Late Paleocene pipe swarm in the Great South – Canterbury Basin (New Zealand)

Bertoni, Claudia; Gan, Yuqian; Paganoni, M.; Mayer, J. J.; Cartwright, Joe; Martin, Joe; Rensbergen, P. Van; Wunderlich, Alexander; Clare, Alan

doi:10.1016/j.marpetgeo.2019.05.039

Cited by 10 publications

(7 citation statements)

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“…A significant fall in sea level is inferred to have occurred at around this time, namely the Th2 event of Hardenbol et al (1998) and the Pa2b event of Kominz et al (2008). Harris et al (2010) argue that this event corresponds to a glacioeustatic fall in sea level of ∼ 15 m. This fall in sea level has also been linked to a large system of fluid escape pipes discovered in late Paleocene sediments offshore eastern New Zealand (Bertoni et al, 2019).…”

Section: Discussionmentioning

confidence: 99%

Late Paleocene CO<sub>2</sub> drawdown, climatic cooling and terrestrial denudation in the southwest Pacific

et al. 2022

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Abstract. Late Paleocene deposition of an organic-rich sedimentary facies on the continental shelf and slope of New Zealand and eastern Australia has been linked to short-lived climatic cooling and terrestrial denudation following sea level fall. Recent studies confirm that the organic matter in this facies, termed “Waipawa organofacies”, is primarily of terrestrial origin, with a minor marine component. It is also unusually enriched in 13C. In this study we address the cause of this enrichment. For Waipawa organofacies and its bounding facies in the Taylor White section, Hawke's Bay, paired palynofacies and carbon isotope analysis of heavy liquid-separated density fractions indicate that the heaviest δ13C values are associated with degraded phytoclasts (woody plant matter) and that the 13C enrichment may be partly due to lignin degradation. Compound-specific stable carbon isotope analyses of samples from the Taylor White and mid-Waipara (Canterbury) sections display similar trends and further reveal a residual 13C enrichment of ∼ 2.5 ‰ in higher plant biomarkers (long chain n-alkanes and fatty acids) and a ∼ 2 ‰–5 ‰ change in subordinate marine biomarkers. Using the relationship between atmospheric CO2 and C3 plant tissue δ13C values, we determine that the 3 ‰ increase in terrestrial δ13C may represent a ∼ 35 % decrease in atmospheric CO2. Refined age control for Waipawa organofacies indicates that deposition occurred between 59.2 and 58.5 Ma, which coincides with an interval of carbonate dissolution in the deep sea that is associated with a Paleocene oxygen isotope maximum (POIM, 59.7–58.1 Ma) and the onset of the Paleocene carbon isotope maximum (PCIM, 59.3–57.4 Ma). This association suggests that Waipawa deposition occurred during a time of cool climatic conditions and increased carbon burial. This relationship is further supported by published TEX86-based sea surface temperatures that indicate a pronounced regional cooling during deposition. We suggest that reduced greenhouse gas emissions from volcanism and accelerated carbon burial, due to tectonic factors, resulted in short-lived global cooling, growth of ephemeral ice sheets and a global fall in sea level. Accompanying erosion and carbonate dissolution in deep-sea sediment archives may have hidden the evidence of this “hypothermal” event until now.

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Section: Discussionmentioning

confidence: 99%

Late Paleocene CO<sub>2</sub> drawdown, climatic cooling and terrestrial denudation in the southwest Pacific

et al. 2022

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“…The seismic data are zero‐phase processed and are displayed with the Society of Exploration Geophysicists (SEG) standard polarity, whereby a downward increase in acoustic impedance (a function of rock velocity and density) corresponds to a positive reflection event (red on seismic profiles) (Brown, 2011). Bertoni et al (2019) report that the vertical resolution of the seismic data is ca. 10 m in the shallow subseafloor between ca.…”

Section: Methodsmentioning

confidence: 99%

“…Horizon K50 represents the end of rifting, with horizons K100, T10 and T70 marking the tops of the Cretaceous, Palaeocene and Eocene successions respectively. Mapped horizons, except for H1 and H2, were assigned an age based on previously reported biostratigraphic data from 14 offshore wells (Bertoni et al, 2018, 2019; Blanke, 2015; Hunt International Petroleum Co. NZ, 1977a, 1977b, 1977c, 1978a, 1978b, 1978c; Placid Oil Company, 1984a, 1984b; Sahoo et al, 2022; Schiøler & Raine, 2009; Schiøler et al, 2011, 2012, 2017) (Figure 2). The ages of Horizon H1 and H2 were estimated from the strata thickness to the upper and lower adjacent horizons (e.g.…”

Section: Methodsmentioning

confidence: 99%

Reutilization of fluid flow pathways over 54 million years, offshore New Zealand

2023

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Structures that facilitate fluid migration are common in sedimentary basins. We document several possible hydrothermal and/or volcanic vents located above a >157 km2, late Cretaceous volcanic field in the Great South Basin, offshore New Zealand. Three of the four vents are vertically stacked, suggesting episodic re‐use of the same fluid pathway between ca. 75 and 56 Ma. A palaeo‐pockmark dated to ca. 49 Ma and free gas occurring within strata ca. 21 Myr old are located directly above these stacked vents. The spatial association of the vents, pockmark and free gas further suggests re‐use of the fluid migration pathway(s) extended for over 54 Myr. Our results imply that reutilization of fluid flow pathways can affect the distribution of fluids within basins over prolonged periods, potentially impacting hydrocarbon/geothermal exploration and geohazard assessment.

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“…Widespread deposition of deep marine mudstones and siltstones occurred across the majority of the Great South and Canterbury Basins during the Cenozoic, with some carbonate deposition in the Oligocene-Miocene (Fig. 1b) (Bertoni et al, 2019;Chenrai and Huuse, 2020;Morley et al, 2017). The Marshall Paraconformity forms the Oligocene-Eocene boundary across the area and is purported to be related to the onset of the Antarctic circumpolar current (Fulthorpe et al, 1996;Morley et al, 2017).…”

Section: Regional Geological Evolutionmentioning

confidence: 99%

Structural controls on the location, geometry and longevity of an intraplate volcanic system: the Tuatara Volcanic Field, Great South Basin, New Zealand

Phillips

Magee

2020

JGS

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Intraplate volcanism is widely distributed across the continents, but the controls on the 3D geometry and longevity of individual volcanic systems remain poorly understood. Geophysical data provide insights into magma plumbing systems, but, as a result of the relatively low resolution of these techniques, it is difficult to evaluate how magma transits highly heterogeneous continental interiors. We use borehole-constrained 2D seismic reflection data to characterize the 3D geometry of the Tuatara Volcanic Field located offshore New Zealand's South Island and investigate its relationship with the pre-existing structure. This c. 270 km2 field is dominated by a dome-shaped lava edifice, surrounded and overlain by c. 69 volcanoes and >70 sills emplaced over 40 myr from the Late Cretaceous to Early Eocene (c. 85–45 Ma). The Tuatara Volcanic Field is located above a basement terrane boundary represented by the Livingstone Fault; the recently active Auckland Volcanic Field is similarly located along-strike on North Island. We suggest that the Livingstone Fault controlled the location of the Tuatara Volcanic Field by producing relief at the base of the lithosphere, thereby focussing lithospheric detachment over c. 40 myr, and provided a pathway that facilitated the ascent of magma. We highlight how observations from ancient intraplate volcanic systems may inform our understanding of active intraplate volcanic systems, including the Auckland Volcanic Field.Supplementary material: Interpreted seismic section showing well control on stratigraphic interpretation is available at https://doi.org/10.6084/m9.figshare.c.5004464

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Late Paleocene pipe swarm in the Great South – Canterbury Basin (New Zealand)

Cited by 10 publications

References 100 publications

Late Paleocene CO<sub>2</sub> drawdown, climatic cooling and terrestrial denudation in the southwest Pacific

Late Paleocene CO<sub>2</sub> drawdown, climatic cooling and terrestrial denudation in the southwest Pacific

Reutilization of fluid flow pathways over 54 million years, offshore New Zealand

Structural controls on the location, geometry and longevity of an intraplate volcanic system: the Tuatara Volcanic Field, Great South Basin, New Zealand

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Late Paleocene pipe swarm in the Great South – Canterbury Basin (New Zealand)

Cited by 10 publications

References 100 publications

Late Paleocene CO&lt;sub&gt;2&lt;/sub&gt; drawdown, climatic cooling and terrestrial denudation in the southwest Pacific

Late Paleocene CO&lt;sub&gt;2&lt;/sub&gt; drawdown, climatic cooling and terrestrial denudation in the southwest Pacific

Reutilization of fluid flow pathways over 54 million years, offshore New Zealand

Structural controls on the location, geometry and longevity of an intraplate volcanic system: the Tuatara Volcanic Field, Great South Basin, New Zealand

Contact Info

Product

Resources

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Late Paleocene CO<sub>2</sub> drawdown, climatic cooling and terrestrial denudation in the southwest Pacific

Late Paleocene CO<sub>2</sub> drawdown, climatic cooling and terrestrial denudation in the southwest Pacific