Surface rupture of the Greendale Fault during the Darfield (Canterbury) earthquake, New Zealand

Quigley, Mark; Dissen, Russ Van; Villamor, Pilar; Litchfield, Nicola; Barrell, David; Furlong, Kevin P.; Stahl, Timothy; Duffy, Brendan; Bilderback, Eric L.; Noble, D.; Townsend, Dougal; Begg, John; Jongens, Richard; Ries, W.; Claridge, J.; Klahn, A.; Mackenzie, H.; Smith, A. J. S.; Hornblow, S.; Nicol, R.; Cox, Simon C.; Langridge, Robert; Pedley, Kate

doi:10.5459/bnzsee.43.4.236-242

Cited by 60 publications

(54 citation statements)

References 10 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The authors called this newly recognized fault the Greendale Fault. The westernmost ∼5 km of the rupture trends WNW–ESE, approximately following the course of the Hororata river and in one place partially blocking its channel, leading to minor flooding of adjacent fields [ Quigley et al , 2010, Figure 5]. However, this westernmost part lacks coverage of Worldview imagery, aerial photography or LiDAR topography.…”

Section: Surface Rupturing In the Darfield Earthquakementioning

confidence: 99%

“…The faults that ruptured in the 2010 and 2011 earthquakes were previously unknown. Preliminary studies have already either mapped the surface ruptures [ Quigley et al , 2010], geodetically constrained the main fault segments [ Beavan et al , 2010] or determined the distribution of aftershocks [ Gledhill et al , 2011]. We combine Interferometric Synthetic Aperture Radar (InSAR) observations (Figure 2), with field mapping, aerial and satellite imagery, a post‐earthquake LiDAR Digital Elevation Model (DEM) and seismological body‐wave solutions to examine the distribution of rupture, and to model the locations and orientations of these previously unknown faults.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Slip in the 2010–2011 Canterbury earthquakes, New Zealand

Elliott¹,

Nissen²,

England³

et al. 2012

J. Geophys. Res.

117

119

View full text Add to dashboard Cite

The 3rd September 2010 Mw 7.1 Darfield and 21st February 2011 Mw 6.3 Christchurch (New Zealand) earthquakes occurred on previously unknown faults. We use InSAR ground displacements, SAR amplitude offsets, field mapping, aerial photographs, satellite optical imagery, a LiDAR DEM and teleseismic body‐wave modeling to constrain the pattern of faulting in these earthquakes. The InSAR measurements reveal slip on multiple strike‐slip segments and secondary reverse faults associated with the Darfield main shock. Fault orientations are consistent with those expected from the GPS‐derived strain field. The InSAR line‐of‐sight displacement field indicates the main fault rupture is about 45 km long, and is confined largely to the upper 10 km of the crust. Slip on the individual fault segments of up to 8 m at 4 km depth indicate stress drops of 6–10 MPa. In each event, rupture initiated on a reverse fault segment, before continuing onto a strike‐slip segment. The non‐double couple seismological moment tensors for each event are matched well by the sum of double couple equivalent moment tensors for fault slip determined by InSAR. The slip distributions derived from InSAR observations of both the Darfield and Christchurch events show a 15‐km‐long gap in fault slip south‐west of Christchurch, which may present a continuing seismic hazard if a further unknown fault structure of significant size should exist there.

show abstract

Section: Surface Rupturing In the Darfield Earthquakementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Slip in the 2010–2011 Canterbury earthquakes, New Zealand

Elliott¹,

Nissen²,

England³

et al. 2012

J. Geophys. Res.

117

119

View full text Add to dashboard Cite

show abstract

“…Map showing seismic stations used in this study (triangles), the mapped surface rupture of the Greendale Fault (red line) [ Quigley et al ., ], and the epicenters of the Darfield and Christchurch earthquakes (solid stars). The approximate locations of the 1869 M w 4.7–4.9 Christchurch earthquake and the 1870 M w 5.6–5.8 Lake Ellesmere earthquake are shown by the outlined stars [ Downes and Yetton , ].…”

Section: Introductionmentioning

confidence: 99%

High‐resolution relocation of aftershocks of the M_w 7.1 Darfield, New Zealand, earthquake and implications for fault activity

et al. 2013

View full text Add to dashboard Cite

Low‐slip‐rate regions often represent under‐recognized hazards, and understanding the progression of seismicity when faults in such areas rupture will help us to better understand earthquake rupture patterns. The 3 September 2010 (UTC) Mw 7.1 Darfield earthquake revealed a formerly unrecognized set of faults in the Canterbury region of New Zealand, an area that had previously been mapped as one of the lower‐hazard areas in the country. In this study, we analyze the first four months of its aftershock sequence to identify active faults and temporal changes in seismicity along them. We jointly invert for three‐dimensional P wave and S wave velocities and hypocentral locations, using data for 2840 aftershocks recorded at 36 temporary and permanent seismic stations within 70 km of the main shock epicenter. These relocations delineate eight individual faults active prior to the 22 February 2011 Mw 6.3 Christchurch earthquake, the largest aftershock of the Darfield earthquake. Two of these faults are in the Christchurch region, one of which corresponds to geodetically determined rupture planes of the Christchurch earthquake. Using focal mechanisms calculated from first‐motion polarities, we find mainly strike‐slip faulting events, with some reverse and normal faulting events as well. We compare the orientations of these faults to the prevailing regional stress directions to identify which faults may have been active prior to the Darfield earthquake and which may be newly developed.

show abstract

“…This late Cretaceous fault is probably dipping at about 60° to the south, whereas the largely dextral Greendale Fault is subvertical with a south-side-up component of movement (Quigley et al 2011). Similar cases where the strike of a new fault has been inherited from older structures but the dip has not have been reported by Ring (1994) from the East African Rift.…”

Section: Pre-existing Structures and The Recent Earthquakesmentioning

confidence: 86%

“…The ENE-WSW-striking faults also occur in the Lyttelton Harbour area and are considered to be either rotated late Cretaceous east-west faults or faults that formed in the late Miocene when the encroaching Chatham Rise interacted with the developing plate boundary zone on the South and North Island of New Zealand. Quigley et al (2011) and other faults with inferred kinematic axes are from Sibson et al (2012). Also shown are main faults in Banks Peninsula with kinematic axes inferred from the data presented in Figures 4-12. Because the method used for constructing principal shortening and extension axes for a given population of faults is similar to that used to determine infinitesimal strain directions for earthquake focal mechanisms (P-and T-axes, respectively), the kinematic axes can be compared.…”

Section: Discussionmentioning

confidence: 99%

Faulting in Banks Peninsula: tectonic setting and structural controls for late Miocene intraplate volcanism, New Zealand

Ring

Hampton

2012

JGS

View full text Add to dashboard Cite

An analysis of faulting in the late Miocene volcanic rocks of Banks Peninsula, South Island, New Zealand, shows that the formation of the volcanic edifice was largely controlled by NE–SW-striking dextral-oblique strike-slip faults. The data show a variable component of west–east- or NW–SE-oriented shortening and north–south or NE–SW extension. Synvolcanic faults reactivated Cretaceous normal faults and are interpreted to have formed a local pull-apart basin that controlled volcanism. Further east, the geometry of Akaroa Harbour is controlled by a north–south-striking oblique reverse fault. Limited fault-slip data collected from sub-recent loess deposits are not significantly different from the data collected in the volcanic rocks and appear to show that the kinematic field did not change significantly over the last c . 10 Ma. The overall kinematic field causing the recent series of earthquakes in the greater Christchurch region is also not fundamentally different from the one that controlled the eruption of the volcanic rocks. We conclude that the inherited Cretaceous faults controlled the development of the late Miocene volcanism on Banks Peninsula and largely provided a major anisotropy along which the recent faults ruptured.

show abstract

Surface rupture of the Greendale Fault during the Darfield (Canterbury) earthquake, New Zealand

Cited by 60 publications

References 10 publications

Slip in the 2010–2011 Canterbury earthquakes, New Zealand

Slip in the 2010–2011 Canterbury earthquakes, New Zealand

High‐resolution relocation of aftershocks of the M_w 7.1 Darfield, New Zealand, earthquake and implications for fault activity

Faulting in Banks Peninsula: tectonic setting and structural controls for late Miocene intraplate volcanism, New Zealand

Contact Info

Product

Resources

About

Surface rupture of the Greendale Fault during the Darfield (Canterbury) earthquake, New Zealand

Cited by 60 publications

References 10 publications

Slip in the 2010–2011 Canterbury earthquakes, New Zealand

Slip in the 2010–2011 Canterbury earthquakes, New Zealand

High‐resolution relocation of aftershocks of the Mw 7.1 Darfield, New Zealand, earthquake and implications for fault activity

Faulting in Banks Peninsula: tectonic setting and structural controls for late Miocene intraplate volcanism, New Zealand

Contact Info

Product

Resources

About

High‐resolution relocation of aftershocks of the M_w 7.1 Darfield, New Zealand, earthquake and implications for fault activity