Weibull-distributed dyke thickness reflects probabilistic character of host-rock strength

Krumbholz, Michael; Hieronymus, Christoph F.; Burchardt, Steffi; Troll, Valentin R.; Tanner, David C.; Friese, Nadine

doi:10.1038/ncomms4272

Cited by 53 publications

(51 citation statements)

References 44 publications

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“…The thickness histogram exhibits an asymmetric thickness distribution with a peak near ca.18 m and a skewed distribution towards the thicker sills. Such distribution is typical of a Weibull distribution, which has been demonstrated to describe the thickness distribution of igneous dykes (Krumbholz et al, ).…”

Section: Resultsmentioning

confidence: 93%

Low resistivity zones at contacts of igneous intrusions emplaced in organic‐rich formations and their implications on fluid flow and petroleum systems: A case study in the northern Neuquén Basin, Argentina

Spacapan¹,

́Odorico²,

Palma³

et al. 2019

Basin Research

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Igneous sills and laccoliths emplaced in sedimentary basins may significantly impact petroleum systems, both positively and negatively. Igneous intrusions provide heat to maturate regionally immature organic-rich host rocks, act as fractured reservoirs hosting commercial accumulations of hydrocarbons, and form structures affecting fluid flow and trapping at different scales. Nevertheless, the petrophysical implications of igneous intrusions on their host rock are poorly known. In this study, we analyse 200 wells in the Río Grande Valley oil field, Neuquén basin, Argentina, where the main reservoirs are in fractured igneous sills. This dataset represents a globally unique possibility to characterize the igneous-host rock interaction using both wireline logs and core material. We identify a systematic Contact Low Resistivity Zone (CLRsZ) at both the upper and lower contacts of the sills emplaced in the organicrich Vaca Muerta and Agrio Formations. We characterize the nature of these CLRsZ and their petrophysical properties by integrating resistivity and gamma ray well logs, petrographic analyses, petrophysical tests and geochemical analyses. The low resistivity signal of the CLRsZ is dominantly carried by massive-sulphide deposits, mainly pyrite, observed both in the host rock and the chilled margin of the sills. Well log images and porosity-permeability analysis on core plugs show that both the sills and their associated CLRsZ can act as carrier for fluid flow and reservoir for hydrocarbons storage. The thickness of the upper and lower CLRsZ correlates linearly with the thickness of the sill, and the volume of both the upper and lower CLRsZ represents ca. 40% with respect to the volume of their associated sill. The thickness of the CLRsZ represents ca. 13% of the thickness of contact aureole induced by the sills. In the CLRsZ, a great proportion of kerogen was transformed to hydrocarbon, so that CLRsZ were restricted to the innermost contact aureole of the sills. Our results show that the CLRsZ can have major implications on fluid flow and should be considered in reservoir models in volcanic basins hosting sills emplaced in organic-rich formations. 4 | EAGE SPACAPAN et Al.

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Section: Resultsmentioning

confidence: 93%

Low resistivity zones at contacts of igneous intrusions emplaced in organic‐rich formations and their implications on fluid flow and petroleum systems: A case study in the northern Neuquén Basin, Argentina

Spacapan¹,

́Odorico²,

Palma³

et al. 2019

Basin Research

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“…Field observations in extinct and exhumed volcanic areas worldwide have identified different geometries of sheet intrusions, among which (i) vertical dikes [e.g., Pollard , ; Lister and Kerr , ; Rubin , ; Ancochea et al ., ; Geshi , ; Paquet et al ., ], (ii) inclined cone sheets [ Harker and Clough , ; Bailey , ; Ancochea et al ., ; Burchardt et al ., ], and (iii) horizontal sills [e.g., Kavanagh et al ., ; Burchardt , ; Galland et al ., ] represent the main types (Figure ). It is interesting to notice that although the shapes of these distinct sheet intrusions are rather different, they are found together in the same volcanic systems (Figure ) [ Walker , ; Geshi , ; Paquet et al ., ] and their thicknesses follow the same statistical distribution indicating a related emplacement dynamics [ Krumbholz et al ., ]. The spatial association and the close temporal relations between cone sheets and dikes led Walker [] to propose that they may be fed by a common source [see also Geshi , ].…”

Section: Introductionmentioning

confidence: 99%

Dynamics of dikes versus cone sheets in volcanic systems

et al. 2014

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Igneous sheet intrusions of various shapes, such as dikes and cone sheets, coexist as parts of complex volcanic plumbing systems likely fed by common sources. How they form is fundamental regarding volcanic hazards, yet no dynamic model simulates and predicts satisfactorily their diversity. Here we present scaled laboratory experiments that reproduced dikes and cone sheets under controlled conditions. Our models show that their formation is governed by a dimensionless ratio (Π 1 ), which describes the geometry of the magma source, and a dynamic dimensionless ratio (Π 2 ), which compares the viscous stresses in the flowing magma to the host rock strength. Plotting our experiments against these two numbers results in a phase diagram evidencing a dike and a cone sheet field, separated by a sharp transition that fits a power law. This result shows that dikes and cone sheets correspond to distinct physical regimes of magma emplacement in the crust. For a given host rock strength, cone sheets preferentially form when the source is shallow, relative to its lateral extent, or when the magma influx velocity (or viscosity) is high. Conversely, dikes form when the source is deep compared to its size, or when magma influx rate (or viscosity) is low. Both dikes and cone sheets may form from the same source, the shift from one regime to the other being then controlled by magma dynamics, i.e., different values of Π 2 . The extrapolated empirical dike-to-cone sheet transition is in good agreement with the occurrence of dikes and cone sheets in various natural volcanic settings.

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“…While (sub)recent microcrack orientations are commonly consistent over large volumes (e.g. Vollbrecht et al 1994;Krumbholz et al 2014a) and therefore predictable, larger fractures have usually a more complex history and thus exhibit more variable systematics. A direct implication is that the strength of the rocks is also scale dependent (Krumbholz et al 2014b).…”

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confidence: 99%

Predictability of properties of a fractured geothermal reservoir: the opportunities and limitations of an outcrop analogue study

et al. 2017

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Weibull-distributed dyke thickness reflects probabilistic character of host-rock strength

Cited by 53 publications

References 44 publications

Low resistivity zones at contacts of igneous intrusions emplaced in organic‐rich formations and their implications on fluid flow and petroleum systems: A case study in the northern Neuquén Basin, Argentina

Low resistivity zones at contacts of igneous intrusions emplaced in organic‐rich formations and their implications on fluid flow and petroleum systems: A case study in the northern Neuquén Basin, Argentina

Dynamics of dikes versus cone sheets in volcanic systems

Predictability of properties of a fractured geothermal reservoir: the opportunities and limitations of an outcrop analogue study

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