Fore-arc basalt to boninite magmatism; characterizing the transition from decompression to fluid flux melting after subduction initiation

Daniel A Coulthard; Mark K Reagan; Renat Almeev; Julian A Pearce; Jeffrey Ryan; Tetsuya Sakuyama; J. W Shervais; Kenji Shimizu

doi:10.1130/abs/2017AM-305866

Abstract

Fore-arc basalt to boninite magmatism; characterizing the transition from decompression to fluid flux melting after subduction initiation

Daniel A Coulthard, Mark K Reagan, Renat Almeev, Julian A Pearce, Jeffrey Ryan, Tetsuya Sakuyama, J. W Shervais and Kenji Shimizu

Abstracts with programs - Geological Society of America, Vol.49(6)

Geological Society of America, 2017 annual meeting & exposition

2017

DOI: 10.1130/abs/2017AM-305866

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Abstract

International Ocean Discovery Program (IODP) Expedition 352 drilled the Bonin fore-arc to sample the stratigraphic succession of lavas that erupted immediately after the Pacific plate began subducting during the Eocene. Here, we report major and trace element compositions of glasses encountered in Expedition 352 cores and use these data to discuss the evolution of sources and melting processes during the early evolution of the Bonin volcanic arc. Forearc basalt (FAB) is the oldest volcanic product of subduction initiation. Hole U1440B comprises a thin talus cover underlain by nearly equal 170 meters of FAB pillow lavas, sheet flows, and hyaloclastites, interlayered FAB-related dolerite and lavas, and dolerite. FAB trace element patterns strongly resemble those of mid-ocean ridge basalts (MORB), but FAB is distinguished from MORB by a stronger depletion in incompatible trace element concentrations. Low-Si Boninites (LSB), genetically related proto-arc rocks encountered as hyaloclastites and pillow lavas at sites U1439 and U1442, regionally overlie FAB, and are distinguished by more siliceous and magnesian major element compositions, enrichments in fluid mobile trace elements, and extreme depletions in rare-earth element concentrations. FAB is largely a product of decompression melting given its similarity to MORB. LSB and arc lavas have many similar geochemical traits that are often attributed to fluid-flux melting of the mantle. Discerning the origin and relative timing of this significant transition in sources and petrogenetic processes are primary goals of this research. A large majority of FAB samples lack a distinct fluid mobile element enrichment. This observation applies to both aqueous fluid soluble trace elements such as Rb, K, and Sr in addition to sediment-melt mobile elements such as Ba and Th. Thus, FAB appears to have been generated as a result of rapid slab-rollback and upwelling of a depleted mantle source. Trace element ratios for LSB plot along trends that imply mixing between FAB and an endmember LSB composition, suggesting that the flux-melting source developed concurrently with continued decompression melting.

Pacific Ocean

andesites

basalts

boninite

chemical composition

Expedition 352

Igneous and metamorphic petrology

igneous rocks

International Ocean Discovery Program

IODP Site U1439

IODP Site U1440

IODP Site U1442

magmatism

North Pacific

Northwest Pacific

plate tectonics

subduction

volcanic rocks

West Pacific

Details

Title: Subtitle: Fore-arc basalt to boninite magmatism; characterizing the transition from decompression to fluid flux melting after subduction initiation
Creators: Daniel A Coulthard - University of Iowa
Mark K Reagan
Renat Almeev
Julian A Pearce
Jeffrey Ryan
Tetsuya Sakuyama
J. W Shervais
Kenji Shimizu
Resource Type: Abstract
Publication Details: Abstracts with programs - Geological Society of America, Vol.49(6)
Conference: Geological Society of America, 2017 annual meeting & exposition
Publisher: Geological Society of America (GSA)
DOI: 10.1130/abs/2017AM-305866
ISSN: 0016-7592
Alternative title: Geological Society of America, 2017 annual meeting & exposition
Language: English
Date published: 2017
Academic Unit: Earth and Environmental Sciences
Record Identifier: 9984229965502771

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