Your search keyword '"Gu, Yu J."' showing total 2 results

1. Mesozoic intraoceanic subduction shaped the lower mantle beneath the East Pacific Rise.

Author

Jingchuan Wang, Lekić, Vedran, Schmerr, Nicholas C., Gu, Yu J., Yi Guo, and Rongzhi Lin

Subjects

*SLABS (Structural geology), *TOMOGRAPHY, *SURFACE of the earth, *SUBDUCTION, *CLUSTER analysis (Statistics), *MID-ocean ridges

Abstract

The Pacific large low-shear-velocity province (LLSVP), as revealed by cluster analysis of global tomographic models, hosts multiple internal anomalies, including a notable gap (~20° wide) between the central and eastern Pacific. The cause of the structural gap remains unconstrained. Directly above this structural gap, we identify an anomalously thick mantle transition zone east of the East Pacific Rise, the fastest-spreading ocean ridge in the world, using a dense set of SS precursors. The area of the thickened transition zone exhibits faster-than-average velocities according to recent tomographic images, suggesting perturbed postolivine phase boundaries shifting in response to lowered temperatures. We attribute this observation to episodes of Mesozoic-aged (250 to 120 million years ago) intraoceanic subduction beneath the present-day Nazca Plate. The eastern portion of the Pacific LLSVP was separated by downwelling because of this ancient oceanic slab. Our discovery provides a unique perspective on linking deep Earth structures with surface subduction. [ABSTRACT FROM AUTHOR]

Published

2024

2. Mesozoic intraoceanic subduction shaped the lower mantle beneath the East Pacific Rise.

Author

Wang J, Lekić V, Schmerr NC, Gu YJ, Guo Y, and Lin R

Abstract

The Pacific large low-shear-velocity province (LLSVP), as revealed by cluster analysis of global tomographic models, hosts multiple internal anomalies, including a notable gap (~20° wide) between the central and eastern Pacific. The cause of the structural gap remains unconstrained. Directly above this structural gap, we identify an anomalously thick mantle transition zone east of the East Pacific Rise, the fastest-spreading ocean ridge in the world, using a dense set of SS precursors. The area of the thickened transition zone exhibits faster-than-average velocities according to recent tomographic images, suggesting perturbed postolivine phase boundaries shifting in response to lowered temperatures. We attribute this observation to episodes of Mesozoic-aged (250 to 120 million years ago) intraoceanic subduction beneath the present-day Nazca Plate. The eastern portion of the Pacific LLSVP was separated by downwelling because of this ancient oceanic slab. Our discovery provides a unique perspective on linking deep Earth structures with surface subduction.

Published

2024