Landslides triggered by the 14 November 2016 Mw 7.8 Kaikōura earthquake, New Zealand

C. Massey; D. Townsend; E. Rathje; K. E. Allstadt; B. Lukovic; Y. Kaneko; B. Bradley; J. Wartman; R. W. Jibson; D. N. Petley; N. Horspool; I. Hamling; J. Carey; S. Cox; J. Davidson; S. Dellow; J. W. Godt; C. Holden; K. Jones; A. Kaiser; M. Little; B. Lyndsell; S. McColl; R. Morgenstern; F. K. Rengers; D. Rhoades; B. Rosser; D. Strong; C. Singeisen; M. Villeneuve

doi:10.1785/0120170305

Landslides triggered by the 14 November 2016 M_w 7.8 Kaikōura earthquake, New Zealand

C. Massey, D. Townsend, E. Rathje, K. E. Allstadt, B. Lukovic, Y. Kaneko, B. Bradley, J. Wartman, R. W. Jibson, D. N. Petley, N. Horspool, I. Hamling, J. Carey, S. Cox, J. Davidson, S. Dellow, J. W. Godt, C. Holden, K. Jones, A. KaiserM. Little, B. Lyndsell, S. McColl, R. Morgenstern, F. K. Rengers, D. Rhoades, B. Rosser, D. Strong, C. Singeisen, M. Villeneuve

Geography, Earth and Environmental Sciences

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

116 Citations (Scopus)

Abstract

The 14 November 2016 M_w 7.8 Kaikōura earthquake generated more than 10,000 landslides over a total area of about 10;000 km², with the majority concentrated in a smaller area of about 3600 km². The largest landslide triggered by the earthquake had an approximate volume of 20 2 Mm³, with a runout distance of about 2.7 km, forming a dam on the Hapuku River. In this article, we present version 1.0 of the landslide inventory we have created for this event. We use the inventory presented in this article to identify and discuss some of the controls on the spatial distribution of landslides triggered by the Kaikōura earthquake. Our main findings are (1) the number of medium to large landslides (source area ≥ 10;000 m²) triggered by the Kaikōura earthquake is smaller than for similar-sized landslides triggered by similar magnitude earthquakes in New Zealand; (2) seven of the largest eight landslides (from 5 to 20 Mm³) occurred on faults that ruptured to the surface during the earthquake; (3) the average landslide density within 200 m of a mapped surface fault rupture is three times that at a distance of 2500 m or more from a mapped surface fault rupture; (4) the “distance to fault” predictor variable, when used as a proxy for ground-motion intensity, and when combined with slope angle, geology, and elevation variables, has more power in predicting landslide probability than the modeled peak ground acceleration or peak ground velocity; and (5) for the same slope angles, the coastal slopes have landslide point densities that are an order of magnitude greater than those in similar materials on the inland slopes, but their source areas are significantly smaller.

Original language	English
Pages (from-to)	1630-1648
Number of pages	19
Journal	Bulletin of the Seismological Society of America
Volume	108
Issue number	3B
DOIs	https://doi.org/10.1785/0120170305
Publication status	Published - Jul 2018

Bibliographical note

Funding Information:
The GeoNet project, the New Zealand Natural Hazards Research Platform, and GNS Science Strategic Science Investment Fund (Landslide Hazards project) funded this work. The two anonymous reviewers and Eric Thompson (U.S. Geological Survey) made some very constructive and insightful comments. Nicola Litchfield and Russ Van Dissen (GNS Science) reviewed drafts of this article. The authors would also like to thank Nicholas Sitar (University of California [UC], Berkeley, California), and Marin Clark and Dimitrios Zekkos (University of Michigan, Ann Arbor, Michigan) for the time they spent in the field with the GNS Science landslide response team. Any use of trade, firm, or product names is for descriptive purposes only and does not imply endorsement by the U.S. Government.

Publisher Copyright:
© 2018, Seismological Society of America. All rights reserved.

ASJC Scopus subject areas

Geophysics
Geochemistry and Petrology

Access to Document

10.1785/0120170305

Cite this

Massey, C., Townsend, D., Rathje, E., Allstadt, K. E., Lukovic, B., Kaneko, Y., Bradley, B., Wartman, J., Jibson, R. W., Petley, D. N., Horspool, N., Hamling, I., Carey, J., Cox, S., Davidson, J., Dellow, S., Godt, J. W., Holden, C., Jones, K., ... Villeneuve, M. (2018). Landslides triggered by the 14 November 2016 M_w 7.8 Kaikōura earthquake, New Zealand. Bulletin of the Seismological Society of America, 108(3B), 1630-1648. https://doi.org/10.1785/0120170305

@article{517a4a8439df46b5be9a7918ec9d1ef6,

title = "Landslides triggered by the 14 November 2016 Mw 7.8 Kaikōura earthquake, New Zealand",

abstract = "The 14 November 2016 Mw 7.8 Kaikōura earthquake generated more than 10,000 landslides over a total area of about 10;000 km2, with the majority concentrated in a smaller area of about 3600 km2. The largest landslide triggered by the earthquake had an approximate volume of 20 2 Mm3, with a runout distance of about 2.7 km, forming a dam on the Hapuku River. In this article, we present version 1.0 of the landslide inventory we have created for this event. We use the inventory presented in this article to identify and discuss some of the controls on the spatial distribution of landslides triggered by the Kaikōura earthquake. Our main findings are (1) the number of medium to large landslides (source area ≥ 10;000 m2) triggered by the Kaikōura earthquake is smaller than for similar-sized landslides triggered by similar magnitude earthquakes in New Zealand; (2) seven of the largest eight landslides (from 5 to 20 Mm3) occurred on faults that ruptured to the surface during the earthquake; (3) the average landslide density within 200 m of a mapped surface fault rupture is three times that at a distance of 2500 m or more from a mapped surface fault rupture; (4) the “distance to fault” predictor variable, when used as a proxy for ground-motion intensity, and when combined with slope angle, geology, and elevation variables, has more power in predicting landslide probability than the modeled peak ground acceleration or peak ground velocity; and (5) for the same slope angles, the coastal slopes have landslide point densities that are an order of magnitude greater than those in similar materials on the inland slopes, but their source areas are significantly smaller.",

author = "C. Massey and D. Townsend and E. Rathje and Allstadt, {K. E.} and B. Lukovic and Y. Kaneko and B. Bradley and J. Wartman and Jibson, {R. W.} and Petley, {D. N.} and N. Horspool and I. Hamling and J. Carey and S. Cox and J. Davidson and S. Dellow and Godt, {J. W.} and C. Holden and K. Jones and A. Kaiser and M. Little and B. Lyndsell and S. McColl and R. Morgenstern and Rengers, {F. K.} and D. Rhoades and B. Rosser and D. Strong and C. Singeisen and M. Villeneuve",

note = "Funding Information: The GeoNet project, the New Zealand Natural Hazards Research Platform, and GNS Science Strategic Science Investment Fund (Landslide Hazards project) funded this work. The two anonymous reviewers and Eric Thompson (U.S. Geological Survey) made some very constructive and insightful comments. Nicola Litchfield and Russ Van Dissen (GNS Science) reviewed drafts of this article. The authors would also like to thank Nicholas Sitar (University of California [UC], Berkeley, California), and Marin Clark and Dimitrios Zekkos (University of Michigan, Ann Arbor, Michigan) for the time they spent in the field with the GNS Science landslide response team. Any use of trade, firm, or product names is for descriptive purposes only and does not imply endorsement by the U.S. Government. Publisher Copyright: {\textcopyright} 2018, Seismological Society of America. All rights reserved.",

year = "2018",

month = jul,

doi = "10.1785/0120170305",

language = "English",

volume = "108",

pages = "1630--1648",

journal = "Bulletin of the Seismological Society of America",

issn = "0037-1106",

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Massey, C, Townsend, D, Rathje, E, Allstadt, KE, Lukovic, B, Kaneko, Y, Bradley, B, Wartman, J, Jibson, RW, Petley, DN, Horspool, N, Hamling, I, Carey, J, Cox, S, Davidson, J, Dellow, S, Godt, JW, Holden, C, Jones, K, Kaiser, A, Little, M, Lyndsell, B, McColl, S, Morgenstern, R, Rengers, FK, Rhoades, D, Rosser, B, Strong, D, Singeisen, C & Villeneuve, M 2018, 'Landslides triggered by the 14 November 2016 M_w 7.8 Kaikōura earthquake, New Zealand', Bulletin of the Seismological Society of America, vol. 108, no. 3B, pp. 1630-1648. https://doi.org/10.1785/0120170305

TY - JOUR

T1 - Landslides triggered by the 14 November 2016 Mw 7.8 Kaikōura earthquake, New Zealand

AU - Massey, C.

AU - Townsend, D.

AU - Rathje, E.

AU - Allstadt, K. E.

AU - Lukovic, B.

AU - Kaneko, Y.

AU - Bradley, B.

AU - Wartman, J.

AU - Jibson, R. W.

AU - Petley, D. N.

AU - Horspool, N.

AU - Hamling, I.

AU - Carey, J.

AU - Cox, S.

AU - Davidson, J.

AU - Dellow, S.

AU - Godt, J. W.

AU - Holden, C.

AU - Jones, K.

AU - Kaiser, A.

AU - Little, M.

AU - Lyndsell, B.

AU - McColl, S.

AU - Morgenstern, R.

AU - Rengers, F. K.

AU - Rhoades, D.

AU - Rosser, B.

AU - Strong, D.

AU - Singeisen, C.

AU - Villeneuve, M.

N1 - Funding Information: The GeoNet project, the New Zealand Natural Hazards Research Platform, and GNS Science Strategic Science Investment Fund (Landslide Hazards project) funded this work. The two anonymous reviewers and Eric Thompson (U.S. Geological Survey) made some very constructive and insightful comments. Nicola Litchfield and Russ Van Dissen (GNS Science) reviewed drafts of this article. The authors would also like to thank Nicholas Sitar (University of California [UC], Berkeley, California), and Marin Clark and Dimitrios Zekkos (University of Michigan, Ann Arbor, Michigan) for the time they spent in the field with the GNS Science landslide response team. Any use of trade, firm, or product names is for descriptive purposes only and does not imply endorsement by the U.S. Government. Publisher Copyright: © 2018, Seismological Society of America. All rights reserved.

PY - 2018/7

Y1 - 2018/7

N2 - The 14 November 2016 Mw 7.8 Kaikōura earthquake generated more than 10,000 landslides over a total area of about 10;000 km2, with the majority concentrated in a smaller area of about 3600 km2. The largest landslide triggered by the earthquake had an approximate volume of 20 2 Mm3, with a runout distance of about 2.7 km, forming a dam on the Hapuku River. In this article, we present version 1.0 of the landslide inventory we have created for this event. We use the inventory presented in this article to identify and discuss some of the controls on the spatial distribution of landslides triggered by the Kaikōura earthquake. Our main findings are (1) the number of medium to large landslides (source area ≥ 10;000 m2) triggered by the Kaikōura earthquake is smaller than for similar-sized landslides triggered by similar magnitude earthquakes in New Zealand; (2) seven of the largest eight landslides (from 5 to 20 Mm3) occurred on faults that ruptured to the surface during the earthquake; (3) the average landslide density within 200 m of a mapped surface fault rupture is three times that at a distance of 2500 m or more from a mapped surface fault rupture; (4) the “distance to fault” predictor variable, when used as a proxy for ground-motion intensity, and when combined with slope angle, geology, and elevation variables, has more power in predicting landslide probability than the modeled peak ground acceleration or peak ground velocity; and (5) for the same slope angles, the coastal slopes have landslide point densities that are an order of magnitude greater than those in similar materials on the inland slopes, but their source areas are significantly smaller.

AB - The 14 November 2016 Mw 7.8 Kaikōura earthquake generated more than 10,000 landslides over a total area of about 10;000 km2, with the majority concentrated in a smaller area of about 3600 km2. The largest landslide triggered by the earthquake had an approximate volume of 20 2 Mm3, with a runout distance of about 2.7 km, forming a dam on the Hapuku River. In this article, we present version 1.0 of the landslide inventory we have created for this event. We use the inventory presented in this article to identify and discuss some of the controls on the spatial distribution of landslides triggered by the Kaikōura earthquake. Our main findings are (1) the number of medium to large landslides (source area ≥ 10;000 m2) triggered by the Kaikōura earthquake is smaller than for similar-sized landslides triggered by similar magnitude earthquakes in New Zealand; (2) seven of the largest eight landslides (from 5 to 20 Mm3) occurred on faults that ruptured to the surface during the earthquake; (3) the average landslide density within 200 m of a mapped surface fault rupture is three times that at a distance of 2500 m or more from a mapped surface fault rupture; (4) the “distance to fault” predictor variable, when used as a proxy for ground-motion intensity, and when combined with slope angle, geology, and elevation variables, has more power in predicting landslide probability than the modeled peak ground acceleration or peak ground velocity; and (5) for the same slope angles, the coastal slopes have landslide point densities that are an order of magnitude greater than those in similar materials on the inland slopes, but their source areas are significantly smaller.

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