Receiver function analysis reveals layered anisotropy in the crust and upper mantle beneath southern Peru and northern Bolivia

Receiver function analysis reveals layered anisotropy in the crust and upper mantle beneath southern Peru and northern Bolivia

Subduction systems play a key role in plate tectonics, but the deformation of the crust and uppermost mantle during continental subduction remains poorly understood. Observations of seismic anisotropy can provide constraints on dynamic processes in the crust and uppermost mantle in subduction system...

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Bibliographic Details
Published in:Tectonophysics Vol. 753; no. C; pp. 93 - 110
Main Authors: Bar, Neta, Long, Maureen D., Wagner, Lara S., Beck, Susan L., Zandt, George, Tavera, Hernando
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 20-02-2019
Elsevier BV
Elsevier
Subjects:
Andes
Anisotropy
Crustal deformation
Deformation
Depth
Dipping
Earth mantle
Function analysis
Interfaces
Magma
Mineralogy
Modelling
Multilayers
Northern Bolivia
Plate tectonics
Plates (tectonics)
Receiver function
Rheological properties
Rheology
S waves
Seismic Anisotropy
Seismographs
Seismometers
Southern Peru
Subduction
Subduction (geology)
Subduction zones
Surface water waves
Surface waves
Tectonics
Tomography
Upper mantle
Bolivia
Peru
Crustal deformation
Southern Peru
Andes
Receiver function
Seismic Anisotropy
Northern Bolivia
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Summary:Subduction systems play a key role in plate tectonics, but the deformation of the crust and uppermost mantle during continental subduction remains poorly understood. Observations of seismic anisotropy can provide constraints on dynamic processes in the crust and uppermost mantle in subduction systems. The subduction zone beneath Peru and Bolivia, where the Nazca plate subducts beneath South America, represents a particularly interesting location to study subduction-related deformation, given the along-strike transition from flat to normally dipping subduction. In this study we constrain seismic anisotropy within and above the subducting slab (including the overriding plate) beneath Peru and Bolivia by examining azimuthal variations in radial and transverse component receiver functions. Because anisotropy-aware receiver function analysis has good lateral resolution and depth constraints, it is complementary to previous studies of anisotropy in this region using shear wave splitting or surface wave tomography. We examine data from long-running permanent stations NNA (near Lima, Peru) and LPAZ (near La Paz, Bolivia), and two dense lines of seismometers from the PULSE and CAUGHT deployments in Peru and Bolivia, respectively. The northern line overlies the Peru flat slab, while the southern line overlies the normally dipping slab beneath Bolivia. We applied harmonic decomposition modeling to constrain the presence, depth, and characteristics of dipping and/or anisotropic interfaces within the crust and upper mantle. We found evidence for varying multi-layer anisotropy, in some cases with dipping symmetry axes, underneath both regions. The presence of multiple layers of anisotropy with distinct geometries that change with depth suggests a highly complex deformation regime associated with subduction beneath the Andes. In particular, our identification of depth-dependent seismic anisotropy within the overlying plate crust implies a change in deformation geometry, dominant mineralogy, and/or rheology with depth, shedding light on the nature of deep crustal deformation during orogenesis. •Receiver function data constrains seismic anisotropy at depth in Peru and Bolivia.•Variable, multi-layered anisotropy is present in the crust and upper mantle.•Anisotropy changes with depth, reflecting changing deformation and/or mineralogy.•Pervasive deformation of the entire crustal column during orogenesis.
Bibliography:USDOE National Nuclear Security Administration (NNSA)
EAR-0943962; EAR-0907880; EAR-0944181; EAR-0908777; EAR-0943991; EAR-1261681
ISSN:0040-1951
1879-3266
DOI:10.1016/j.tecto.2019.01.007