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Preliminary interpretation of electromagnetic, heat flow, seismic, and geochemical data for gas hydrate distribution across the Porangahau Ridge, New Zealand (2009)

Schwalenberg, Katrin 1967-

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In: Marine geology, Amsterdam [u.a.] : Elsevier Science, 1964, (2009), 1872-6151

In: year:2009

In: extent:10

Description / Table of Contents: Porangahau Ridge, located offshore the Wairarapa on the Hikurangi Margin, is an active ocean-continent collision region in northeastern New Zealand coastal waters. Bottom simulating reflections (BSRs) in seismic data indicate the potential for significant gas hydrate deposits across this part of the margin. Beneath Porangahau Ridge a prominent high-amplitude reflection band has been observed to extend from a deep BSR towards the seafloor. Review of the seismic data suggest that this high-amplitude band is caused by local shoaling of the base of gas hydrate stability due to advective heat flow and it may constitute the location of elevated gas hydrate concentrations. During R/V Tangaroa cruise TAN0607 in 2006 heat flow probing for measurements of vertical fluid migration, sediment coring for methane concentrations, and additional seismic profiles were obtained across the ridge. In a subsequent 2007 expedition, on R/V Sonne cruise SO191, a controlled source electromagnetic (CSEM) experiment was conducted along the same seismic, geochemical, and heat flow transect to reveal the electrical resistivity distribution. CSEM data highlight a remarkable coincidence of anomalously high resistivity along the western, landward flank of the ridge which point to locally higher gas hydrate concentration above the high amplitude reflection band. Measured sediment temperature profiles, also along the western flank, consistently show non-linear and concave geothermal gradients typical of advective heat flow. Geochemical data reveal elevated methane concentrations in surface sediments concomitant with a rapid decline in sulfate concentrations indicating elevated methane flux and oxidation of methane in conjunction with sulfate reduction at the landward ridge base. Together, these data sets suggest that the western rim of Porangahau Ridge is a tectonically driven zone of rising fluids that transport methane and cause an upward inflection of the base of gas hydrate stability and the formation of locally enriched gas hydrate above the reflective zone.

Type of Medium: Online Resource

Pages: 10 , graph. Darst

ISSN: 1872-6151

URL: http://dx.doi.org/10.1016/j.margeo.2009.10.024

DOI: 10.1016/j.margeo.2009.10.024

Language: English

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2

Electronic Resource

Orbitally induced oscillations in the East Antarctic ice sheet at the Oligocene/Miocene boundary (2001)

Woolfe, Ken J. ; Barrett, Peter J. ; Wilson, Gary S. ; [et al.]

[s.l.] : Macmillian Magazines Ltd.

Nature 413 (2001), S. 719-723

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ISSN: 1476-4687

Source: Nature Archives 1869 - 2009

Topics: Biology , Chemistry and Pharmacology , Medicine , Natural Sciences in General , Physics

Notes: [Auszug] Between 34 and 15 million years (Myr) ago, when planetary temperatures were 3–4 °C warmer than at present and atmospheric CO2 concentrations were twice as high as today, the Antarctic ice sheets may have been unstable. Oxygen isotope records from deep-sea ...

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1038/35099534

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Evolution of fluid expulsion and concentrated hydrate zones across the southern Hikurangi subduction margin, New Zealand: An analysis from depth migrated seismic data (2012)

Plaza-Faverola, Andreia ; Klaeschen, Dirk ; Barnes, Philip ; [et al.]

AGU (American Geophysical Union)

In: Geochemistry, Geophysics, Geosystems, 13 . Q08018.

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Publication Date: 2018-03-01

Description: Identification of methane sources controlling hydrate distribution and concentrations in continental margins remains a major challenge in gas hydrate research. Lack of deep fluid samples and high quality regional scale seismic reflection data may lead to underestimation of the significance of fluid escape from subducting and compacting sediments in the global inventory of methane reaching the hydrate zone, the water column and the atmosphere. The distribution of concentrated hydrate zones in relation to focused fluid flow across the southern Hikurangi subduction margin was investigated using high quality, long offset (10 km streamer), pre-stack depth migrated multichannel seismic data. Analysis of low P wave velocity zones, bright-reverse polarity reflections and dim-amplitude anomalies reveals pathways for gas escape and zones of gas accumulation. The study shows the structural and stratigraphic settings of three main areas of concentrated hydrates: (1) the Opouawe Bank, dominated by focused periodic fluid input along thrust faults sustaining dynamic hydrate concentrations and gas chimneys development; (2) the frontal anticline, with a basal set of protothrusts controlling permeability for fluids from deeply buried and subducted sediments sustaining hydrate concentrations at the crest of the anticline; and (3) the Hikurangi Channel, with buried sand dominated channels hosting significant amounts of gas beneath the base of the hydrate zone. In sand dominated channels gas injection into the hydrate zone favors highly concentrated hydrate accumulations. The evolution of fluid expulsion controlling hydrate formation offshore southern Hikurangi is described in stages during which different methane sources (in situ, buried and thermogenic) have been dominant.

Type: Article , PeerReviewed

Format: text

DOI: 10.1029/2012GC004228

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Morphometric and critical taper analysis of the Rock Garden region, Hikurangi Margin, New Zealand: Implications for slope stability and potential tsunami generation (2010)

Kukowski, Nina ; Greinert, Jens ; Henrys, Stuart

Elsevier

In: Marine Geology, 272 (1-4). pp. 141-153.

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Publication Date: 2013-06-10

Description: New high-resolution swath bathymetry data show a complex seafloor morphology from the Rock Garden area, offshore Hikurangi Margin, that coincides with the subduction of a seamount presently located beneath the summit of Rock Garden. Another ridge-shaped lower plate feature is initially colliding with Rock Garden, forming a re-entrant at its seaward flank. The slopes of the accretionary ridges are steeper than 10° and often more than 20° regionally. Slumping mostly occurs on the trench-ward slopes, with individual slumps affecting areas up to several km2. Critical taper analysis, using realistic wedge geometries and fluid pressures scenarios, shows that much of the seaward slopes in the region are most likely outside the stability field and therefore subject to failure. The most prominent feature revealed by seafloor maps is the trench-ward flank of Rock Garden with a height of 1800 to 2000 m and an average slope of more than 10°. Extensional faults arranged in two sub-circular arcs indicate that Rock Garden may be on the verge of failure. Critical taper analysis also supports this claim and shows that if basal fluid pressure approaches lithostatic pressure, e.g. during a large Mw 〉 8 earthquakes, then a complete failure of the entire trench-ward flank of Rock Garden would potentially affect an area as large as 150 km2 and a rock volume of 150 to 170 km3. This worst case scenario would generate a tsunami wave some tens of meters high. Therefore, the observation that a number of seamounts are buried beneath the outer Hikurangi accretionary wedge suggests that a thorough assessment of these features needs to be undertaken and its results incorporated into tsunami hazard models for the East Coast of New Zealand's North Island.

Type: Article , PeerReviewed

Format: text

DOI: 10.1016/j.margeo.2009.06.004

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Crustal erosion and accretion processes leading to forearc uplift of Raukumara Basin, Hikurangi-Kermadec subduction zone, northeastern New Zealand (2008)

Sutherland, Rupert ; Stagpoole, Vaughan ; Uruski, Chris ; [et al.]

In: [Poster] In: AGU Fall Meeting, 15.-19.12, San Francisco, USA .

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Publication Date: 2012-07-06

Type: Conference or Workshop Item , NonPeerReviewed

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Crustal structure of the Kermadec arc from MANGO seismic refraction profiles (2016)

Bassett, Dan ; Kopp, Heidrun ; Sutherland, Rupert ; [et al.]

AGU (American Geophysical Union) | Wiley

In: Journal of Geophysical Research: Solid Earth, 121 (10). 7514-7546 .

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Publication Date: 2019-04-04

Description: Three active-source seismic refraction profiles are integrated with morphological and potential field data to place the first regional constraints on the structure of the Kermadec subduction zone. These observations are used to test contrasting tectonic models for an along-strike transition in margin structure previously known as the 32°S boundary. We use residual bathymetry to constrain the geometry of this boundary and propose the name Central Kermadec Discontinuity (CKD). North of the CKD, the buried Tonga Ridge occupies the forearc with VP 6.5–7.3 km s-1 and residual free-air gravity anomalies constrain its latitudinal extent (north of 30.5°S), width (110 ± 20 km) and strike (~005° south of 25°S). South of the CKD the forearc is structurally homogeneous down-dip with VP 5.7–7.3 km s-1. In the Havre Trough backarc, crustal thickness south of the CKD is 8-9 km, which is up-to 4 km thinner than the northern Havre Trough and at least 1 km thinner than the southern Havre Trough. We suggest that the Eocene arc did not extend along the current length of the Tonga-Kermadec trench. The Eocene arc was originally connected to the Three Kings Ridge and the CKD was likely formed during separation and easterly translation of an Eocene arc substrate during the early Oligocene. We suggest that the first-order crustal thickness variations along the Kermadec arc were inherited from before the Neogene and reflect Mesozoic crustal structure, the Cenozoic evolution of the Tonga-Kermadec-Hikurangi margin and along-strike variations in the duration of arc volcanism.

Type: Article , PeerReviewed

Format: text

DOI: 10.1002/2016JB013194

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Geophysical imaging of the fore-arc deformation at the northern Hikurangi margin, New Zealand (2009)

Scherwath, Martin ; Kopp, Heidrun ; Flueh, Ernst R. ; [et al.]

In: [Talk] In: Jahrestagung der Deutschen Geophysikalischen Gesellschaft (DGG), 26.03, Kiel .

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Publication Date: 2012-02-23

Type: Conference or Workshop Item , NonPeerReviewed

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An Update on Recent Gas Hydrate Research Activity in New Zealand (2013)

Crutchley, Gareth ; Barnes, Philip ; Bialas, Jörg ; [et al.]

In: [Talk] In: AOGS 2013 : Asia Oceania Geosciences Society Annual Meeting, 24.-28.06.2013, Brisbane, Australia .

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Publication Date: 2016-01-19

Description: Recent years have seen a steady increase in gas hydrate-related research in New Zealand, driven by several large-scale projects and strong international collaboration. The Hikurangi Margin, east of New Zealand’s North Island, is the country’s premier gas hydrate province. Here, much of the research has been focused on processes surrounding methane seepage out of the sea floor and on geological conditions that are likely to promote the deposition of concentrated hydrate deposits. Studies into submarine erosion and landslides related to gas hydrate systems have also been a major focus in this province. In particular, flattened ridge tops and submarine mass wasting deposits have been investigated that appear to be related to the up-slope termination of gas hydrate stability. Research is also being carried out to characterise animal communities of the seabed where methane seepage occurs, in order to provide ecological risk assessments for drilling activities. Elsewhere on New Zealand’s continental margins research is also accelerating. Several “frontier” basins around New Zealand are currently being explored with respect to their potential for hosting attractive gas hydrate deposits. A primary focus is to identify and characterise key elements of favourable depositional environments, with a longer-term aim of gas hydrate exploration drilling.

Type: Conference or Workshop Item , NonPeerReviewed

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Seismic imaging of gas conduits beneath seafloor seep sites in a shallow marine gas hydrate province, Hikurangi Margin, New Zealand (2010)

Crutchley, Gareth ; Pecher, Ingo A. ; Gorman, Andrew R. ; [et al.]

Elsevier

In: Marine Geology, 272 (1/4). pp. 114-126.

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Publication Date: 2020-07-09

Description: We present recently-acquired high-resolution seismic data and older lower-resolution seismic data from Rock Garden, a shallow marine gas hydrate province on New Zealand's Hikurangi Margin. The seismic data reveal plumbing systems that supply gas to three general sites where seeps have been observed on the Rock Garden seafloor: the ‘LM3’ sites (including LM3 and LM3-A), the ‘Weka’ sites (including Weka-A, Weka-B, and Weka-C), and the ‘Faure’ sites (including Faure-A, Faure-B, and Rock Garden Knoll). At the LM3 sites, seismic data reveal gas migration from beneath the bottom simulating reflection (BSR), through the gas hydrate stability zone (GHSZ), to two separate seafloor seeps (LM3 and LM3-A). Gas migration through the deeper parts of GHSZ below the LM3 seeps appears to be influenced by faulting in the hanging wall of a major thrust fault. Closer to the seafloor, the dominant migration pathways appear to occupy vertical chimneys. At the Weka sites, on the central part of the ridge, seismic data reveal a very shallow BSR. A distinct convergence of the BSR with the seafloor is observed at the exit point of one of the Weka seep locations (Weka-A). Gas supply to this seep is predicted to be focused along the underside of a permeability contrast at the BGHS caused by overlying gas hydrates. The Faure sites are associated with a prominent arcuate slump feature. At Faure-A, high-amplitude reflections, extending from a shallow BSR towards the seafloor, are interpreted as preferred gas migration pathways that exploit relatively-high-permeability sedimentary layers. At Faure-B, we interpret gas migration to be channelled to the seep along the underside of the BGHS — the same scenario interpreted for the Weka-A site. At Rock Garden Knoll, gas occupies shallow sediments within the GHSZ, and is interpreted to migrate up-dip along relatively high-permeability layers to the area of seafloor seepage. We predict that faulting, in response to uplift and flexural extension of the ridge, may be an important mechanism in creating fluid flow conduits that link the reservoir of free gas beneath the BGHS with the shallow accumulations of gas imaged beneath Rock Garden Knoll. From a more regional perspective, much of the gas beneath Rock Garden is focused along a northwest-dipping fabric, probably associated with subduction-related deformation of the margin.

Type: Article , PeerReviewed

Format: text

DOI: 10.1016/j.margeo.2009.03.007

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Focussed fluid flow on the Hikurangi Margin, New Zealand — Evidence from possible local upwarping of the base of gas hydrate stability (2010)

Pecher, Ingo A. ; Henrys, Stuart A. ; Wood, Warren T. ; [et al.]

Elsevier

In: Marine Geology, 272 (1/4). pp. 99-113.

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Publication Date: 2017-08-07

Description: The southern Hikurangi Subduction Margin is characterized by significant accretion with predicted high rates of fluid expulsion. Bottom simulating reflections (BSRs) are widespread on this margin, predominantly occurring beneath thrust ridges. We present seismic data across the Porangahau Ridge on the outer accretionary wedge. The data show high-amplitude reflections above the regional BSR level. Based on polarity and reflection strength, we interpret these reflections as being caused by free gas. We propose that the presence of gas above the regional level of BSRs indicates local upwarping of the base of gas hydrate stability caused by advective heatflow from upward migrating fluids, although we cannot entirely rule out alternative processes. Simplified modelling of the increase of the thermal gradient associated with fluid flow suggests that funnelling of upward migrating fluids beneath low-permeability slope basins into the Porangahau Ridge would not lead to the pronounced thermal anomaly inferred from upwarping of the base of gas hydrate stability. Focussing of fluid flow is predicted to take place deep in the accretionary wedge and/or the underthrust sediments. Above the high-amplitude reflections, sediment reflectivity is low. A lack of lateral continuity of reflections suggests that reflectivity is lost because of a destruction of sediment layering from deformation rather than gas-hydrate-related amplitude blanking. Structural permeability from fracturing of sediments during deformation may facilitate fluid expulsion on the ridge. A gap in the BSR in the southern part of the study area may be caused by a loss of gas during fluid expulsion. We speculate that gaps in otherwise continuous BSRs that are observed beneath some thrusts on the Hikurangi Margin may be characteristic of other locations experiencing focussed fluid expulsion.

Type: Article , PeerReviewed

Format: text

DOI: 10.1016/j.margeo.2009.10.006

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