Kinematics and geometry of active detachment faulting beneath the Trans-Atlantic Geotraverse (TAG) hydrothermal field on the Mid-Atlantic Ridge

deMartin, B.; Sohn, Robert A.; Canales, J. P.; Humphris, Susan E.

doi:10.1130/g23718a.1

Cited by 264 publications

(361 citation statements)

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“…The absence of a crustal melt reservoir and the extension of microearthquake activity (and thus the brittle-plastic rheological transition) to depths greater than 7 km suggest that hydrothermal fluids penetrate much deeper into the lithosphere than previously supposed deMartin et al, 2007).…”

Section: The Role Of the Detachment Faultmentioning

confidence: 83%

“…Over the last ten years, however, geophysical studies have revealed that the TAG hydrothermal field is located on the hanging wall of an active detachment fault (Tivey et al, 2003;Canales et al, 2007;deMartin et al, 2007). This finding has major implications for our understanding of hydrothermal circulation at slow-spreading mid-ocean ridges.…”

Section: Introductionmentioning

confidence: 93%

“…A study of microearthquakes over an eight month period showed that detachment faulting is accommodated on an ~15 km-long, dome-shaped fault surface that penetrates into the mantle at a steep dip of ~70° over the depth interval of ~3 to >7 km below the seafloor, and rolls over to a low angle of ~20°, becoming aseismic at shallower depths of 2-3 km below the seafloor (Figure 2) ). An active-source seismic survey revealed that there are no mid-crustal magma bodies beneath the hydrothermal field , so deMartin et al (2007) inferred that hydrothermal fluids must penetrate to great depths (>7 km) to extract heat out of a gabbroic intrusion at the root zone of the detachment fault (Figure 2). They suggested that circulation in the middle to lower crust may be focused on the relatively permeable, three-dimensional detachment fault surface, while in the upper crust high temperature fluids rise vertically through the highly tectonized hanging wall .…”

Section: Geotectonic Setting Of the Tag Hydrothermal Systemmentioning

confidence: 99%

“…Since the discovery in 1985 of the first high temperature vents, massive sulfide deposits, and new vent ecosystems in the Atlantic Ocean again by Peter Rona (Rona at el., 1986), the TAG hydrothermal field has served as a major 'type' example of a massive sulfide deposit on a slow-spreading ridge, particularly with its similarities to sulfide deposits in Cyprus (e.g., Herzig et al, 1991;Hannington et al, 1998;Humphris and Cann, 2000). It is one of the most comprehensively studied seafloor hydrothermal fields and has been the focus of numerous geophysical (e.g., Kong et al, 1992, Tivey et al, 1993, 1996Goto et al, 2003;deMartin et al, 2007;Canales et al, 2007;Zhao et al, 2012;Pontbriand and Sohn, 2014), geochemical (e.g., Edmond et al, 1995;Humphris et al, 1998;Tivey et al, 1995Humphris and Bach, 2005), and biological (e.g., Van Dover et al, 1988;Galkin and Moskalev, 1990;Copley et al, 1999) investigations. In addition, it is one of only three actively venting seafloor hydrothermal systems to be sampled in the third dimension as part of the Ocean Drilling Program (ODP) Herzig et al, 1998).…”

Section: Introductionmentioning

confidence: 99%

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The Trans-Atlantic Geotraverse hydrothermal field: A hydrothermal system on an active detachment fault

Humphris

Tivey

2015

Deep Sea Research Part II: Topical Studies in Oceanography

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Over the last ten years, geophysical studies have revealed that the Trans-Atlantic Geotraverse (TAG) hydrothermal field (26°08'N on the Mid-Atlantic Ridge) is located on the hanging wall of an active detachment fault. This is particularly important in light of the recognition that detachment faulting accounts for crustal accretion/extension along a significant portion of the Mid-Atlantic Ridge, and that the majority of confirmed vent sites on this slow-spreading ridge are hosted on detachment faults. The TAG hydrothermal field is one of the largest sites of high-temperature hydrothermal activity and mineralization found to date on the seafloor, and is comprised of active and relict deposits in different stages of evolution. The episodic nature of hydrothermal activity over the last 140 ka provides strong evidence that the complex shape and geological structure of the active detachment fault system exerts first order, but poorly understood, influences on the hydrothermal circulation patterns, fluid chemistry, and mineral deposition. While hydrothermal circulation extracts heat from a deep source region, the location of the source region at TAG is unknown. Hydrothermal upflow is likely focused along the relatively permeable detachment fault interface at depth, and then the high temperature fluids leave the low-angle portion of the detachment fault and rise vertically through the highly fissured hanging wall to the seafloor. The presence of abundant anhydrite in the cone on the summit of the TAG active mound and in veins in the crust beneath provides evidence for a fluid circulation system that entrains significant amounts of seawater into the shallow parts of the mound and stockwork. Given the importance of detachment faulting for crustal extension at slow spreading ridges, the fundamental question that still needs to be addressed is: How do detachment fault systems, and the structure at depth associated with these systems (e.g., presence of plutons and/or high permeability zones) influence the pattern of hydrothermal circulation, mineral deposition, and fluid chemistry, both in space and time, within slowly accreted ocean crust?

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Section: The Role Of the Detachment Faultmentioning

confidence: 83%

Section: Introductionmentioning

confidence: 93%

Section: Geotectonic Setting Of the Tag Hydrothermal Systemmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The Trans-Atlantic Geotraverse hydrothermal field: A hydrothermal system on an active detachment fault

Humphris

Tivey

2015

Deep Sea Research Part II: Topical Studies in Oceanography

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“…An 8-month microseismic experiment at the TAG hydrothermal field (26.1°N) shows deformation along the active detachment fault accommodated by continuous creep associated with steady hydroacoustic event rates (Figure 1d). Microseismicity events at ridge sections with active detachments (TAG 13,15 , 23°N 16 ) are observed down to 7-8 km below seafloor, with the interpreted fault rooting directly below the neovolcanic zone 13 . In contrast, at the centre of symmetrical segments (35°N 17 and Figure 1b, 29°N 18 ) events extend to maximum depths of 5-6 km, 1-3 km shallower than near detachments (see There is a close association of hydrothermal activity and asymmetrical accretion.…”

mentioning

confidence: 99%

Central role of detachment faults in accretion of slow-spreading oceanic lithosphere

Escartı́n

Smith

Cann

et al. 2008

Nature

421

374

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Enhanced seismicity is probably generated along detachment faults accommodating a sizeable proportion of the total plate separation. In contrast, symmetrical segments have lower levels of seismicity, which concentrates primarily at their ends. Basalts erupted along asymmetrical segments have compositions that are consistent with crystallization at higher pressures than basalts from symmetrical segments, and with lower extents of partial melting of the mantle. The large fields of detachment surfaces recently identified in oceanic crust formed along the slow spreading MAR and ultra-slow spreading South-West Indian Ridge (SWIR) 3,6 demonstrate the involvement of these structures in the accretion of a larger portion of the oceanic lithosphere than previously inferred from seafloor corrugated planes alone 7 . The resulting seafloor morphology and lithospheric structure on the flanks of the ridge axis are strongly asymmetrical 3 and differ from the more regular and roughly symmetrical axis-parallel abyssal hill fabric believed to characterize 'normal' slow-spreading seafloor. The abyssal hill morphology is caused by ridge-parallel, highangle faulting of volcanic seafloor 8 (Figures 1a-c). In contrast, detachment-related terrain is caused by long-lived steep, normal faults initiated beneath the rift valley floor that rotate to low angles as their footwalls are exposed 7,8 . Distinctive narrow ridges with steep outward-facing slopes that are often curved in plan view develop near exposed detachments at the seafloor, and bound deep swales 7 (Figures 1d-e), producing blocky and chaotic terrain 7,9 . The asymmetric nature of accretion in the presence of detachments is also observed in the overall lithospheric structure, composition and geophysical character wherever data are available 3,4,10 . The MAR lacks the broad ridges only found along the melt-poor SWIR, likely a manifestation of detachment faulting that is different from striated fault planes and associated structure 3 . There is an excellent correlation between mode of accretion and seismicity at the ridge axis. This section of the MAR was hydroacoustically monitored between January 1999 and September 2003 11 . The hydroacoustic catalogue is complementary to the >30 year teleseismic catalogue, as it records smaller magnitude events (magnitude of completeness of 3 and 5, respectively 12 ), over a shorter period of time (<5 vs. >30 years). Both seismic catalogues show that detachment-dominated, asymmetrical ridge sections host ~75% more hydroacoustic events and ~65% more teleseismic events than 4 symmetrical segments (Figure 2b and c). The concentration of seismicity at segments shown to have active detachment faults (Figures 1d-e), such as the Logachev massif south of the Fifteen-Twenty Fracture zone and the TAG detachment fault near 26°N 6,7,13 , is thus a general pattern. Active detachments also control the zones of sustained seismicity, which lack shock-aftershock sequences that were previously identified along the northern MAR 14 . Differences between the hyd...

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Fluid evolution in an Oceanic Core Complex: A fluid inclusion study from IODP hole U1309 D—Atlantis Massif, 30°N, Mid‐Atlantic Ridge

Castelain

McCaig

Cliff

2014

Geochem. Geophys. Geosyst.

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In the detachment mode of slow seafloor spreading, convex-upward detachment faults take up a high proportion of the plate separation velocity exposing gabbro and serpentinized peridotite on the seafloor. Large, long-lived hydrothermal systems such as TAG are situated off axis and may be controlled by fluid flow up a detachment fault, with the source of magmatic heat being as deep as 7 kmbsf. The consequences of such deep circulation for the evolution of fluid temperature and salinity have not previously been investigated. Microthermometry on fluid inclusions trapped in diabase, gabbro, and trondjhemite, recovered at the Atlantis Massif Oceanic Core Complex (30 N, Mid-Atlantic Ridge), reveals evidence for magmatic exsolution, phase separation, and mixing between hydrothermal fluids and previously phase-separated fluids. Four types of fluid inclusions were identified, ranging in salinity from 1.4 to 35 wt % NaCl, although the most common inclusions have salinities close to seawater (3.4 wt % NaCl). Homogenization temperatures range from 160 to >400 C, with the highest temperatures in hypersaline inclusions trapped in trondjhemite and the lowest temperatures in low-salinity inclusions trapped in quartz veins. The fluid history of the Atlantis Massif is interpreted in the context of published thermochronometric data from the Massif, and a comparison with the inferred circulation pattern beneath the TAG hydrothermal field, to better constrain the pressure temperature conditions of trapping and when in the history of exhumation of the rocks sampled by IODP Hole U1309D fluids have been trapped.

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Kinematics and geometry of active detachment faulting beneath the Trans-Atlantic Geotraverse (TAG) hydrothermal field on the Mid-Atlantic Ridge

Cited by 264 publications

References 32 publications

The Trans-Atlantic Geotraverse hydrothermal field: A hydrothermal system on an active detachment fault

The Trans-Atlantic Geotraverse hydrothermal field: A hydrothermal system on an active detachment fault

Central role of detachment faults in accretion of slow-spreading oceanic lithosphere

Fluid evolution in an Oceanic Core Complex: A fluid inclusion study from IODP hole U1309 D—Atlantis Massif, 30°N, Mid‐Atlantic Ridge

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