P. Reid scite author profile

Realization of enhanced geothermal systems (EGSs) prescribes the need for novel methods to monitor subsurface fracture connectivity and fluid distribution. Magnetotellurics (MT) is a passive electromagnetic (EM) method sensitive to electrical conductivity contrasts as a function of depth, specifically hot saline fluids in a resistive porous media. In July 2011, an EGS fluid injection at 3.6-km depth near Paralana, South Australia, was monitored by comparing repeated MT surveys before and after hydraulic stimulation. An observable coherent change above measurement error in the MT response was present and causal, in that variations in phase predict variations in apparent resistivity. Phase tensor residuals proved the most useful representation for characterizing alterations in subsurface resistivity structure, whereas resistivity tensor residuals aided in determining the sign and amplitude of resistivity variations. These two tensor representations of the residual MT response suggested fluids migrated toward the northeast of the injection well along an existing fault system trending north-northeast. Forward modeling and concurrent microseismic data support these results, although microseismic data suggest fractures opened along two existing fracture networks trending north-northeast and northeast. This exemplifies the need to use EM methods for monitoring fluid injections due to their sensitivity to conductivity contrasts.

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Magnetotelluric monitoring of a fluid injection: Example from an enhanced geothermal system

Peacock

Thiel

Reid³

et al. 2012

Geophysical Research Letters

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Enhanced geothermal systems (EGS) are on the verge of becoming commercially viable for power production, where advancements in subsurface characterization are imperative to develop EGS into a competitive industry. Theory of an EGS is simple, pump fluids into thermally enhanced lithology and extract the hot fluids to produce energy. One significant complication in EGS development is estimating where injected fluids flow in the subsurface. Micro‐seismic surveys can provide information about where fractures opened, but not fracture connectivity nor fluid inclusion. Electromagnetic methods are sensitive to conductivity contrasts and can be used as a supplementary tool to delineate reservoir boundaries. In July, 2011, an injection test for a 3.6 km deep EGS at Paralana, South Australia was continuously monitored by both micro‐seismic and magnetotellurics (MT). Presented are the first results from continuous MT measurements suggesting transient variations in subsurface conductivity structure generated from the introduction of fluids at depth can be measured. Furthermore, phase tensor representation of the time dependent MT response suggests fluids migrated in a NE direction from the injection well. Results from this experiment supports the extension of MT to a monitoring tool for not only EGS but other hydraulic stimulations.

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Hot Dry Rock Geothermal Exploration in Australia

Hillis

Hand

Mildren³

et al. 2004

ASEG Extended Abstracts

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The Importance of Coupling Passive and Active Seismic Methods in Geothermal Fields - A Case Study at Paralana, Australia

Albaric¹,

Langet²,

Hasting³

et al. 2012

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Fracture delineation and monitoring of geothermal and coal seam gas areas using magnetotellurics

Thiel

Peacock

Heinson

et al. 2012

ASEG Extended Abstracts

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Induced Seismicity Patterns in the Paralana Geothermal Reservoir, South Australia

Albaric¹,

Øye²,

Hasting³

et al. 2013

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We are presenting the results of the analysis of seismicity induced by the first main stimulation of the geothermal reservoir at Paralana (south Australia) in July 2011. More than 7000 events were detected and processed automatically. A 3D velocity model was built from active seismic data and used to locate the events. Well-located microearthquakes were relocated using differential travel-times improved by waveform cross-correlation. Focal mechanisms of the four largest events (two Mw 2.4 and one 2.5) are all in thrust with a strike-slip component, consistent with the stress regime in the area.

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Progress towards magnetotelluric time lapse monitoring of enhanced geothermal system fluids

Li¹,

Li²,

Meng³

et al. 2011

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P. Reid

Monitoring of induced seismicity during the first geothermal reservoir stimulation at Paralana, Australia

Time-lapse magnetotelluric monitoring of an enhanced geothermal system

Magnetotelluric monitoring of a fluid injection: Example from an enhanced geothermal system

Hot Dry Rock Geothermal Exploration in Australia

The Importance of Coupling Passive and Active Seismic Methods in Geothermal Fields - A Case Study at Paralana, Australia

Fracture delineation and monitoring of geothermal and coal seam gas areas using magnetotellurics

Induced Seismicity Patterns in the Paralana Geothermal Reservoir, South Australia

Progress towards magnetotelluric time lapse monitoring of enhanced geothermal system fluids

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