Late Cenozoic rates of magmatic activity in the Central Andes and their relationships to continental crust formation and thickening

Abstract Coupled zircon U-Pb age, trace-element, and Lu-Hf isotope analyses from central Sierra Nevada (eastern California, USA) metavolcanic strata reveal the expression of three Mesozoic arc flare-ups in the volcanic record over ∼150 m.y. of magmatic activity. Zircon εHf(i) values vary up to 20 epsilon units within individual samples and coeval sample populations but show no clear links with other geochemical indices, requiring both mixing and fractionation for arc magma genesis. Zircon compositions show repeated temporal trends across flare-ups: Hf isotopes spanning evolved to juvenile values converge to more juvenile compositions, middle rare earth element (MREE) depletion and heavy REE slopes increase during flare-up main phases, and highly variable U/Yb values converge to low values as flare-ups conclude. Despite pervasive contamination, juvenile source magmas dominate magmas erupted throughout the entirety of high-magma-addition episodes. Arc flare-ups thus represent ∼30 m.y. of increased mantle magma input that represents significant continental crust formation in Cordilleran arcs.

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INFLUENCE OF PULSED MAGMATIC ACTIVITY, LATENT HEAT, AND PARTIAL MELTING ON THE STRENGTH OF THE CONTINENTAL CRUST

10.1130/abs/2020am-358401 ◽

2020 ◽

Author(s):

Aleksi Rantanen ◽

◽

David Whipp ◽

Jussi S. Heinonen ◽

Lars Kaislaniemi ◽

...

Keyword(s):

Partial Melting ◽

Continental Crust ◽

Latent Heat ◽

Magmatic Activity

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Plate Coupling Mechanism of the Central Andes Subduction: Insight from Gravity Model

Journal of Geodetic Science ◽

10.1515/jogs-2019-0002 ◽

2019 ◽

Vol 9 (1) ◽

pp. 13-21

Author(s):

Rezene Mahatsente

Keyword(s):

Subduction Zone ◽

Continental Crust ◽

Gravity Model ◽

Central Andes ◽

High Density ◽

Seismic Gap ◽

Coupling Mechanism ◽

Crust And Upper Mantle ◽

Velocity Models ◽

Plate Coupling

Abstract The Central Andes experienced major earthquake (Mw =8.2) in April 2014 in a region where the giant 1877 earthquake (Mw=8.8) occurred. The 2014 Iquique earthquake did not break the entire seismic gap zones as previously predicted. Geodetic and seismological observations indicate a highly coupled plate interface. To assess the locking mechanism of plate interfaces beneath Central Andes, a 2.5-D gravity model of the crust and upper mantle structure of the central segment of the subduction zone was developed based on terrestrial and satellite gravity data from the LAGEOS, GRACE and GOCE satellite missions. The densities and major structures of the gravity model are constrained by velocity models from receiver function and seismic tomography. The gravity model defined details of crustal and slab structure necessary to understand the cause of megathrust asperity generation. The densities of the upper and lower crust in the fore-arc (2970 – 3000 kg m−3) are much higher than the average density of continental crust. The high density bodies are interpreted as plutonic or ophiolitic structures emplaced onto continental crust. The plutonic or ophiolitic structures may be exerting pressure on the Nazca slab and lock the plate interfaces beneath the Central Andes subduction zone. Thus, normal pressure exerted by high density fore-arc structures and buoyancy force may control plate coupling in the Central Andes. However, this interpretation does not exclude other possible factors controlling plate coupling in the Central Andes. Seafloor roughness and variations in pore-fluid pressure in sediments along subduction channel can affect plate coupling and asperity generation.

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Constraining the tectonic setting of continental crust formation from coupled in situ Rb-Sr dating and Pb isotopic analysis of detrital, single K-feldspar grains

10.7185/gold2021.5245 ◽

2021 ◽

Author(s):

Dan Bevan ◽

Christopher Coath ◽

Jamie Lewis ◽

Daniel Stubbs ◽

Joel Rodney ◽

...

Keyword(s):

Continental Crust ◽

Tectonic Setting ◽

Isotopic Analysis ◽

Crust Formation

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Tectonic settings of continental crust formation: Insights from Pb isotopes in feldspar inclusions in zircon

Geology ◽

10.1130/g38117.1 ◽

2016 ◽

Vol 44 (10) ◽

pp. 819-822 ◽

Cited By ~ 11

Author(s):

Hélène Delavault ◽

Bruno Dhuime ◽

Chris J. Hawkesworth ◽

Peter A. Cawood ◽

Horst Marschall ◽

...

Keyword(s):

Continental Crust ◽

Pb Isotopes ◽

Crust Formation ◽

Tectonic Settings

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Global factors of lead-zinc ore formation

Moscow University Bulletin. Series 4. Geology ◽

10.33623/0579-9406-2019-4-3-10 ◽

2019 ◽

pp. 3-10

Author(s):

A. L. Dergachev

Keyword(s):

Continental Crust ◽

Island Arcs ◽

Geological Time ◽

Crust Formation ◽

Ore Formation ◽

Global Factor ◽

Lead And Zinc ◽

Lead Zinc ◽

Cyclic Changes

Tectonic evolution of the Earth is a principle global factor responsible for uneven distribution of lead and zinc reserves in geological time. Cyclic changes in productivity of lead-zinc ore-formation processes resulted from periodical amalgamation of most blocks of continental crust, formation, stabilization and final break-up of supercontinents. Many features of age spectrums of lead and zinc reserves are caused by gradual increase of volume of continental crust resulting from accretion of island arcs to ancient cratons, widening of distribution of ensialic environments of ore-formation and increasing role of continental crust in magmatic processes.

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