Wetting properties of anorthite aggregates: Implications for fluid connectivity in continental lower crust

Yoshino, Toshihiko; Mibe, Kenji; Yasuda, Atsushi; Fujii, Toshitsugu

doi:10.1029/2001jb000440

Cited by 34 publications

(29 citation statements)

References 28 publications

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“…Faceting at the crystal surfaces was observed at both cpx-liquid and garnet-liquid interfaces, which indicates anisotropy of interfacial energy at both cpx-liquid and garnet-liquid interfaces. Yoshino et al (2002) showed that faceting effects were significant only at large grain size. In the eclogite-H 2 O system, Mibe et al (2003) reported that the median dihedral angles including faceting faces correspond to those excluding faceting faces within experimental uncertainties.…”

Section: Results From the Experimentsmentioning

confidence: 99%

Morphological stability of hydrous liquid droplets at grain boundaries of eclogite minerals in the deep upper mantle

Matsukage

Hashimoto

Nishihara

2017

Journal of Mineralogical and Petrological Sciences

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The morphological stability of hydrous liquid droplets at grain boundaries of eclogite minerals in the basaltic part of a subducting slab were investigated based on experimental constraints for the dihedral angles. We measured the dihedral angles in the eclogite-H 2 O system at a temperature of 1000°C and at pressures ranging from 4 to 16 GPa. The dihedral angle of hydrous liquid versus garnet-garnet (θ GG-L ) increased with increasing pressure from 46°at 4 GPa to 66°at 12 GPa, although it showed a weak decreasing trend at pressures higher than 12 GPa. The dihedral angle of hydrous liquid versus clinopyroxene-clinopyroxene (θ CC-L ) was almost constant with increasing pressure (61 and 59°at 4 and 10 GPa, respectively). The dihedral angle of hydrous liquid versus garnet-clinopyroxene (θ GC-L ) was 73-76°at 4-10 GPa, and it was always higher than θ GG-L and θ CC-L . By applying the morphological stability criteria for liquid in a system with two solid phases (garnet and clinopyroxene) and bond percolation theory for a three-dimensional lattice of tetracoordination, we found that the hydrous liquid was isolated at the grain edges and corners of eclogite minerals in the cold slab under a wide range of pressure conditions of the upper mantle from 4-14 GPa when the grain size of garnet was equal to that of clinopyroxene. Thus, basaltic crust containing hydrous liquid droplets may carry water to the lowermost upper mantle and the mantle transition zone when the slab is cold.

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Section: Results From the Experimentsmentioning

confidence: 99%

Morphological stability of hydrous liquid droplets at grain boundaries of eclogite minerals in the deep upper mantle

Matsukage

Hashimoto

Nishihara

2017

Journal of Mineralogical and Petrological Sciences

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“…Despite previous statements that aqueous fluids will not connect to form conductive pathways at the depths of the northern Tibet conductors (Wei et al 2001), the unusual thickness of Tibetan crust (>60 km) means that the pressure dependence of dihedral angle must be considered. Though water forms dihedral angles >60 ~ with typical crustal and mantle minerals in the lower crust and uppermost mantle of normal lithospheres (crust c. 40 km thick), at pressure (p) > 1 GPa and temperature (T) > 800~ the dihedral angle is <60 ~ for water in plagioclase (Yoshino et al 2002) and quartz (Holness 1993) aggregates, and for water in olivine at p > 1.5 GPa and T > 1000~ (Mibe et al 1999). These are pT conditions presumably relevant to northern Tibet.…”

Section: Seismic Attenuation: Evidence For High Temperatures and Partmentioning

confidence: 98%

Crustal flow in Tibet: geophysical evidence for the physical state of Tibetan lithosphere, and inferred patterns of active flow

Klemperer

2006

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Many seismic and magnetotelluric experiments within Tibet provide proxies for lithospheric temperature and lithology, and hence rheology. Most data have been collected between c. 88°E and 95°E in a corridor around the Lhasa-Golmud highway, but newer experiments in western Tibet, and inversions of seismic data utilizing wave-paths transiting the Tibetan Plateau, support a substantial uniformity of properties broadly parallel to the principal Cenozoic and Mesozoic sutures, and perpendicular to the modern NNE convergence direction. These data require unusually weak zones in the crust at different depths throughout Tibet at the present day. In southern Tibet these weak zones are in the upper crust of the Tethyan Himalaya, the middle crust in the southern Lhasa terrane, and the middle and lower crust in the northern Lhasa terrane. In northern Tibet, north of the Banggong-Nujiang suture, the middle and probably the lower crust of both the Qiangtang and Songpan-Ganzi terranes are unusually weak. The Indian uppermost mantle is cold and seismogenic beneath the Tethyan Himalaya and the southernmost Lhasa terrane, but is probably overlain by a northward thickening zone of Asian mantle beneath the northern Lhasa terrane. Beneath northern Tibet the upper mantle has not been replaced by subducting Indian and Asian lithospheres, and is warmer than to the south. These inferred vertical strength profiles all have minima in the crust, thereby permitting, though not actually requiring, some form of channelized flow at the present day. Using the simplest parameterization of channel-flow models, I infer that a Poiseuille-type flow (flow between stationary boundaries) parallel to India-Asia convergence is occurring throughout much of southern Tibet, and a combination of Couette (top-driven, between moving boundaries) and Poiseuille lithospheric flow, perpendicular to lithospheric shortening, is active in northern Tibet. Explicit channel-flow models that successfully replicate much of the large-scale geophysical behaviour of Tibet need refinement and additional model complexity to capture the full details of the temporal and spatial variation of the India-Asia collision.

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“…We propose an alternative model: a transition from the state of isolated fluids to the state of interconnected fluids. The crustal resistivity is primarily controlled by conductive crustal fluid and its interconnectivity at the microscopic level, such as on grain boundaries or along micro-cracks343536373839. Our conceptual model is as follows: before the earthquake, some fluids were partially in an isolated state, and the pore pressure changed immediately before and during the earthquake, connecting the fluids through a new fluid-path network.…”

Section: Discussionmentioning

confidence: 99%

Rapid changes in the electrical state of the 1999 Izmit earthquake rupture zone

et al. 2013

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Crustal fluids exist near fault zones, but their relation to the processes that generate earthquakes, including slow-slip events, is unclear. Fault-zone fluids are characterized by low electrical resistivity. Here we investigate the time-dependent crustal resistivity in the rupture area of the 1999 Mw 7.6 Izmit earthquake using electromagnetic data acquired at four sites before and after the earthquake. Most estimates of apparent resistivity in the frequency range of 0.05 to 2.0 Hz show abrupt co-seismic decreases on the order of tens of per cent. Data acquired at two sites 1 month after the Izmit earthquake indicate that the resistivity had already returned to pre-seismic levels. We interpret such changes as the pressure-induced transition between isolated and interconnected fluids. Some data show pre-seismic changes and this suggests that the transition is associated with foreshocks and slow-slip events before large earthquakes.

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Wetting properties of anorthite aggregates: Implications for fluid connectivity in continental lower crust

Cited by 34 publications

References 28 publications

Morphological stability of hydrous liquid droplets at grain boundaries of eclogite minerals in the deep upper mantle

Morphological stability of hydrous liquid droplets at grain boundaries of eclogite minerals in the deep upper mantle

Crustal flow in Tibet: geophysical evidence for the physical state of Tibetan lithosphere, and inferred patterns of active flow

Rapid changes in the electrical state of the 1999 Izmit earthquake rupture zone

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