The Iceland Deep Drilling Project 4.5 km deep well, IDDP-2, in the seawater-recharged Reykjanes geothermal field in SW Iceland has successfully reached its supercritical target

Friðleifsson, G. Ó.; Elders, W. A.; Zierenberg, Robert A.; Stefánsson, A.; Fowler, Andrew; Weisenberger, Tobias B.; Harðarson, Björn S.; Mesfin, Kiflom G.

doi:10.5194/sd-23-1-2017

Cited by 70 publications

(54 citation statements)

References 17 publications

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“…Recent compilations of deep crustal permeability measurements (Achtziger‐Zupančič et al, ; Ingebritsen & Gleeson, ) clearly show that the permeability‐depth profiles of tectonically quiescent and active regions are markedly different with much larger permeability in active regions. Besides, in situ measurements of permeability in volcanic systems from drilling projects (Fridhleifsson et al, ; Ikeda et al, ; Reinsch et al, ) and lab experiments also suggest nonnegligible permeability even at temperatures higher than the brittle‐ductile transition (∼>500 °C; Watanabe, Numakura, et al ; Watanabe, Egawa, et al ).…”

Section: Transient Permeabilitymentioning

confidence: 99%

Volatile Degassing From Magma Chambers as a Control on Volcanic Eruptions

Mittal

Richards

2019

JGR Solid Earth

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The loss of volatiles from a magma reservoir affects the magmatic overpressure responsible for driving ground deformation and eruptions. Although the high‐temperature metamorphic aureole around a magma chamber is typically considered to have low permeability, recent theoretical, experimental, and field studies have highlighted the role of transient permeability in magmatic systems. Also, direct measurements suggest that passive degassing is a significant component of total volatile loss in both basaltic and silicic volcanoes. Consequently, the effective permeability of the crust when magma is present in the system can be many orders of magnitude larger than that of exhumed rock samples. We develop a fully coupled porothermoelastic framework to account for both the flow of volatiles as well as associated effects on the stress state of the crust and calculate an analytical solution for spherical geometry. We then combine a magma chamber box model with these solutions to analyze eruption dynamics in magmatic systems. We find that in addition to viscous relaxation, magma recharge, and cooling timescales, the pore pressure diffusion timescale exerts a first‐order control on volcanic eruptions with moderately high crustal permeabilities of order 10−17 to 10−19 m2. We describe a parameter space to identify which components dominate in different regimes for volcanic eruptions according to these different timescales.

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Section: Transient Permeabilitymentioning

confidence: 99%

Volatile Degassing From Magma Chambers as a Control on Volcanic Eruptions

Mittal

Richards

2019

JGR Solid Earth

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“…As mentioned above, no silicic rocks are found on the Reykjanes peninsula west of Hengill. The only occurrences are a basalt andesite intrusion encountered at a depth of around 800 m in well SG-12 in Svartsengi [60] and some felsite veins at the depth of 4634.5 m in IDDP-2 at the tip of the peninsula [61]. This is probably because the Reykjanes peninsula is a thin and young, basically oceanic, crust and different from crust further inland.…”

Section: The Role Of Meltingmentioning

confidence: 99%

New Conceptual Model for the Magma-Hydrothermal-Tectonic System of Krafla, NE Iceland

Árnason

2020

Geosciences

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The complexity of the Krafla volcano and its geothermal system(s) has puzzled geoscientists for decades. New and old geoscientific studies are reviewed in order to shed some light on this complexity. The geological structure and history of the volcano is more complex than hitherto believed. The visible 110 ka caldera hosts, now buried, an 80 ka inner caldera. Both calderas are bisected by an ESE-WNW transverse low-density structure. Resistivity surveys show that geothermal activity has mainly been within the inner caldera but cut through by the ESE-WNW structure. The complexity of the geothermal system in the main drill field can be understood by considering the tectonic history. Isotope composition of the thermal fluids strongly suggests at least three different geothermal systems. Silicic magma encountered in wells K-39 and IDDP-1 indicates a hitherto overlooked heat transport mechanism in evolved volcanos. Basaltic intrusions into subsided hydrothermally altered basalt melt the hydrated parts, producing a buoyant silicic melt which migrates upwards forming sills at shallow crustal levels which are heat sources for the geothermal system above. This can explain the bimodal behavior of evolved volcanos like Krafla and Askja, with occasional silicic, often phreatic, eruptions but purely basaltic in-between. When substantial amounts of silicic intrusions/magma have accumulated, major basalt intrusion(s) may “ignite” them causing a silicic eruption.

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“…Among these experiments, only the IDDP‐2 well in Reykjanes was able to provide a clear evidence of the occurrence of supercritical fluids. In January 2017 fluids at 426 °C and 34 MPa were reached at 4,500 m depth (Frileifsson et al, ) in Iceland. One of the most recent attempts to tap supercritical fluids took place in Italy at the Larderello‐Travale geothermal field (LTGF) in the framework of the DESCRAMBLE project (Bertani et al, ).…”

Section: Introductionmentioning

confidence: 99%

Tectonic and Anthropogenic Microseismic Activity While Drilling Toward Supercritical Conditions in the Larderello‐Travale Geothermal Field, Italy

et al. 2020

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This study investigates the seismic activity occurring at the Larderello‐Travale geothermal field, central Italy, from June 2017 to January 2018. We deployed a network composed of nine broadband stations around the Venelle 2 well drilling for supercritical fluids. During the experiment, we recognize two types of seismic events (type 1 and type 2). Type‐1 events have clear P and S wave arrivals and occur in clusters both above and below the K‐horizon, which is a seismic reflector marking a debated transition zone at depth. The distribution and evolution of the seismic sequences suggest that the K‐horizon could be interpreted as a fluid‐rich region at near‐lithostatic pressures. Type‐2 events usually occur in swarms and show a periodic pattern, a narrow frequency band, and almost identical waveforms. Their source is estimated to be located near the well, and their occurrence ceases after about 3 weeks from the conclusion of the drilling. We propose a causal link with the drilling operations where pressure fronts inside the well may promote phase changes and fluid flow across the drilled formations. Our study sheds light on the fluid‐driven tectonic and anthropogenic seismic activity at the Larderello‐Travale geothermal field. More generally, we show that microseismic activity occurring during drilling in high‐pressure and high‐temperature conditions can remain at low magnitudes and that geothermal wells targeting geothermal fluids in such systems may be handled safely despite the critical conditions encountered at depth. The drilling of the Venelle 2 well is an encouraging example for the development of geothermal energy in critical conditions.

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The Iceland Deep Drilling Project 4.5 km deep well, IDDP-2, in the seawater-recharged Reykjanes geothermal field in SW Iceland has successfully reached its supercritical target

Cited by 70 publications

References 17 publications

Volatile Degassing From Magma Chambers as a Control on Volcanic Eruptions

Volatile Degassing From Magma Chambers as a Control on Volcanic Eruptions

New Conceptual Model for the Magma-Hydrothermal-Tectonic System of Krafla, NE Iceland

Tectonic and Anthropogenic Microseismic Activity While Drilling Toward Supercritical Conditions in the Larderello‐Travale Geothermal Field, Italy

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The Iceland Deep Drilling Project 4.5 km deep well, IDDP-2, in the seawater-recharged Reykjanes geothermal field in SW Iceland has successfully reached its supercritical target

Cited by 70 publications

References 17 publications

Volatile Degassing From Magma Chambers as a Control on Volcanic Eruptions

Volatile Degassing From Magma Chambers as a Control on Volcanic Eruptions

New Conceptual Model for the Magma-Hydrothermal-Tectonic System of Krafla, NE Iceland

Tectonic and Anthropogenic Microseismic Activity While Drilling Toward Supercritical Conditions in the Larderello‐Travale Geothermal Field, Italy

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Product

Resources

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The Iceland Deep Drilling Project 4.5 km deep well, IDDP-2, in the seawater-recharged Reykjanes geothermal field in SW Iceland has successfully reached its supercritical target