Mechanical Implications of Creep and Partial Coupling on the World's Fastest Slipping Low-Angle Normal Fault in Southeastern Papua New Guinea

James Biemiller; Carolyn Boulton; Laura Wallace; Susan Ellis; Timothy Little; Marcel Mizera; Andre Niemeijer; Luc Lavier

doi:10.1029/2020JB020117

Mechanical Implications of Creep and Partial Coupling on the World's Fastest Slipping Low-Angle Normal Fault in Southeastern Papua New Guinea

James Biemiller^*, Carolyn Boulton, Laura Wallace, Susan Ellis, Timothy Little, Marcel Mizera, Andre Niemeijer, Luc Lavier

^*Corresponding author for this work

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

Abstract

We use densely spaced campaign GPS observations and laboratory friction experiments on fault rocks from one of the world's most rapidly slipping low-angle normal faults, the Mai'iu fault in Papua New Guinea, to investigate the nature of interseismic deformation on active low-angle normal faults. GPS velocities reveal 8.3 ± 1.2 mm/year of horizontal extension across the Mai'iu fault, and are fit well by dislocation models with shallow fault locking (above 2 km depth), or by deeper locking (from ~5–16 km depth) together with shallower creep. Laboratory friction experiments show that gouges from the shallowest portion of the fault zone are predominantly weak and velocity-strengthening, while fault rocks deformed at greater depths are stronger and velocity-weakening. Evaluating the geodetic and friction results together with geophysical and microstructural evidence for mixed-mode seismic and aseismic slip at depth, we find that the Mai'iu fault is most likely strongly locked at depths of ~5–16 km and creeping updip and downdip of this region. Our results suggest that the Mai'iu fault and other active low-angle normal faults can slip in large (M_w > 7) earthquakes despite near-surface interseismic creep on frictionally stable clay-rich gouges.

Original language	English
Article number	e2020JB020117
Number of pages	24
Journal	Journal of Geophysical Research: Solid Earth
Volume	125
Issue number	10
DOIs	https://doi.org/10.1029/2020JB020117
Publication status	Published - Oct 2020

Funding

We first and foremost thank the people of Milne Bay and Oro provinces in Papua New Guinea for their support and hospitality, without which the field‐based components would not have been possible. We thank Samuel Webber, Neville Palmer, and Rory Hart for field and technical support. We thank Samuel Webber, Jürgen Österle, Daniel Stockli, Kevin Norton, and Whitney Behr for helpful discussions. This study was supported by the US National Science Foundation grant EAR‐1524729 (L.W., L.L., J.B.) and graduate student fellowship program (J.B.), New Zealand Royal Society Marsden Fund grant VUW1310 (T.L., C.B., M.M., S.E.), European Research Council grant SEISMIC (335915) (A.N.), and the Dutch Research Council VIDI grant 854.12.011 (A.N.).

Keywords

GPS
low-angle normal fault
normal fault
rate-and-state friction
seismic stability
Woodlark Rift

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title = "Mechanical Implications of Creep and Partial Coupling on the World's Fastest Slipping Low-Angle Normal Fault in Southeastern Papua New Guinea",

abstract = "We use densely spaced campaign GPS observations and laboratory friction experiments on fault rocks from one of the world's most rapidly slipping low-angle normal faults, the Mai'iu fault in Papua New Guinea, to investigate the nature of interseismic deformation on active low-angle normal faults. GPS velocities reveal 8.3 ± 1.2 mm/year of horizontal extension across the Mai'iu fault, and are fit well by dislocation models with shallow fault locking (above 2 km depth), or by deeper locking (from ~5–16 km depth) together with shallower creep. Laboratory friction experiments show that gouges from the shallowest portion of the fault zone are predominantly weak and velocity-strengthening, while fault rocks deformed at greater depths are stronger and velocity-weakening. Evaluating the geodetic and friction results together with geophysical and microstructural evidence for mixed-mode seismic and aseismic slip at depth, we find that the Mai'iu fault is most likely strongly locked at depths of ~5–16 km and creeping updip and downdip of this region. Our results suggest that the Mai'iu fault and other active low-angle normal faults can slip in large (Mw > 7) earthquakes despite near-surface interseismic creep on frictionally stable clay-rich gouges.",

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author = "James Biemiller and Carolyn Boulton and Laura Wallace and Susan Ellis and Timothy Little and Marcel Mizera and Andre Niemeijer and Luc Lavier",

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Mechanical Implications of Creep and Partial Coupling on the World's Fastest Slipping Low-Angle Normal Fault in Southeastern Papua New Guinea. / Biemiller, James; Boulton, Carolyn; Wallace, Laura et al.
In: Journal of Geophysical Research: Solid Earth, Vol. 125, No. 10, e2020JB020117, 10.2020.

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

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AU - Ellis, Susan

AU - Little, Timothy

AU - Mizera, Marcel

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AU - Lavier, Luc

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AB - We use densely spaced campaign GPS observations and laboratory friction experiments on fault rocks from one of the world's most rapidly slipping low-angle normal faults, the Mai'iu fault in Papua New Guinea, to investigate the nature of interseismic deformation on active low-angle normal faults. GPS velocities reveal 8.3 ± 1.2 mm/year of horizontal extension across the Mai'iu fault, and are fit well by dislocation models with shallow fault locking (above 2 km depth), or by deeper locking (from ~5–16 km depth) together with shallower creep. Laboratory friction experiments show that gouges from the shallowest portion of the fault zone are predominantly weak and velocity-strengthening, while fault rocks deformed at greater depths are stronger and velocity-weakening. Evaluating the geodetic and friction results together with geophysical and microstructural evidence for mixed-mode seismic and aseismic slip at depth, we find that the Mai'iu fault is most likely strongly locked at depths of ~5–16 km and creeping updip and downdip of this region. Our results suggest that the Mai'iu fault and other active low-angle normal faults can slip in large (Mw > 7) earthquakes despite near-surface interseismic creep on frictionally stable clay-rich gouges.

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KW - seismic stability

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Mechanical Implications of Creep and Partial Coupling on the World's Fastest Slipping Low-Angle Normal Fault in Southeastern Papua New Guinea

Abstract

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Keywords

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