Petrophysical, geochemical, and hydrological evidence for extensive fracture-mediated fluid and heat transport in the Alpine Fault's hanging-wall damage zone

Townend, John; Sutherland, Rupert; Toy, Virginia; Doan, M. L.; Célérier, Bernard; Massiot, Cécile; Coussens, Jamie; Jeppson, T.; Janku-Capova, Lucie; Remaud, L; Upton, Phædra; Schmitt, DR; Pézard, Philippe; Williams, J; Allen, MJ; Baratin, LM; Barth, Nicolas C.; Becroft, Leeza; Boese, CM; Boulton, Carolyn; Broderick, Neil G. R.; Carpenter, B. M.; Chamberlain, C. J.; Cooper, Alan F.; Coutts, Ashley; Cox, Simon C.; Craw, Lisa; Eccles, JD; Faulkner, D. R.; Grieve, Jason; Grochowski, Julia; Gulley, Anton; Hartog, Arthur H.; Henry, Gilles; Howarth, Jamie; Jacobs, Katrina; Kato, Naoki; Kirilova, Martina; Kometani, Yusuke; Langridge, R. M.; Lin, Wei; Little, Timothy A.; Lukács, Adrienn; Mallyon, Deirdre; Mariani, Elisabetta; Mathewson, Loren; Melosh, Ben; Menzies, C.D.; Moore, J; Morales, L. F. G.; Mori, Hiroshi; Niemeijer, A. R.; Nishikawa, Osamu; Nitsch, O.; Paris, J.; Prior, DJ; Sauer, Katrina; Savage, M. K.; Schleicher, Anja M.; Shigematsu, Norio; Taylor-Offord, Sam; Teagle, D.A.H.; Tobin, H. J.; Valdez, R. D.; Weaver, KC; Wiersberg, Thomas; Zimmer, Martin

doi:10.26686/wgtn.13876499

Cited by 4 publications

(9 citation statements)

References 79 publications

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“…If so, the interpreted damage zone would then be nearly 600 m wide and exhibit reflectors with dip angles of 40°–56°. The dip angles of the imaged reflectors are well within the range of observed values from other analyses showing dips of 45°–65° both in the DFDP‐2 borehole (Massiot et al., 2018; Townend et al., 2017; Toy et al., 2017) and extrapolated shallow trenches (Langridge et al., 2018).…”

Section: Discussionsupporting

confidence: 84%

“…Thus, this fault or fracture zone might have a significant contrast in acoustic impedance in order to produce seismic reflections and to be visible in seismic images. However, it is not well constrained in other studies (Janku‐Capova et al., 2018; Jeppson & Tobin, 2020a; Massiot et al., 2018; Townend et al., 2017).…”

Section: Resultsmentioning

confidence: 85%

“…(2018) can attain a width of up to 1–10 km and reflects a superposition of various fractures that cause seismological and geodetic alteration. This broad damage zone is observed to be hydrogeological active (Janku‐Capova et al., 2018; Menzies et al., 2016; Townend et al., 2017). Extensive fracturing enables fluid flow and is observed to be both inherited from previous structures and fault‐related (Massiot et al., 2018; Simpson et al., 2020; Williams et al., 2018).…”

Section: Discussionmentioning

confidence: 99%

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3D Active Source Seismic Imaging of the Alpine Fault Zone and the Whataroa Glacial Valley in New Zealand

et al. 2021

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The Alpine Fault zone in New Zealand marks a major transpressional plate boundary that is late in its typical earthquake cycle. Understanding the subsurface structures is crucial to understand the tectonic processes taking place. A unique seismic survey including 2D lines, a 3D array, and borehole recordings, has been performed in the Whataroa Valley and provides new insights into the Alpine Fault zone down to ∼2 km depth at the location of the Deep Fault Drilling Project (DFDP)‐2 drill site. Seismic images are obtained by focusing prestack depth migration approaches. Despite the challenging conditions for seismic imaging within a sediment filled glacial valley and steeply dipping valley flanks, several structures related to the valley itself as well as the tectonic fault system are imaged. A set of several reflectors dipping 40°–56° to the southeast are identified in a ∼600 m wide zone that is interpreted to be the minimum extent of the damage zone. Different approaches image one distinct reflector dipping at ∼40°, which is interpreted to be the main Alpine Fault reflector located only ∼100 m beneath the maximum drilled depth of the DFDP‐2B borehole. At shallower depths (z < 0.5 km), additional reflectors are identified as fault segments with generally steeper dips up to 56°. Additionally, a glacially over‐deepened trough with nearly horizontally layered sediments and a major fault (z < 0.5 km) are identified 0.5–1 km south of the DFDP‐2B borehole. Thus, a complex structural environment is seismically imaged and shows the complexity of the Alpine Fault at Whataroa.

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Section: Discussionsupporting

confidence: 84%

Section: Resultsmentioning

confidence: 85%

Section: Discussionmentioning

confidence: 99%

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3D Active Source Seismic Imaging of the Alpine Fault Zone and the Whataroa Glacial Valley in New Zealand

et al. 2021

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“…Field observations are shown in colored boxes: Green is the sonic log wave speed recorded in the DFDP‐2B well from Townend et al. (2017), pink is the low‐velocity zone (LVZ) defined from teleseismic and refraction seismic analysis by Stern et al. (2007), and yellow is the LVZ defined by Feenstra et al.…”

Section: Implications Of P‐wave Anisotropy For Imaging the Alpine Faultmentioning

confidence: 99%

“…We compare our experimental and numerically simulated wave speeds at low effective pressures to the DFDP‐2B borehole sonic log acquired in 2014 (Figure 11). The DFDP‐2B well drilled to a depth of 818 m beneath the Whataroa Valley in the Central Southern Alps of New Zealand as part of the Deep Fault Drilling Project (Massiot et al., 2018; Townend et al., 2017; Toy et al., 2017). The sonic log records wave speeds at a range of angles to foliation (normal to foliation to 50° from normal) due to the high deviation of the DFDP‐2B borehole.…”

Section: Implications Of P‐wave Anisotropy For Imaging the Alpine Faultmentioning

confidence: 99%

Seismic Anisotropy and Its Impact on Imaging the Shallow Alpine Fault: An Experimental and Modeling Perspective

et al. 2020

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The transpressional Alpine Fault in New Zealand has created a thick shear zone with associated highly anisotropic rocks. Low seismic velocity zones and high seismic reflectivity are recorded in the Alpine Fault Zone, but no study has explored the underlying physical rock parameters of the shallow crust that control these observations. Protomylonites are the volumetrically dominant lithology of the fault zone. Here we combine experimental measurements of P‐wave speeds with numerical models of elastic wave anisotropy of protomylonite samples to explore how the fault zone can be seismically imaged. Numerical models that account for the porosity‐free real samples' fabric elastic tensors from electron backscatter diffraction (EBSD) are calculated by MTEX and a finite element model (FEM), while microfractures are modeled with differential effective medium (DEM) theory. At effective pressures representative of the Alpine Fault brittle zone, experimental wave speeds are lower than those predicted by MTEX/FEM. A possible DEM model suggests that a combination of random and aligned microfractures with aspect ratios increasing with pressure can explain the experimental wave speeds for pressures <70 MPa. Such microporosity in the form of foliation‐ and mica basal plane‐parallel microfractures and grain boundaries is validated with synchrotron X‐ray microtomography and transmission electron microscopy (TEM) images. Finally, by modeling anisotropy of seismic reflection coefficients with angle of incidence, we demonstrate that the high reflectivity and low‐velocity zone (LVZ) observed at the Alpine Fault can only be explained if this microporosity is accounted for throughout the brittle fault zone, even at depths of 7–10 km.

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Heterogeneity in Microseismicity and Stress Near Rupture‐Limiting Section Boundaries Along the Late‐Interseismic Alpine Fault

et al. 2022

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Paleoseismic evidence from the late‐interseismic Alpine Fault suggests key section boundaries conditionally inhibit rupture. We utilize a year of data from a two‐part seismometer network (Dense Westland Arrays Researching Fault Segmentation) to characterize ∼7,500 earthquakes (−0.7 ≤ MLv ≤ 4.2) and ∼800 focal mechanisms, producing high‐resolution structural images of these boundaries to study effects of material and structural heterogeneities on mode‐switching rupture behavior. Lithologically‐controlled frictional behavior and crustal strength appear to influence lateral and vertical on‐fault seismicity distributions. Ultramafic hanging‐wall serpentinite and serpentinite‐related fault core minerals along the South Westland (SW) boundary, result in a locally shallow seismogenic cuttoff (∼8 km) and abundant on‐fault seismicity. Maximum horizontal compressive stress rotations (14° anti‐clockwise and 20° clockwise near the SW and North Westland (NW) boundaries, respectively, relative to the Central Section), coupled with spatially variable fault frictional properties, are more important than geometry alone in controlling Sections' relative frictional stability. Whereas the SW and Central Sections are well‐oriented for failure, the NW Section is severely misoriented compared with favorably oriented faults of the Marlborough Fault Zone, which possibly facilitate a preferred rupture route. Geometrically, a 40° dip change at the SW boundary may be accommodated either by a single through‐going fault plane ‐ a difficult geometry across which to obtain multi‐segment earthquakes when considering rupture dynamics ‐ or by a deeper vertical fault strand truncated by a shallower listric plane. Our new observations have implications for Alpine Fault rupture scenarios and highlight the need to consider a range of spatially heterogeneous, interdependent physical factors when evaluating controls on rupture segmentation.

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Petrophysical, geochemical, and hydrological evidence for extensive fracture-mediated fluid and heat transport in the Alpine Fault's hanging-wall damage zone

Cited by 4 publications

References 79 publications

3D Active Source Seismic Imaging of the Alpine Fault Zone and the Whataroa Glacial Valley in New Zealand

3D Active Source Seismic Imaging of the Alpine Fault Zone and the Whataroa Glacial Valley in New Zealand

Seismic Anisotropy and Its Impact on Imaging the Shallow Alpine Fault: An Experimental and Modeling Perspective

Heterogeneity in Microseismicity and Stress Near Rupture‐Limiting Section Boundaries Along the Late‐Interseismic Alpine Fault

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