Slow slip along the Hikurangi margin linked to fluid-rich sediments trailing subducting seamounts

Nathan L. Bangs; Julia K. Morgan; Rebecca E. Bell; Shuoshuo Han; Ryuta Arai; Shuichi Kodaira; Andrew C. Gase; Xinming Wu; Richard Davy; Laura Frahm; Hannah L. Tilley; Daniel H.N. Barker; Joel H. Edwards; Harold J. Tobin; Tim J. Reston; Stuart A. Henrys; Gregory F. Moore; Dan Bassett; Richard Kellett; Valerie Stucker; Bill Fry

doi:10.1038/s41561-023-01186-3

Slow slip along the Hikurangi margin linked to fluid-rich sediments trailing subducting seamounts

Nathan L. Bangs^*, Julia K. Morgan, Rebecca E. Bell, Shuoshuo Han, Ryuta Arai, Shuichi Kodaira, Andrew C. Gase, Xinming Wu, Richard Davy, Laura Frahm, Hannah L. Tilley, Daniel H.N. Barker, Joel H. Edwards, Harold J. Tobin, Tim J. Reston, Stuart A. Henrys, Gregory F. Moore, Dan Bassett, Richard Kellett, Valerie StuckerBill Fry

^*Corresponding author for this work

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

Abstract

Large seamounts and basement relief cause permanent deformation when they collide with the overriding plate at subduction zones. The resulting structural and compositional heterogeneities have been implicated as controlling factors in megathrust slip behaviour. Subducting seamounts may temporarily lock plates, favouring subsequent large earthquakes. Alternatively, seamounts may redistribute stress, reducing seismic slip. Here we present three-dimensional seismic data from the seamount-studded subducting Hikurangi Plateau along New Zealand’s North Island. We find that one well-imaged seamount, the Pāpaku Seamount, locally uplifts the overriding plate and leaves a tube-shaped lens of sediment trailing in its wake. Anomalously low seismic velocities within and below the Pāpaku lens and along the megathrust fault are consistent with the presence of unconsolidated, overpressured fluid-rich sediments. Similar observations from an older sediment lens, which corresponds to the location of a 2014 slow-slip rupture event, suggest that such overpressures can persist along the megathrust due to delayed drainage out of the subducting plate. The collocation of the 2014 slow-slip earthquake with this sediment lens suggests that these fluid-rich regions define zones that enable slow slip. We hypothesize that sediment lenses left behind by subducting seamounts can create low-effective-stress patches within transitionally stable marine sediment along the megathrust that are conducive to slow slip.

Original language	English
Pages (from-to)	505-512
Number of pages	8
Journal	Nature Geoscience
Volume	16
Issue number	6
DOIs	https://doi.org/10.1038/s41561-023-01186-3
Publication status	Published - 5 Jun 2023

Bibliographical note

Funding Information:
We thank the captains, crew and onboard science parties of the RV Tangaroa and the RV Marcus G. Langseth for their contribution to the data acquisition. We thank Paradigm Geophysical for providing software. We thank NIWA for providing bathymetry data. The academic NZ3D project was financially supported by US NSF (award #s 1559298 (N.L.B., S.H. and A.C.G.), 1901645 (N.L.B. and S.H.), 1559008 (G.F.M. and H.L.T.), 2023186 (G.F.M. and H.L.T.), 1558574 (H.J.T.) and 1558440 (J.H.E.)), NERC NE/M021203/1 (R.E.B., R.D. and L.F.), JAMSTEC (R.A. and S.K.), NZ MBIE and GNS Science (D.H.N.B., S.A.H., D.B., R.K., V.S. and B.F.).

Publisher Copyright:
© 2023, The Author(s), under exclusive licence to Springer Nature Limited.

ASJC Scopus subject areas

General Earth and Planetary Sciences

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1038/s41561-023-01186-3

Cite this

Bangs, N. L., Morgan, J. K., Bell, R. E., Han, S., Arai, R., Kodaira, S., Gase, A. C., Wu, X., Davy, R., Frahm, L., Tilley, H. L., Barker, D. H. N., Edwards, J. H., Tobin, H. J., Reston, T. J., Henrys, S. A., Moore, G. F., Bassett, D., Kellett, R., ... Fry, B. (2023). Slow slip along the Hikurangi margin linked to fluid-rich sediments trailing subducting seamounts. Nature Geoscience, 16(6), 505-512. https://doi.org/10.1038/s41561-023-01186-3

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title = "Slow slip along the Hikurangi margin linked to fluid-rich sediments trailing subducting seamounts",

abstract = "Large seamounts and basement relief cause permanent deformation when they collide with the overriding plate at subduction zones. The resulting structural and compositional heterogeneities have been implicated as controlling factors in megathrust slip behaviour. Subducting seamounts may temporarily lock plates, favouring subsequent large earthquakes. Alternatively, seamounts may redistribute stress, reducing seismic slip. Here we present three-dimensional seismic data from the seamount-studded subducting Hikurangi Plateau along New Zealand{\textquoteright}s North Island. We find that one well-imaged seamount, the Pāpaku Seamount, locally uplifts the overriding plate and leaves a tube-shaped lens of sediment trailing in its wake. Anomalously low seismic velocities within and below the Pāpaku lens and along the megathrust fault are consistent with the presence of unconsolidated, overpressured fluid-rich sediments. Similar observations from an older sediment lens, which corresponds to the location of a 2014 slow-slip rupture event, suggest that such overpressures can persist along the megathrust due to delayed drainage out of the subducting plate. The collocation of the 2014 slow-slip earthquake with this sediment lens suggests that these fluid-rich regions define zones that enable slow slip. We hypothesize that sediment lenses left behind by subducting seamounts can create low-effective-stress patches within transitionally stable marine sediment along the megathrust that are conducive to slow slip.",

author = "Bangs, {Nathan L.} and Morgan, {Julia K.} and Bell, {Rebecca E.} and Shuoshuo Han and Ryuta Arai and Shuichi Kodaira and Gase, {Andrew C.} and Xinming Wu and Richard Davy and Laura Frahm and Tilley, {Hannah L.} and Barker, {Daniel H.N.} and Edwards, {Joel H.} and Tobin, {Harold J.} and Reston, {Tim J.} and Henrys, {Stuart A.} and Moore, {Gregory F.} and Dan Bassett and Richard Kellett and Valerie Stucker and Bill Fry",

note = "Funding Information: We thank the captains, crew and onboard science parties of the RV Tangaroa and the RV Marcus G. Langseth for their contribution to the data acquisition. We thank Paradigm Geophysical for providing software. We thank NIWA for providing bathymetry data. The academic NZ3D project was financially supported by US NSF (award #s 1559298 (N.L.B., S.H. and A.C.G.), 1901645 (N.L.B. and S.H.), 1559008 (G.F.M. and H.L.T.), 2023186 (G.F.M. and H.L.T.), 1558574 (H.J.T.) and 1558440 (J.H.E.)), NERC NE/M021203/1 (R.E.B., R.D. and L.F.), JAMSTEC (R.A. and S.K.), NZ MBIE and GNS Science (D.H.N.B., S.A.H., D.B., R.K., V.S. and B.F.). Publisher Copyright: {\textcopyright} 2023, The Author(s), under exclusive licence to Springer Nature Limited.",

year = "2023",

month = jun,

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doi = "10.1038/s41561-023-01186-3",

language = "English",

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Bangs, NL, Morgan, JK, Bell, RE, Han, S, Arai, R, Kodaira, S, Gase, AC, Wu, X, Davy, R, Frahm, L, Tilley, HL, Barker, DHN, Edwards, JH, Tobin, HJ, Reston, TJ, Henrys, SA, Moore, GF, Bassett, D, Kellett, R, Stucker, V & Fry, B 2023, 'Slow slip along the Hikurangi margin linked to fluid-rich sediments trailing subducting seamounts', Nature Geoscience, vol. 16, no. 6, pp. 505-512. https://doi.org/10.1038/s41561-023-01186-3

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T1 - Slow slip along the Hikurangi margin linked to fluid-rich sediments trailing subducting seamounts

AU - Bangs, Nathan L.

AU - Morgan, Julia K.

AU - Bell, Rebecca E.

AU - Han, Shuoshuo

AU - Arai, Ryuta

AU - Kodaira, Shuichi

AU - Gase, Andrew C.

AU - Wu, Xinming

AU - Davy, Richard

AU - Frahm, Laura

AU - Tilley, Hannah L.

AU - Barker, Daniel H.N.

AU - Edwards, Joel H.

AU - Tobin, Harold J.

AU - Reston, Tim J.

AU - Henrys, Stuart A.

AU - Moore, Gregory F.

AU - Bassett, Dan

AU - Kellett, Richard

AU - Stucker, Valerie

AU - Fry, Bill

N1 - Funding Information: We thank the captains, crew and onboard science parties of the RV Tangaroa and the RV Marcus G. Langseth for their contribution to the data acquisition. We thank Paradigm Geophysical for providing software. We thank NIWA for providing bathymetry data. The academic NZ3D project was financially supported by US NSF (award #s 1559298 (N.L.B., S.H. and A.C.G.), 1901645 (N.L.B. and S.H.), 1559008 (G.F.M. and H.L.T.), 2023186 (G.F.M. and H.L.T.), 1558574 (H.J.T.) and 1558440 (J.H.E.)), NERC NE/M021203/1 (R.E.B., R.D. and L.F.), JAMSTEC (R.A. and S.K.), NZ MBIE and GNS Science (D.H.N.B., S.A.H., D.B., R.K., V.S. and B.F.). Publisher Copyright: © 2023, The Author(s), under exclusive licence to Springer Nature Limited.

PY - 2023/6/5

Y1 - 2023/6/5

N2 - Large seamounts and basement relief cause permanent deformation when they collide with the overriding plate at subduction zones. The resulting structural and compositional heterogeneities have been implicated as controlling factors in megathrust slip behaviour. Subducting seamounts may temporarily lock plates, favouring subsequent large earthquakes. Alternatively, seamounts may redistribute stress, reducing seismic slip. Here we present three-dimensional seismic data from the seamount-studded subducting Hikurangi Plateau along New Zealand’s North Island. We find that one well-imaged seamount, the Pāpaku Seamount, locally uplifts the overriding plate and leaves a tube-shaped lens of sediment trailing in its wake. Anomalously low seismic velocities within and below the Pāpaku lens and along the megathrust fault are consistent with the presence of unconsolidated, overpressured fluid-rich sediments. Similar observations from an older sediment lens, which corresponds to the location of a 2014 slow-slip rupture event, suggest that such overpressures can persist along the megathrust due to delayed drainage out of the subducting plate. The collocation of the 2014 slow-slip earthquake with this sediment lens suggests that these fluid-rich regions define zones that enable slow slip. We hypothesize that sediment lenses left behind by subducting seamounts can create low-effective-stress patches within transitionally stable marine sediment along the megathrust that are conducive to slow slip.

AB - Large seamounts and basement relief cause permanent deformation when they collide with the overriding plate at subduction zones. The resulting structural and compositional heterogeneities have been implicated as controlling factors in megathrust slip behaviour. Subducting seamounts may temporarily lock plates, favouring subsequent large earthquakes. Alternatively, seamounts may redistribute stress, reducing seismic slip. Here we present three-dimensional seismic data from the seamount-studded subducting Hikurangi Plateau along New Zealand’s North Island. We find that one well-imaged seamount, the Pāpaku Seamount, locally uplifts the overriding plate and leaves a tube-shaped lens of sediment trailing in its wake. Anomalously low seismic velocities within and below the Pāpaku lens and along the megathrust fault are consistent with the presence of unconsolidated, overpressured fluid-rich sediments. Similar observations from an older sediment lens, which corresponds to the location of a 2014 slow-slip rupture event, suggest that such overpressures can persist along the megathrust due to delayed drainage out of the subducting plate. The collocation of the 2014 slow-slip earthquake with this sediment lens suggests that these fluid-rich regions define zones that enable slow slip. We hypothesize that sediment lenses left behind by subducting seamounts can create low-effective-stress patches within transitionally stable marine sediment along the megathrust that are conducive to slow slip.

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ER -

Slow slip along the Hikurangi margin linked to fluid-rich sediments trailing subducting seamounts

Abstract

Bibliographical note

ASJC Scopus subject areas

UN SDGs

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