The rise and fate of a long-lived deep crustal 'hot zone' beneath the neogene-quaternary Cordillera de San Buenaventura in the Southern Puna Plateau (NW Argentina)

Arc magmatism plays a key-role in the growth and differentiation of continental crust. In particular, the prolonged magmatic flux events control the genesis of deep crustal hot zones where magma accumulation and fractionation favour the continental arc crust evolution and geochemical stratification. In this view long-lived magmatic systems located in arc domains, with their erupted products spanning from basalts to rhyolites are formidable archive for the understanding the evolution of transcrustal magmatic plumbing systems and the construction of a stratified continental crust. This study focuses on the long-lived (ca. 9 Ma) Miocene-Holocene Cordillera de San Buenaventura volcanic system in the Southern Puna Plateau (NW Argentina), a unique natural laboratory where exploring the building up of MASH-zones (or deep crustal 'hot zones') and related sustained volcanism. Synthesis of new and published data, together with new thermobarometry and fractional crystallization modelling, indicates a cyclic scenario with mantle melts undergoing fractional crystallization dominated incipient and waning stages alternate to major mafic magma recharge events during the building up phase of the MASH-zone. This magmatic scenario is also discussed in the light of the coeval geodynamic framework dominated by the subduction of the Nazca plate and the eastward migration of the frontal arc magmatism.

Automated summary

Arc magmatism plays a crucial role in the growth and differentiation of continental crust. This study focuses on the long-lived Cordillera de San Buenaventura volcanic system in NW Argentina to understand the evolution of transcrustal magmatic plumbing systems and the construction of a stratified continental crust. The study reveals a cyclic scenario with mantle melts undergoing fractional crystallization and mafic magma recharge events during the formation of the deep crustal 'hot zones'. The study also considers the geodynamic framework dominated by subduction and arc magmatism migration.