Thermal and rheological controls on the formation of mafic enclaves or banded pumice

Andrews, B. J.; Manga, Michael

doi:10.1007/s00410-013-0961-7

Cited by 34 publications

(23 citation statements)

References 76 publications

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“…The formation of the trachytic enclave within the syenite may be directly related to the emplacement of a new magma batch derived from a deeper trachytic reservoir. Enclave formation follows fragmentation of a cooled dike by convection within the still partially molten syenite body (Andrews and Manga 2014). This may also explain why the enclavehosting syenite sample has high 87 Sr/ 86 Sr, as that portion of syenite would have been affected by magmatic and hydrothermal fluids related to the trachyte dyke emplacement episode.…”

Section: Plumbing System Model: "Nest Volcano"mentioning

confidence: 98%

A trachyte–syenite core within a basaltic nest: filtering of primitive injections by a multi-stage magma plumbing system (Oki-Dōzen, south-west Japan)

Brenna

Nakada

Miura

et al. 2015

Contrib Mineral Petrol

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that distinguish it from the rest of the system. Geochemical modelling indicates that magmatic differentiation through crystal fractionation and minor crustal assimilation occurred in crustal and shallow sub-volcanic magma reservoirs. In the central part of the system, a number of vertically spaced reservoirs acted as a filter, capturing basaltic dykes and hindering their ascent. In the outer region, dykes either reached the surface unhindered and erupted to form the basaltic/trachybasaltic succession or stalled at crustal levels and differentiated to trachyte before forming dispersed domes/flows. The central plumbing system "filter" resulted in a nest-shaped volcano, with a trachytic core surrounded by basaltic products, and stopped direct injection of basaltic magmas into the shallow syenitic magma reservoir, likely preventing its destabilization and explosive eruption.

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Section: Plumbing System Model: "Nest Volcano"mentioning

confidence: 98%

A trachyte–syenite core within a basaltic nest: filtering of primitive injections by a multi-stage magma plumbing system (Oki-Dōzen, south-west Japan)

Brenna

Nakada

Miura

et al. 2015

Contrib Mineral Petrol

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“…Typically, magma mixing/mingling occurs during replenishment by a mafic magma of a felsic and mushy reservoir [8][9][10][11][12][13][14] , either deep or shallow, which, in the latter case, may trigger a volcanic eruption 8 . The injection of denser basalt into a lighter reservoir most likely produces viscous gravity currents spreading at the floor, leading to a stratified two-layer system 15 , except when excess momentum is available, which may induce fountaining 16 .…”

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confidence: 99%

“…Ensuing crystallization can lead to density inversion producing either local 17,18 or wholesale 19 overturning and associated mixing/mingling, depending on viscosity contrast 20 . Observations and fluid dynamical considerations [8][9][10][11][12][13][14][15][16][17][18][19][20][21] have shown that, in calcalkaline reservoirs, mixing/mingling most likely starts either from such boundary layer instabilities 17 , with centimetre to decimetre wavelength scale 18 , or from breakup of injected magma dykes 12 . These mechanisms readily explain enclave sizes as observed in plutonic or volcanic rocks 18,21 , that is, mingled magmas.…”

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confidence: 99%

“…Previous work has considered magma mixing using analogical, numerical or experimental approaches [8][9][10][11][12][13][14][15][16][17][18][19][20] , which have all yielded valuable information on the fluid mechanics, leading to efficient stirring. However, the rigorous evaluation of the conditions favourable to intimate magma mixing has been hampered by the difficulty of simulating mixing at high pressure, and by the complex fluid-mechanical behaviour of magmas.…”

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confidence: 99%

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On the conditions of magma mixing and its bearing on andesite production in the crust

et al. 2014

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Mixing between magmas is thought to affect a variety of processes, from the growth of continental crust to the triggering of volcanic eruptions, but its thermophysical viability remains unclear. Here, by using high-pressure mixing experiments and thermal calculations, we show that hybridization during single-intrusive events requires injection of high proportions of the replenishing magma during short periods, producing magmas with 55-58 wt% SiO 2 when the mafic end-member is basaltic. High strain rates and gas-rich conditions may produce more felsic hybrids. The incremental growth of crustal reservoirs limits the production of hybrids to the waning stage of pluton assembly and to small portions of it. Large-scale mixing appears to be more efficient at lower crustal conditions, but requires higher proportions of mafic melt, producing more mafic hybrids than in shallow reservoirs. Altogether, our results show that hybrid arc magmas correspond to periods of enhanced magma production at depth.

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“…Vernon 2014; Clemens and Bezuidenhout 2014). The convective rise of the hybrid conduit to form mingled magmas (Snyder and Tait 1996;Clynne 1999;Andrews and Mang 2014) and buoyant rise of hybrid magma blobs that become enclaves suspended within the enclosing host granitic magma at emplacement level (e.g. Vernon 1984;Clynne 1999;Coombs et al 2003).…”

Section: The Late Triassic Akazishan Plutonmentioning

confidence: 99%

Origins of Early Mesozoic granitoids and their enclaves from West Kunlun, NW China: implications for evolving magmatism related to closure of the Paleo-Tethys ocean

Wang

Liu

Korhonen

et al. 2015

Int J Earth Sci (Geol Rundsch)

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the melting of a source at middle crustal depths. The AP host and its enclaves from the southeastern part of the West Kunlun have low Rb, Rb/Sr (0.15-1.90) and weakly negative Eu anomalies but high HREE contents indicating limited fractionation of plagioclase without residual garnet in their source. The inferred protolith is an intermediate igneous rock in the middle or lower crust. MEs hosted in the AP have high Mg# (39.7-45.0) and Nb and weakly negative Eu anomalies, as well as high Sr, P and Ti, corresponding to a medium-K basaltic rock, which may have originated from mixing of partial melting of metasomatised mantle wedge that has been modified by upwelling asthenospheric mantle and crustal melting in the deep source. Post-collisional southeasternward younging of Mesozoic granitoids in the West Kunlun records a transition from shallow level, mid-crustal melting to deeper level, lower-crustal melting. The post-collisional granitoids show significant mantle input increasing from northwest to southeast, which was closely associated with mafic magma-driven partial melting of mantle and crustal sources as a consequence of slab break-off. Syn-to post-collisional Early Mesozoic granites emplaced along the Mazar-Kangxiwar suture zone suggest that these tectonomagmatic processes followed the closure of the Paleo-Tethys ocean during the Tarim and Karakorum-Qiangtang continental collision.

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Thermal and rheological controls on the formation of mafic enclaves or banded pumice

Cited by 34 publications

References 76 publications

A trachyte–syenite core within a basaltic nest: filtering of primitive injections by a multi-stage magma plumbing system (Oki-Dōzen, south-west Japan)

A trachyte–syenite core within a basaltic nest: filtering of primitive injections by a multi-stage magma plumbing system (Oki-Dōzen, south-west Japan)

On the conditions of magma mixing and its bearing on andesite production in the crust

Origins of Early Mesozoic granitoids and their enclaves from West Kunlun, NW China: implications for evolving magmatism related to closure of the Paleo-Tethys ocean

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