Controls on hydrothermal fluid flow in caldera-hosted settings: Evidence from Lake City caldera, USA

Garden, Thomas O.; Gravley, Darren M.; Kennedy, Ben; Deering, C. D.; Chambefort, Isabelle

doi:10.1130/ges01506.1

Cited by 20 publications

(14 citation statements)

References 117 publications

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“…In March 2008, field observers reported that 70-80 % of the thermal ring displayed fumarolic activity [Staudacher 2010], so that the thermal anomaly seems linked to hydrothermal fluid circulation in the caldera. This is consistent with models detailed by Stix et al [2003] and 4D mapping of caldera collapse at Piton de la Fournaise Derrien et al, 2020Garden et al [2017, where flow of hydrothermal fluids preferentially follows pre-existing faults. The three other distinct secondary thermal zones ( Figure 4C) seem to be located on the southern ORFs, and close to the location of four older pit-crater events (1953, 1961, 1986 and 2002) at the summit of PdF ( Figure 5E).…”

Section: Active Faults During the Caldera Formation Andsupporting

confidence: 89%

“…The three other distinct secondary thermal zones ( Figure 4C) seem to be located on the southern ORFs, and close to the location of four older pit-crater events (1953, 1961, 1986 and 2002) at the summit of PdF ( Figure 5E). These secondary thermal zones are more spatially diffuse than the main thermal ring, therefore inter-granular fluid flow may happen inside intra-caldera breccia at these locations (a process also evidenced by Garden et al [2017]). A well-developed hydrothermal system is inferred below the summit [e.g.…”

Section: Active Faults During the Caldera Formation Andmentioning

confidence: 97%

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The 2007 caldera collapse at Piton de la Fournaise: new insights from multi-temporal structure-from-motion

Derrien

Peltier²,

Villeneuve

et al. 2020

Volcanica

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We produced new multi-temporal Digital Elevation Models (DEMs) of the April 2007 summit collapse at Piton de la Fournaise from previously unused aerial photographs. This dataset reveals the precise temporal evolution of the collapsed volume and caldera morphological changes during the event. It provides a unique opportunity to study caldera formation, one of the most hazardous natural phenomena, for which relatively little scientific and quantified information is available. During this rare example of observed caldera formation, the summit started to collapse four days after the onset of a high-volume eruption at an unusually low elevation (at 20:48 UTC on April 5 th ). Our new data show that during the first 30 hours, collapse was relatively fast (840 m 3 s −1 average), and continued for at least the following 12 days, at a slower rate (46 m 3 s −1 average), which had not previously been reported. On April 19 th , the collapse reached 96 % of its final volume, while the remaining 4 % was probably attained by May 1 st (end of lava emission at the vent). New infrared 3D mapping of the caldera floor made a year after the event demonstrates that post-collapse hydrothermal activity in the caldera is closely associated with the main ring faults active during the collapse, which are now preferential paths for fluids to reach the surface.

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Section: Active Faults During the Caldera Formation Andsupporting

confidence: 89%

Section: Active Faults During the Caldera Formation Andmentioning

confidence: 97%

The 2007 caldera collapse at Piton de la Fournaise: new insights from multi-temporal structure-from-motion

Derrien

Peltier²,

Villeneuve

et al. 2020

Volcanica

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“…Magmatic fluids stored in deep‐seated reservoirs beneath caldera systems hold high potential for geothermal exploration and production (e.g., Fulignati et al., 1997; Giordano et al., 2014; Grigsby, 1982), especially in resurgent caldera settings that are often associated with the shallow emplacement of magma and the related development of hydrothermal systems within the caldera deposits (Lipman, 1984; Wohletz & Heiken, 1992). Circulation of geothermal fluids is typically controlled by the secondary permeability of faults connected to caldera and resurgence‐forming processes (e.g., Garden et al., 2017; Giordano et al., 2014). Therefore, faults represent optimal targets for unlocking geothermal fluids (Martí et al., 2008).…”

Section: Introduction and Aims Of The Studymentioning

confidence: 99%

Modeling Intra‐Caldera Resurgence Settings: Laboratory Experiments With Application to the Los Humeros Volcanic Complex (Mexico)

et al. 2021

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• Scaled experimental models have explored the influence of different boundary conditions in controlling the style of caldera resurgence • Models investigated the role of intrusion depth, symmetry of collapse and the presence of existing faults on resurgence processes • Models simulate many characteristics of resurgent calderas, such as the sub-orthogonal fault pattern at the Los Humeros Volcanic Complex

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“…The above discussion suggests that inherited discontinuities can be reactivated during the caldera collapse. Considering that at LH and in other caldera collapse settings (e.g., Martí et al, 2008;Giordano et al 2014;Norini et al, 2015Norini et al, , 2019Garden et al 2017;Liotta and WP4 Working Group, 2019;Montanari et al 2017a;Jentsch et al, 2020) caldera structures are considered to bear a potential for favouring the upward migration of hydrothermal fluids, we speculate that these reactivated structures may behave in a similar manner. Besides, the presence/lack of calderarelated structures due to the possible inhibition induced by inherited fault reactivation is a condition that may influence the degree of fracturation and consequently the secondary permeability and fluid flow inside the caldera complex, therefore strongly affecting the geothermal potential.…”

Section: J O U R N a L P R E -P R O O Fmentioning

confidence: 90%

Exploring fault propagation and the role of inherited structures during caldera collapse through laboratory experiments

Maestrelli

Bonini

Corti

et al. 2021

Journal of Volcanology and Geothermal Research

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Caldera collapse received large attention during the last decades and was widely studied using various approaches, spanning from field-geology to numerical and analogue modelling. Analogue models allow to reproduce caldera collapse deformation, providing information otherwise difficult to obtain during such an extremely transient geological process. A wide range of analogue studies is available in literature, nonetheless, some aspects are still barely known, particularly the propagation of caldera faults and the role of inherited structures during caldera collapse. We have thus addressed the above research questions through analogue models. Our models show how calderas may experience asymmetry due to the lateral propagation of caldera-related faults. Furthermore, inherited discontinuities may affect caldera collapse by inducing rectilinear caldera faults that generate non-circular ring faults. Finally, sub-vertical discontinuities may be able, in specific conditions, to inhibit the formation of standard caldera structures that have been commonly observed in previous experimental series (i.e., early inward-dipping reverse faults followed by peripheral normal ring faults). Our models were then compared with four natural examples (the Acoculco and Los Humeros caldera complexes in Mexico, the Tuscolo-Artemisio caldera in the Colli Albani volcanic district, Italy and the Glencoe Caldera in Scotland), suggesting a relevant control exerted by inherited faults during caldera collapse. On the basis of the modelling results, we propose an evolutionary model that can be generalized and likely applied to many other caldera settings worldwide.

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Controls on hydrothermal fluid flow in caldera-hosted settings: Evidence from Lake City caldera, USA

Cited by 20 publications

References 117 publications

The 2007 caldera collapse at Piton de la Fournaise: new insights from multi-temporal structure-from-motion

The 2007 caldera collapse at Piton de la Fournaise: new insights from multi-temporal structure-from-motion

Modeling Intra‐Caldera Resurgence Settings: Laboratory Experiments With Application to the Los Humeros Volcanic Complex (Mexico)

Exploring fault propagation and the role of inherited structures during caldera collapse through laboratory experiments

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