Abstract

The aseismic Cocos and Carnegie Ridges, two prominent bathymetric features in the eastern Pacific, record $20 Myr of interaction between the Gala pagos hotspot and the adjacent Gala pagos Spreading Center. Trace element data determined by inductively coupled plasma-mass spectrometry in >90 dredged seamount lavas are used to estimate melt generation conditions and mantle source compositions along the ridges. Lavas from seamount provinces on the Cocos Ridge are alkalic and more enriched in incompatible trace elements than any in the Gala pagos archipelago today. The seamount lavas are effectively modeled as small degree melts of a Gala pagos plume source. Their eruption immediately follows the failure of a rift zone at each seamount province's location. Thus the anomalously young alkalic lavas of the Cocos Ridge, including Cocos Island, are probably caused by post-abandonment volcanism following either a ridge jump or rift failure, and not the direct activity of the Gala pagos plume. The seamounts have plume-like signatures because they tap underlying mantle previously infused with Gala pagos plume material. Whereas plume heterogeneities appear to be long-lived, tectonic rearrangements of the ridge plate boundary may be the dominant factor in controlling regional eruptive behavior and compositional variations.