Terrestrial Laser Scanning of Lava Flows to Constrain Fracture Models in Geothermal Reservoirs; a Case Study from the Taupo Volcanic Zone, New Zealand

Research output: Contribution to conferenceAbstract

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Terrestrial Laser Scanning of Lava Flows to Constrain Fracture Models in Geothermal Reservoirs; a Case Study from the Taupo Volcanic Zone, New Zealand. / Massiot, Cecile; Nicol, A.; McNamara, David et al.
2015. Abstract from AGU Fall Meeting 2015, San Francisco, United States.

Research output: Contribution to conferenceAbstract

Harvard

Massiot, C, Nicol, A, McNamara, D, Garcia-Sélles, D, Archibald, G, Townend, J, Villeneuve, M & Siratovich, PA 2015, 'Terrestrial Laser Scanning of Lava Flows to Constrain Fracture Models in Geothermal Reservoirs; a Case Study from the Taupo Volcanic Zone, New Zealand', AGU Fall Meeting 2015, San Francisco, United States, 13/12/15 - 15/01/16.

APA

Massiot, C., Nicol, A., McNamara, D., Garcia-Sélles, D., Archibald, G., Townend, J., Villeneuve, M., & Siratovich, P. A. (2015). Terrestrial Laser Scanning of Lava Flows to Constrain Fracture Models in Geothermal Reservoirs; a Case Study from the Taupo Volcanic Zone, New Zealand. Abstract from AGU Fall Meeting 2015, San Francisco, United States.

Vancouver

Massiot C, Nicol A, McNamara D, Garcia-Sélles D, Archibald G, Townend J et al.. Terrestrial Laser Scanning of Lava Flows to Constrain Fracture Models in Geothermal Reservoirs; a Case Study from the Taupo Volcanic Zone, New Zealand. 2015. Abstract from AGU Fall Meeting 2015, San Francisco, United States.

Author

Massiot, Cecile ; Nicol, A. ; McNamara, David et al. / Terrestrial Laser Scanning of Lava Flows to Constrain Fracture Models in Geothermal Reservoirs; a Case Study from the Taupo Volcanic Zone, New Zealand. Abstract from AGU Fall Meeting 2015, San Francisco, United States.

Bibtex - Download

@conference{b95d1814a8c446df92a16e76d4984cf9,
title = "Terrestrial Laser Scanning of Lava Flows to Constrain Fracture Models in Geothermal Reservoirs; a Case Study from the Taupo Volcanic Zone, New Zealand",
abstract = "Geothermal reservoirs hosted in volcanic rocks, like the Rotokawa Geothermal Field in the Taupo Volcanic Zone (TVZ), New Zealand, typically contain fracture networks that control fluid flow. Realistic discrete fracture network (DFN) models have the potential to improve geothermal resource management. However, the spatial distribution and geometries of fracture networks are often poorly understood due to limited data and complex deformation histories including lava emplacement, subsequent burial and faulting.To understand better the distribution of fractures formed during lava emplacement, we study andesitic flow exposures from Mt Ruapehu, at the southern end of the TVZ. Terrestrial Laser Scanner (TLS) acquisition on three 50-200 m2 outcrops provided large 3D point clouds of the shape of the outcrop. Delineation of thousands of individual fractures has been semi-automated using local geometrical constraints and a shape detection algorithm detecting planar and curved surfaces. Fracture orientation, length, area, linear (P10) and areal (P20) densities from the TLS data provide input parameters for the DFN models. Fracture detection is validated using high-resolution panoramic photographs (GigaPan) and manual scanline measurements. Cooling joints are highly connected via sub-horizontal joints that are aligned with vesicular layers. UCS tests show a mechanical anisotropy between vertical and horizontal samples. Most of the cooling joints terminate within or at the brecciated margins of individual flows which contrast mechanically with the massive flow interior. Thus, highly connected and curved fractures are mostly confined to lava flows.This study provides a framework for developing DFNs for geothermal reservoirs hosted in andesitic flows based on empirical observations of intrinsic fracturing and mechanical anisotropies of the host lithology. Fractures in individual lava flows may be interconnected in the reservoir by a combination of cooling joints, subsequent tectonic fault zones and hydrothermal fractures. The combination of TLS, Gigapan and manual scanlines is widely applicable to constraining DFNs other geological settings.",
author = "Cecile Massiot and A. Nicol and David McNamara and David Garcia-S{\'e}lles and Garth Archibald and John Townend and Marlene Villeneuve and Siratovich, {P. A.}",
year = "2015",
language = "English",
note = "AGU Fall Meeting 2015 ; Conference date: 13-12-2015 Through 15-01-2016",

}

RIS (suitable for import to EndNote) - Download

TY - CONF

T1 - Terrestrial Laser Scanning of Lava Flows to Constrain Fracture Models in Geothermal Reservoirs; a Case Study from the Taupo Volcanic Zone, New Zealand

AU - Massiot, Cecile

AU - Nicol, A.

AU - McNamara, David

AU - Garcia-Sélles, David

AU - Archibald, Garth

AU - Townend, John

AU - Villeneuve, Marlene

AU - Siratovich, P. A.

PY - 2015

Y1 - 2015

N2 - Geothermal reservoirs hosted in volcanic rocks, like the Rotokawa Geothermal Field in the Taupo Volcanic Zone (TVZ), New Zealand, typically contain fracture networks that control fluid flow. Realistic discrete fracture network (DFN) models have the potential to improve geothermal resource management. However, the spatial distribution and geometries of fracture networks are often poorly understood due to limited data and complex deformation histories including lava emplacement, subsequent burial and faulting.To understand better the distribution of fractures formed during lava emplacement, we study andesitic flow exposures from Mt Ruapehu, at the southern end of the TVZ. Terrestrial Laser Scanner (TLS) acquisition on three 50-200 m2 outcrops provided large 3D point clouds of the shape of the outcrop. Delineation of thousands of individual fractures has been semi-automated using local geometrical constraints and a shape detection algorithm detecting planar and curved surfaces. Fracture orientation, length, area, linear (P10) and areal (P20) densities from the TLS data provide input parameters for the DFN models. Fracture detection is validated using high-resolution panoramic photographs (GigaPan) and manual scanline measurements. Cooling joints are highly connected via sub-horizontal joints that are aligned with vesicular layers. UCS tests show a mechanical anisotropy between vertical and horizontal samples. Most of the cooling joints terminate within or at the brecciated margins of individual flows which contrast mechanically with the massive flow interior. Thus, highly connected and curved fractures are mostly confined to lava flows.This study provides a framework for developing DFNs for geothermal reservoirs hosted in andesitic flows based on empirical observations of intrinsic fracturing and mechanical anisotropies of the host lithology. Fractures in individual lava flows may be interconnected in the reservoir by a combination of cooling joints, subsequent tectonic fault zones and hydrothermal fractures. The combination of TLS, Gigapan and manual scanlines is widely applicable to constraining DFNs other geological settings.

AB - Geothermal reservoirs hosted in volcanic rocks, like the Rotokawa Geothermal Field in the Taupo Volcanic Zone (TVZ), New Zealand, typically contain fracture networks that control fluid flow. Realistic discrete fracture network (DFN) models have the potential to improve geothermal resource management. However, the spatial distribution and geometries of fracture networks are often poorly understood due to limited data and complex deformation histories including lava emplacement, subsequent burial and faulting.To understand better the distribution of fractures formed during lava emplacement, we study andesitic flow exposures from Mt Ruapehu, at the southern end of the TVZ. Terrestrial Laser Scanner (TLS) acquisition on three 50-200 m2 outcrops provided large 3D point clouds of the shape of the outcrop. Delineation of thousands of individual fractures has been semi-automated using local geometrical constraints and a shape detection algorithm detecting planar and curved surfaces. Fracture orientation, length, area, linear (P10) and areal (P20) densities from the TLS data provide input parameters for the DFN models. Fracture detection is validated using high-resolution panoramic photographs (GigaPan) and manual scanline measurements. Cooling joints are highly connected via sub-horizontal joints that are aligned with vesicular layers. UCS tests show a mechanical anisotropy between vertical and horizontal samples. Most of the cooling joints terminate within or at the brecciated margins of individual flows which contrast mechanically with the massive flow interior. Thus, highly connected and curved fractures are mostly confined to lava flows.This study provides a framework for developing DFNs for geothermal reservoirs hosted in andesitic flows based on empirical observations of intrinsic fracturing and mechanical anisotropies of the host lithology. Fractures in individual lava flows may be interconnected in the reservoir by a combination of cooling joints, subsequent tectonic fault zones and hydrothermal fractures. The combination of TLS, Gigapan and manual scanlines is widely applicable to constraining DFNs other geological settings.

M3 - Abstract

T2 - AGU Fall Meeting 2015

Y2 - 13 December 2015 through 15 January 2016

ER -