRESO INTERNACIONAL DE PROSPECTORES Y EXPLORADORES64   ___________________________________________________________________________________________________________________    ____________________________________________________________________________________________________________________  Unraveling the evolution of southernmost Peru between 100 and 50 Ma through U-Pb geochronology of the Toquepala Group:  Implications for exploration of large porphyry copper deposits  Thierry P.A. Sempere1, Jean-Louis Paquette2, William Martínez3,  Alonso A. Marchena3, & Jorge Acosta3  1 Gerencia Regional de Exploraciones, ANDES C&P, Lima, Perú (thierrysempere@icloud.com) 2 Université Clermont Auvergne, CNRS, Laboratoire Magmas et Volcans, 63178 Aubière, Francia 3 Instituto Geológico, Minero y Metalúrgico (INGEMMET), Lima, Perú  ____________________________________________________________________________________________________________________  1. Abstract / Resumen Integration of the zircon U-Pb ages available on the Toquepala Group, La Caldera batholith (s.l.), and porphyry Cu systems, in combination with geochemical data, unravels the evolution of the magmatic arc of southernmost Peru during the Late Cretaceous and Early Paleogene. Arc magmatic production increased starting ~90 Ma, and culminated between ~74 and ~62 Ma through a flare-up characterized by large plutonic and volcanic (especially ignimbritic) volumes. This long process resulted in the thickening of the arc crust, to a state of overthickening that triggered its extensional collapse, starting diachronously 61–59 Ma, during which giant porphyry Cu systems were emplaced between ~60 and ~53 Ma. Our empirical reconstruction of this protracted evolution provides simple guides for exploration of giant porphyry Cu deposits in southern Peru, as well as a magmato-tectonic theoretical framework. Aclarando la evolución del extremo sur del Perú entre 100 y 50 Ma mediante la geocronología U-Pb del Grupo Toquepala: Implicancias para la exploración por grandes pórfidos de cobre. La integración de las edades U-Pb en zircones disponibles sobre el Grupo Toquepala, batolito de La Caldera (s.l.), y pórfidos de cobre permite aclarar la evolución magmática del arco sur-peruano durante el Cretácico superior y Paleógeno inferior, en combinación con datos geoquímicos. A partir de ~90 Ma la actividad magmática fue creciendo y culminó entre ~74 y 62 Ma por una llamarada (flare-up) caracterizada por importantes volúmenes tanto plutónicos como volcánicos (y especialmente ignimbríticos). Este largo proceso resultó en el engrosamiento de la corteza del arco, a tal punto que ésta terminó por sufrir un colapso extensional a partir de 61–59 Ma, durante el cual se emplazaron sistemas porfídicos, incluyendo pórfidos gigantes de cobre, entre ~60 y ~53 Ma. Nuestra reconstrucción empírica de esta evolución proporciona una guía simple para la exploración minera, además de un marco teórico de índole magmato-tectónica.  2. Introduction   World-class porphyry copper deposits in southernmost Peru (Cuajone, Quellaveco, Toquepala; = CQT hereafter) are related to porphyry intrusions emplaced in a thick succession of volcanic and volcanodetritic strata, referred to as the Toquepala Group (Concha & Valle, 1999; Mattos & Valle, 1999; Martínez & Cervantes, 2003; Acosta, 2006; Martínez et al., 2017). In contrast with the copper deposits, relatively little is known about the geochronology of the Toquepala Group, and this work attempts to fill this gap. Here we outline a chronology based on zircon U-Pb ages that illuminates the magmatic evolution of southernmost Peru and shows that the porphyry copper deposits were emplaced during the final stage of this evolution, a finding that has crucial implications for mining exploration. We use hereafter ‘zUPb’ as an abbreviation for the locution ‘zircon U-Pb’.  RESÚMENES EXTENDIDOS DE CHARLAS TÉCNICAS65RECURSOS MINERALES PARA UN FUTURO SOSTENIBLE   3. Stratigraphy of the Toquepala Group   The >2 km-thick Toquepala Group is known south of 16.4°S and east of 71.5°W. It generally overlies sedimentary strata of Jurassic to Early Cretaceous age, and is overlain by the forearc sedimentary deposits of the Moquegua Group, the base of which is, at least locally, older than 45 Ma. Martínez & Zuloaga (2000) updated the stratigraphy of the Toquepala Group in the Moquegua area and divided it into 4 formations, namely the Huaracane, Inogoya, Paralaque and Quellaveco formations (from base to top). Zircon U-Pb dating of 3 of these units (Simmons, 2013; Fig. 1) however resulted in discrepancies with this stratigraphy, suggesting that the units may have been misidentified, at least in part, during sampling. For instance, samples reportedly from the oldest Huaracane Formation yielded the oldest and youngest ages in Simmons’ (2013) zUPb age dataset: 90.3 ± 0.8 and 68.3 ± 0.7 Ma, respectively. Only one sample assigned to the Paralaque Formation was dated, to 71.4 ± 0.7 Ma, but this age falls in the range of ages obtained by Simmons (2013) reportedly from the Quellaveco Formation; these ages allow to define 4 major eruptions, at 73.8 ± 0.8 Ma (n=1), 72.9 ± 0.6 Ma (n=2), 71.3 ± 0.3 Ma (n=5), and 69.8 ± 0.3 Ma (n=4).  Given these discrepancies, we do not refer hereafter to the stratigraphy and focus instead on absolute zUPb ages (Fig. 2).   Figure 1. Location of the zUPb ages obtained on the Toquepala Group and related units. Circles indicate dated ignimbrites; curved arrows indicate ages on detrital zircons. Red symbols plot ages obtained by Paquette & Sempere (unpublished). The other ages (mainly by Simmons, 2013) are referenced in the figure.  3. Late Cretaceous – Early Paleogene zircon U-Pb age spectrum  The oldest zUPb age obtained so far on the Toquepala Group is from a laminated ignimbrite intercalated in andesite flows ~34 km NE of Ilo, which yielded a late Cenomanian age (~94.1 Ma; Paquette & Sempere, unpublished). This ignimbrite occurs ~1 km above the base of a very thick volcanic succession mapped as the Toquepala Group, which overlies volcano-sedimentary strata that yielded Callovian ammonites (Bellido & Guevara, 1963). The youngest age, ~63.4 Ma (Danian), is from a deformed ignimbrite sampled ~34 km NNE of the city of Tacna (Paquette & Sempere, unpublished). Figure 2 displays most of the available zUPb ages concerning southernmost Peru: porphyry and plutonic rocks from the CQT deposits and area, and ignimbrites from the Toquepala Group (Fig. 1). A RESÚMENES EXTENDIDOS DE CHARLAS TÉCNICASXII CONGRESO INTERNACIONAL DE PROSPECTORES Y EXPLORADORES66   clear continuity of zUPb ages is observed between the main ignimbrite field, the dated plutons in the CQT area, and the CQT porphyry systems, as well as the known range of zUPb ages obtained on the La Caldera batholith (sensu lato, i.e. from the Arequipa region to the border with Chile; Mukasa, 1986; Demouy et al., 2012; Noury, 2014; Paquette & Sempere, unpublished). In addition, porphyry Cu systems in the Arequipa area (where the Toquepala Group is unknown; Núñez et al., 2000) intrude the La Caldera batholith (and, tangentially, the Precambrian basement) but have only slightly older ages (~60-59 Ma; Mukasa, 1986). The continuous age distribution observed in Fig. 2 indicates that porphyry emplacements in the late Paleocene and earliest Eocene occured near the end of one single protracted evolution that had started in the mid-Cretaceous or even earlier.   Figure 2. Spectrum of zUPb ages relative to the area shown in Figure 1, evidencing the time continuity between the overall evolution of the magmatic arc and the giant porphyry systems. Most age data are derived from Sillitoe & Mortensen (2010), Simmons (2013), Simmons et al. (2013), and Paquette & Sempere (unpublished). The zUPb age range of the La Caldera batholith in the Arequipa region is also shown (Mukasa, 1986; Demouy et al., 2012).  4. Magmatic (over)thickening of the arc crust  The La Caldera arc was established at ~90 Ma along what is now the homonymous horst, and underwent a magmatic growth reflected by increasingly voluminous plutonic masses (Demouy et al., 2012). This growth culminated between ~74 and 62 Ma by a magmatic flare-up involving very large plutonic and volcanic volumes, with thick ignimbrites erupted every 1–2 Myr (Fig. 2; Simmons, 2013; Noury, 2014; this work).  The available geochemical data strongly suggest that this growth resulted in an anomalous thickening of the arc crust (Martínez et al., 2017, 2018; Marchena, 2019; Marchena et al., 2019): the “precursor” plutons shortly predating the porphyry systems (Fig. 2) display indeed high Sr/Y ratios reflecting that the coeval crust was overthickened at that time. This signature commonly results from high Sr implying the inhibition of plagioclase crystallization by high lithostatic pressure at depths >50 km, and/or from low Y reflecting that the lower crust included stable garnet and was thus anomalously thick.  5. Extensional collapse and coeval emplacement of porphyry systems  Confirming a now classical concept, the overthickened arc crust ended up undergoing a major extensional collapse, which resulted in the uplift and exhumation of specific areas. The zUPb dataset reveals that the collapse was initiated diachronously between 61 Ma (Arequipa longitude) and 59 Ma (Quellaveco longitude). In agreement, nearly all faults observed in the area of interest are normal, and the most important have km-size offsets that define large blocks. In particular, the La RESÚMENES EXTENDIDOS DE CHARLAS TÉCNICAS67RECURSOS MINERALES PARA UN FUTURO SOSTENIBLE   Caldera horst was structured and exhumed during the collapse. Thermochronological ages in the area (Noury, 2014; Noury et al., 2017) are compatible with a collapse-driven exhumation and cooling during the ~60-55 Ma interval. Hydrothermal muscovite crystallized in a normal fault zone 40 km NNE of Tacna yielded an 40Ar-39Ar age of 61.4 ± 0.3 Ma (Sempere et al., 2018). Because the porphyry systems that host the giant Cu deposits of southernmost Peru yielded zUPb ages between ~60 and ~53 Ma (Mukasa, 1986; Sillitoe & Mortensen, 2010; Simmons et al., 2013; Fig. 2), our work implies that they were emplaced during the extensional collapse.  6. Conclusions  The world-class porphyry Cu systems of southern Peru were emplaced during a short (<7 Myr) time span that coincided with the extensional collapse of the previously overthickened arc crust.  This empirical finding provides a simple guide for exploration, and also suggests a theoretical framework that stresses the importance of tectonic phenomena driven by arc magmatism.   Acknowledgments We warmly thank for their collaboration many colleagues and students too numerous to be cited here. Our study includes zUPb ages obtained at the Université Clermont Auvergne, France (Paquette & Sempere, unpublished), which will be published at a later stage of this research.   References Acosta, J. 2006. Características metalogenéticas de los yacimientos asociados a los arcos magmáticos mesozoicos y cenozoicos del sur del Perú (latitudes 16°00’S-18°30’S). INGEMMET, 32 p.  Bellido, E., Guevara, C. 1963. Geología de los cuadrángulos de Punta de Bombón y Clemesí. Boletín de la Carta Geológica Nacional, v. 5, 102 p. Concha, O., Valle, J. 1999. Prospección, exploración y desarrollo del yacimiento de Cuajone. ProExplo 1999, p. 117–143. Demouy, S., Paquette, J.-L., Saint-Blanquat, M. de, Benoit, M., Belousova, E.A., O’Reilly, S.Y., García, F., Tejada, L.C., Gallegos, R., Sempere, T. 2012. Spatial and temporal evolution of Liassic to Paleocene arc activity in southern Peru unraveled by zircon U–Pb and Hf in-situ data on plutonic rocks. Lithos, v. 155, p. 183–200. Marchena, A. 2019. Caracterización petrográfica e interpretación litogeoquímica del magmatismo de los proyectos Tía María–La Tapada, Los Calatos y Chipispaya (Arequipa-Moquegua-Tacna). Tesis de grado, Universidad Nacional de Ingeniería, 279 p.  Marchena, A., Martínez, W., Otero, J. 2019. Trazadores litogeoquímicos de fertilidad del magmatismo vinculado a pórfidos de Cu (-Mo, -Au) en el sur del Perú, del Jurásico al Mioceno. ProExplo 2019, 4 p. Martínez, W., Zuloaga, A. 2000. Memoria explicativa de la geología del cuadrángulo de Moquegua. INGEMMET, Boletines, serie A, 12 p.  Martínez, W., Cervantes, J. 2003. Rocas ígneas en el sur del Perú: Nuevos datos geocronométricos, geoquímicos y estructurales entre los paralelos 16° y 18°30′S. INGEMMET, Boletines, serie D, v. 26, 140 p. Martínez, W., Marchena, A., Otero, J., Cervantes, J., León, W. 2017. Geología y controles tectono-magmáticos de los sistemas porfiríticos en el arco magmático occidental del Sur del Perú. INGEMMET, Boletines, serie D, 112 p. Martínez, W., Marchena, A., Otero, J., Cervantes, J. 2018. Tectonomagmatismo y fertilidad de los depósitos porfiríticos del Jurásico al Neógeno, sur de Perú. XIX Congreso Peruano de Geología, Lima, 4 p. Mattos, R., Valle, J. 1999. Exploración, geología y desarrollo del yacimiento Toquepala. ProExplo 1999, p. 101–116. Mukasa, S.B. 1986. Zircon U-Pb ages of super-units in the Coastal Batholith, Peru: Implications for magmatic and tectonic processes. Geological Society of America Bulletin, v. 97, p. 241–254. Noury, M. 2014. Evolution géologique de l’avant-arc sud-péruvien : apports des données géo-thermo-chronologiques. PhD dissertation, Université de Grenoble, 341 p. Noury, M., Philippon, M., Bernet, M., Paquette, J.-L., Sempere, T. 2017. Geological record of flat slab–induced extension in the southern Peruvian forearc. Geology, doi:10.1130/G38990.1 . Núñez, F., Mollepaza, S., Salas, P. 2000. Características metalogenéticas del depósito porfirítico Cerro Verde. X Congreso Peruano de Geología, Lima, p. 1217–1230. Sempere, T.P.A., Fornari, M., Acosta, J., Pino, A., Flores, A., Jacay, J., Bedoya, C. 2018. Nuevas edades 40Ar-39Ar y K-Ar en el sur del Perú. XIX Congreso Peruano de Geología, Lima, 4 p. Sillitoe, R.H., Mortensen, J.K. 2010. Longevity of porphyry copper formation at Quellaveco, Peru. Economic Geology, v. 105, p. 1157–1162. Simmons, A.T. 2013. Magmatic and hydrothermal stratigraphy of Paleocene and Eocene porphyry Cu-Mo deposits in southern Peru. PhD dissertation, The University of British Columbia at Vancouver, 346 p. Simmons, A.T., Tosdal, R.M., Wooden, J.L., Mattos, R., Concha, O., McCracken, S., Beale, T. 2013. Punctuated magmatism associated with porphyry Cu-Mo formation in the Paleocene to Eocene of southern Peru. Economic Geology, v. 108, p. 625–639. RESÚMENES EXTENDIDOS DE CHARLAS TÉCNICAS

Unraveling the evolution of southernmost Peru between 100 and 50 Ma through U-Pb geochronology of the Toquepala Group: Implications for exploration of large porphyry copper deposits

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Unraveling the evolution of southernmost Peru between 100 and 50 Ma through U-Pb geochronology of the Toquepala Group: Implications for exploration of large porphyry copper deposits

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