Evaluating 9 m of near-surface transpressional displacement during the Mw 7.8 2016 Kaikōura earthquake: re-excavation of a pre-earthquake paleoseismic trench, Kekerengu Fault, New Zealand

During the Kaikōura earthquake, a paleoseismic trench was dextrally displaced ∼9 m and shortened by 1.3 ± 0.4 m - the largest globally recorded displacement of a trench. Analysis showed that two processes accommodated subequal amounts of slip at the surface: (1) discrete dextral-slip on two steeply-...

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Bibliographic Details
Published inNew Zealand journal of geology and geophysics Vol. 66; no. 2; pp. 244 - 262
Main Authors Morris, Philippa, Little, Timothy, Van Dissen, Russ, Hill, Matthew, Hemphill-Haley, Mark, Kearse, Jesse, Norton, Kevin
Format Journal Article
LanguageEnglish
Published Abingdon Taylor & Francis 01.06.2023
Taylor & Francis Ltd
Subjects
2016 Kaikōura earthquake
Deformation
Dipping
Displacement
Dredging
Earthquakes
Excavation
Fault lines
fault zone deformation
Fault zones
Geological faults
Kinematics
Paleogeology
Paleoseismology
Rafting
Rafts
Rotation
Seismic activity
Slip
strike-slip faults
structural geology
Turf
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Summary:During the Kaikōura earthquake, a paleoseismic trench was dextrally displaced ∼9 m and shortened by 1.3 ± 0.4 m - the largest globally recorded displacement of a trench. Analysis showed that two processes accommodated subequal amounts of slip at the surface: (1) discrete dextral-slip on two steeply-dipping faults bounding a <3.5 m wide central deformation zone; and (2) coseismic clockwise rotation of turf rafts and pervasive sediment deformation in that zone. The second (successive) process resulted in upward (<1 m) and outward (<2 m) bulging along low-angle thrusts, creating horizontal fault-perpendicular shortening that exceeds the heave (∼1.3 m). This discrepancy results from coseismic rotation of rafts, that shorten upon approaching perpendicularity with the fault - creating extra apparent shortening (in fault-orthogonal view). Comparison of pre- and post-earthquake trench logs indicates that strike-slip ruptures at the same site can be expressed differently over time; fault strands carrying major displacement in 2016 were not the locus of deformation in the previous earthquake(s), suggesting temporal unpredictability is important in defining fault zones. The last several paleoearthquakes at the trench produced cm-dm scale normal-sense dip separations across faults; however, the 2016 earthquake created compressive structures including up-bulging and low-angle reverse faulting, as well as fissuring. This contrast in deformation style likely resulted from an >8° clockwise rotation of the local slip vector in 2016 (becoming transpressive), highlighting that small changes in slip kinematics may affect rupture zone structures.
ISSN:0028-8306
1175-8791
DOI:10.1080/00288306.2021.1954958