Plate Boundary Reorganization at a Large-offset, Rapidly Propagating Rift

R. N. Hey; P. D. Johnson; F. Martinez; J. Korenaga; M. L. Somers; Q. J. Huggett; T. P. LeBas; R. I. Rusby; D. F. Naar

doi:10.1038/378167a0

Plate Boundary Reorganization at a Large-offset, Rapidly Propagating Rift

R. N. Hey
, P. D. Johnson
, F. Martinez
, J. Korenaga
, M. L. Somers
, Q. J. Huggett
, T. P. LeBas
, R. I. Rusby
, D. F. Naar

College of Marine Science

Research output: Contribution to journal › Article › peer-review

Abstract

THE existence of rapidly spinning microplates along the southern East Pacific Rise has been documented by geophysical swath-mapping surveys ^1–6 , and their evolution has been successfully described by an edge-driven kinematic model ⁷ . But the mechanism by which such microplates originate remains unknown. Proposed mechanisms ^1–10 have generally involved rift propagation ¹¹ , possibly driven by hotspots or changes in direction of sea-floor spreading. Here we present geophysical data collected over the Earth's fastest spreading centre, the Pacific–Nazca ridge between the Easter and Juan Fernandez microplates (Fig. 1), which reveal a large-offset propagating rift presently reorganizing the plate boundary geometry. A recent episode of rapid 'duelling' propagation of the historically failing spreading centre in this system has created a 120 × 120 km overlap zone between dual active spreading centres, which may be the initial stage of formation of a new microplate.

Original language	American English
Journal	Nature
Volume	378
DOIs	https://doi.org/10.1038/378167a0
State	Published - Jan 1 1995

Disciplines

Life Sciences

Access to Document

10.1038/378167a0License: CC BY

https://doi.org/10.1038/378167a0

Cite this

@article{a80e6b246fd4480db0551582726bca9b,

title = "Plate Boundary Reorganization at a Large-offset, Rapidly Propagating Rift",

abstract = " THE existence of rapidly spinning microplates along the southern East Pacific Rise has been documented by geophysical swath-mapping surveys 1–6 , and their evolution has been successfully described by an edge-driven kinematic model 7 . But the mechanism by which such microplates originate remains unknown. Proposed mechanisms 1–10 have generally involved rift propagation 11 , possibly driven by hotspots or changes in direction of sea-floor spreading. Here we present geophysical data collected over the Earth's fastest spreading centre, the Pacific–Nazca ridge between the Easter and Juan Fernandez microplates (Fig. 1), which reveal a large-offset propagating rift presently reorganizing the plate boundary geometry. A recent episode of rapid 'duelling' propagation of the historically failing spreading centre in this system has created a 120 × 120 km overlap zone between dual active spreading centres, which may be the initial stage of formation of a new microplate.",

author = "Hey, \{R. N.\} and Johnson, \{P. D.\} and F. Martinez and J. Korenaga and Somers, \{M. L.\} and Huggett, \{Q. J.\} and LeBas, \{T. P.\} and Rusby, \{R. I.\} and Naar, \{D. F.\}",

year = "1995",

month = jan,

day = "1",

doi = "10.1038/378167a0",

language = "American English",

volume = "378",

journal = "Nature",

}

TY - JOUR

T1 - Plate Boundary Reorganization at a Large-offset, Rapidly Propagating Rift

AU - Hey, R. N.

AU - Johnson, P. D.

AU - Martinez, F.

AU - Korenaga, J.

AU - Somers, M. L.

AU - Huggett, Q. J.

AU - LeBas, T. P.

AU - Rusby, R. I.

AU - Naar, D. F.

PY - 1995/1/1

Y1 - 1995/1/1

N2 - THE existence of rapidly spinning microplates along the southern East Pacific Rise has been documented by geophysical swath-mapping surveys 1–6 , and their evolution has been successfully described by an edge-driven kinematic model 7 . But the mechanism by which such microplates originate remains unknown. Proposed mechanisms 1–10 have generally involved rift propagation 11 , possibly driven by hotspots or changes in direction of sea-floor spreading. Here we present geophysical data collected over the Earth's fastest spreading centre, the Pacific–Nazca ridge between the Easter and Juan Fernandez microplates (Fig. 1), which reveal a large-offset propagating rift presently reorganizing the plate boundary geometry. A recent episode of rapid 'duelling' propagation of the historically failing spreading centre in this system has created a 120 × 120 km overlap zone between dual active spreading centres, which may be the initial stage of formation of a new microplate.

AB - THE existence of rapidly spinning microplates along the southern East Pacific Rise has been documented by geophysical swath-mapping surveys 1–6 , and their evolution has been successfully described by an edge-driven kinematic model 7 . But the mechanism by which such microplates originate remains unknown. Proposed mechanisms 1–10 have generally involved rift propagation 11 , possibly driven by hotspots or changes in direction of sea-floor spreading. Here we present geophysical data collected over the Earth's fastest spreading centre, the Pacific–Nazca ridge between the Easter and Juan Fernandez microplates (Fig. 1), which reveal a large-offset propagating rift presently reorganizing the plate boundary geometry. A recent episode of rapid 'duelling' propagation of the historically failing spreading centre in this system has created a 120 × 120 km overlap zone between dual active spreading centres, which may be the initial stage of formation of a new microplate.

UR - https://digitalcommons.usf.edu/msc_facpub/2223

UR - https://doi.org/10.1038/378167a0

U2 - 10.1038/378167a0

DO - 10.1038/378167a0

M3 - Article

VL - 378

JO - Nature

JF - Nature

ER -

Plate Boundary Reorganization at a Large-offset, Rapidly Propagating Rift

Abstract

Disciplines

Access to Document

Other files and links

Cite this