Structural Variation Along the Southern Hikurangi Subduction Zone, Aotearoa New Zealand, From Seismic Reflection and Retro‐Deformation Analysis

The southern Hikurangi subduction zone exhibits significant along‐strike variation in convergence rate and obliquity, sediment thickness and, uniquely, the increasing proximity of southern Hikurangi to, and impingement on, the incoming continental Chatham Rise, an ancient Gondwana accretionary compl...

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Bibliographic Details
Published in:Tectonics (Washington, D.C.) D.C.), 2024-07, Vol.43 (7), p.n/a
Main Authors: Stevens, D. E., McNeill, L. C., Henstock, T. J., Barnes, P. M., Crutchley, G., Bangs, N., Henrys, S., Avendonk, H. J. A.
Format: Article
Language:English
Subjects:
Accretion
Bathymetry
Convergence
Deformation
Earthquakes
Fault lines
faulting
Hikurangi
History
Impingement
New Zealand
Obliquity
Ocean floor
Plate convergence
Plate motion
Plate tectonics
Plates
Reflection
Rocks
Seismic activity
seismic reflection
Seismic reflection profiles
structure
Subduction
Subduction zones
Tectonic processes
Tectonics
Tsunami hazard
Weather hazards
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Summary:The southern Hikurangi subduction zone exhibits significant along‐strike variation in convergence rate and obliquity, sediment thickness and, uniquely, the increasing proximity of southern Hikurangi to, and impingement on, the incoming continental Chatham Rise, an ancient Gondwana accretionary complex. There are corresponding changes in the morphology and structure of the Hikurangi accretionary prism. We combine widely spaced multichannel seismic reflection profiles with high resolution bathymetry and previous interpretations to characterize the structure and the history of the accretionary prism since 2 Ma. The southern Hikurangi margin can be divided into three segments. A northeastern segment (A) characterized by a moderately wide (∼70 km), low taper (∼5°) prism recording uninhibited outward growth in the last ∼1 Myr. Deformation resolvable in seismic reflection data accounts for ∼20 % of plate convergence, comparable with the central Hikurangi margin further North. A central segment (B) characterized by a narrow (∼30 km), moderate taper (∼8°) prism, with earlier (∼2‐∼1 Ma) shortening than segment A. Outward prism growth ceased coincidentally with development of major strike‐slip faults in the prism interior, reduced margin‐normal convergence rate, and the onset of impingement on the incoming Chatham Rise to the south. A southwestern segment (C) marks the approximate southern termination of subduction but widens to ∼50 km due to rapid outward migration of the deformation front via fault reactivation within the now‐underthrusting corner of the Chatham Rise. Segment C exhibits minimal shortening as margin‐normal subduction velocity decreases and plate motion is increasingly taken up by interior thrusts and strike‐slip faults. Plain Language Summary Between the North and South Islands of New Zealand, the interaction of the Pacific and Australian tectonic plates is highly complex. Beneath the North Island, the Pacific plate moves westward and slides underneath the Australian plate at the Hikurangi subduction zone, but through the South Island, the two plates slide past each other along the Alpine Fault. The transition between these two zones affects tectonic patterns to the north and south, and the resulting earthquake and tsunami hazard. Using marine seismic reflection technology, we have built detailed cross‐sectional images of the shallowest ∼20 km of the structure of the Earth beneath the seabed, which record the history of plate interactions. By studyi
ISSN:0278-7407
1944-9194
DOI:10.1029/2023TC008212