Geological controls on fault relay zone scaling

Long, J. J.; Imber, Jonathan B.

doi:10.1016/j.jsg.2011.09.011

Cited by 81 publications

(44 citation statements)

References 43 publications

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“…Peacock and Sanderson 1994;Trudgill and Cartwright 1994;Peacock and Sanderson 1995;Long and Imber 2011), and in general interaction zones of faults, are potential sites of hydrothermal fluid flow because they are characterized by high stress, which increases the local fracturing and permeability (Curewitz and Karson 1997;Ferrill and Morris 2001;Rotevatn et al 2007). The EGF coincides with the breached relay ramp of the SVFS (Figs 2C and 2D).…”

Section: Structural Constraints On the Euganean Thermal Water Circulamentioning

confidence: 99%

Conceptual and numerical models of a tectonically-controlled geothermal system: a case study of the Euganean Geothermal System, Northern Italy

Pola¹,

Fabbri²,

Piccinini³

et al. 2015

Central European Geology

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The Euganean Geothermal Field (EGF) is the most important thermal field in northern Italy. It is located in the alluvial plain of the Veneto Region where approximately 17*10 6 m 3 of thermal water with temperatures of 60-86 °C are exploited annually. A regional-scale conceptual model of the Euganean Geothermal System is proposed in this paper using the available hydrogeologic, geochemical and structural data for both the EGF and central Veneto. The thermal water is of meteoric origin and infiltrates approximately 80 km to the north of the EGF in the Veneto Prealps. The water flows to the south in a Mesozoic limestone and dolomite reservoir reaching a depth of approximately 3,000 m and a temperature of approximately 100 °C due to the normal geothermal gradient. The regional Schio-Vicenza fault system and its highly permeable damage zone act as a preferential path for fluid migration in the subsurface. In the EGF area, a geologic structure formed by the interaction of different segments of the fault system increases the local fracturing and the permeability favoring the upwelling of the thermal waters. Numerical simulations are performed to validate the proposed conceptual model using a finite difference code that simulates thermal energy transport in hydrothermal systems. A specific configuration of thermal conductivity and permeability for the formations involved in the thermal system is obtained after calibration of these parameters. This set of parameters is verified in a long-term simulation (55,100 years) obtaining a 60-70 °C plume in the EGF area. The modeled temperatures approach the measured temperatures of 60-86 °C, demonstrating that this conceptual model can be realistically simulated.

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Section: Structural Constraints On the Euganean Thermal Water Circulamentioning

confidence: 99%

Conceptual and numerical models of a tectonically-controlled geothermal system: a case study of the Euganean Geothermal System, Northern Italy

Pola¹,

Fabbri²,

Piccinini³

et al. 2015

Central European Geology

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“…For instance, worldwide catalogues of relay zone geometry have demonstrated a power-law scaling relationship that covers approximately 8 orders of magnitude (e.g. Peacock, 2003;Long and Imber, 2011). Evidence for heave gradients and locally non-coaxial strains are described on a separation scale of tens of kilometres in the East African Rift (e.g.…”

Section: Rift-zone-parallel Extension Associated With Normal Fault Anmentioning

confidence: 99%

“…Normal faults comprise multiple discontinuous, non-collinear segments, with overlaps and segment linkage forming characteristic stepping geometries on a broad range of scales (e.g. Cartwright et al, 1996;Peacock et al, 2000;Acocella et al, 2005;Long and Imber, 2011;Henstra et al, 2015). Fault growth models have been derived using natural examples and numerical, or scaled-analogue modelling techniques, in which normal faults grow through stages in which discontinuous segments interact and link across relay zones to form composite structures with fault displacement deficits initially accommodated by soft-linkage rotation and/or material folding (e.g.…”

Section: Introductionmentioning

confidence: 99%

“…Segmentation is a feature common to all scales of faults and fault development (e.g. Walsh et al, 2003;Long and Imber, 2011) and the conservation of regional strain across networks of discontinuous segments has…”

Section: Introductionmentioning

confidence: 99%

“…Peacock andSanderson, 1991, 1994;Childs et al, 1995;Long and Imber, 2010), and depending on the degree of overlap and separation of individual segments, may lead to different styles of deformation (e.g. Tentler and Acocella, 2010;Long and Imber, 2011;Childs et al, 2017) ( Fig. 1a, b).…”

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confidence: 99%

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Extension parallel to the rift zone during segmented fault growth: application to the evolution of the NE Atlantic

et al. 2017

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Abstract. The mechanical interaction of propagating normal faults is known to influence the linkage geometry of firstorder faults, and the development of second-order faults and fractures, which transfer displacement within relay zones. Here we use natural examples of growth faults from two active volcanic rift zones (Koa'e, island of Hawai'i, and Krafla, northern Iceland) to illustrate the importance of horizontalplane extension (heave) gradients, and associated vertical axis rotations, in evolving continental rift systems. Secondorder extension and extensional-shear faults within the relay zones variably resolve components of regional extension, and components of extension and/or shortening parallel to the rift zone, to accommodate the inherently three-dimensional (3-D) strains associated with relay zone development and rotation. Such a configuration involves volume increase, which is accommodated at the surface by open fractures; in the subsurface this may be accommodated by veins or dikes oriented obliquely and normal to the rift axis. To consider the scalability of the effects of relay zone rotations, we compare the geometry and kinematics of fault and fracture sets in the Koa'e and Krafla rift zones with data from exhumed contemporaneous fault and dike systems developed within a > 5 × 10 4 km 2 relay system that developed during formation of the NE Atlantic margins. Based on the findings presented here we propose a new conceptual model for the evolution of segmented continental rift basins on the NE Atlantic margins.

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2012

Crustal Permeability

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A simple predictive model of quartz solubility in water-salt-C02 systems at temperatures up to 1000 ∘ C and pressures up to 1000 MPa. Geochimica Cosmochimica Acta, 76, 1597-1608. Allen DM, Grasby SE, Voormeij DA (2006) Determining the circulation depth of thermal springs in the southern Rocky Mountain Trench, southeastern British Columbia, Canada using geothermometry and borehole temperature logs.

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Geological controls on fault relay zone scaling

Cited by 81 publications

References 43 publications

Conceptual and numerical models of a tectonically-controlled geothermal system: a case study of the Euganean Geothermal System, Northern Italy

Conceptual and numerical models of a tectonically-controlled geothermal system: a case study of the Euganean Geothermal System, Northern Italy

Extension parallel to the rift zone during segmented fault growth: application to the evolution of the NE Atlantic

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