Evidence for melt migration enhancing recrystallization of metastable assemblages in mafic lower crust, Fiordland, New Zealand

Daczko, Nathan R.; Halpin, Jacqueline A.

doi:10.1111/j.1525-1314.2009.00811.x

Cited by 40 publications

(43 citation statements)

References 72 publications

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“…% liquid, as the leucosome changes rheologically from behaving like a liquid to behaving like a solid, passing through the rigid percolation threshold (Vigneresse et al, 1996) or the solid-to-liquid transition (Rosenberg & Handy, 2005). This hypothesis is supported by petrographical and geochemical studies suggesting that some leucosomes represent cumulates after the more evolved liquid was lost (Sawyer, 1987;Ellis & Obata, 1992;Fourcade et al, 1992;Milord et al, 2001;Solar & Brown, 2001;Johnson et al, 2003;Slagstad et al, 2005;Cruciani et al, 2008;Daczko & Halpin, 2009;Morfin et al, 2014;Brown et al, 2016).…”

Section: Melt Generation and Crystallizationsupporting

confidence: 64%

Crystallization of Heterogeneous Pelitic Migmatites: Insights from Thermodynamic Modelling

Koblinger

Pattison

2017

Journal of Petrology

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Pelitic migmatites are texturally and mineralogically heterogeneous owing to variable proportions of light and dark coloured domains (leucosome and melanosome), the degree to which the two domains are segregated from one another and the variable composition of the leucosome (tonalitetrondhjemite to alkali feldspar granite). We use thermodynamic modelling to (1) provide insights into the variation in leucosome composition and solidification conditions for different melting and crystallization processes and (2) address the practical problem of how to sample heterogeneous migmatites for the purpose of constraining the pressure-temperature conditions of their formation. The latter is challenging because the appropriate bulk composition is affected by the above heterogeneity, as well as by the possibility of melt loss. Both dehydration melting and excess-water melting (for 2Á0 wt % excess water) are simulated for both equilibrium and fractional melting endmember processes. Three end-member processes are considered during the crystallization stage: (1) fractional crystallization of the melt; (2) equilibrium crystallization of just the melt in isolation from the solid phases; (3) crystallization during which melt and solids maintain chemical communication. Loss of melt during heating and cooling are also considered. Some of the key results of our simulations of pelitic migmatites are as follows. (1) Leucosome composition is primarily a reflection of the melt composition and to lesser degrees the crystallization process and the temperature of melt loss during cooling. Granite (sensu stricto) is the most common leucosome type, arising from many melting and crystallization processes, whereas tonalite or trondhjemite leucosome is generally indicative of excess-water melting. (2) Melts lost from partially molten regions, which have the potential to coalesce and form granites at shallower crustal levels, show less compositional variation than leucosomes in migmatites. Extracted melts are monzogranitic, or rarely granodioritic at low temperatures. (3) Comparing plagioclase compositions between leucosome and melanosome is potentially an effective means of distinguishing between crystallization processes, as well as the degree of retrograde melt-leucosome-melanosome chemical interaction. Fractional crystallization produces zoned plagioclase in the leucosome, isolated equilibrium crystallization produces plagioclase of different composition in the leucosome and melanosome, whereas chemical interaction causes the leucosome and melanosome plagioclase compositions to remain similar during crystallization. (4) The peak temperature of heterogeneous migmatites is most reliably constrained from an equilibrium phase assemblage diagram calculated using just the melanosome composition. Addition of leucosome to the melanosome composition can lead to peaktemperature estimates that differ from actual peak conditions by À25 to þ50 C. In extreme cases, such as in rocks containing high proportions of leucosome to melanosome, or in which...

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Section: Melt Generation and Crystallizationsupporting

confidence: 64%

Crystallization of Heterogeneous Pelitic Migmatites: Insights from Thermodynamic Modelling

Koblinger

Pattison

2017

Journal of Petrology

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“…Peak metamorphic facies include eclogite, omphacite-, garnet-, two-pyroxeneand hornblende-granulite and amphibolite facies (Oliver 1977;Bradshaw 1989a;Clarke et al 2000;Allibone et al 2009b;Daczko & Haplin 2009;De Paoli et al 2009). Ultramafic rocks at Hawes Head described in this study are surrounded by the Western Fiordland Orthogneiss Misty Pluton, which comprises relatively leucocratic twopyroxene9hornblende, feldspathic diorite, monzodiorite and minor monzonite in the vicinity of Hawes Head.…”

Section: Geological Settingmentioning

confidence: 66%

Petrogenesis and geochemical characterisation of ultramafic cumulate rocks from Hawes Head, Fiordland, New Zealand

Daczko

Emami

Allibone³

et al. 2012

New Zealand Journal of Geology and Geophysics

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Early Cretaceous parts of the western Median Batholith (Western Fiordland Orthogneiss) represent the exposed root of a magmatic arc of dioritic to monzodioritic composition (SiO 2 051Á55 wt%; Na 2 O/K 2 O 03.7Á8.8 in this study). We characterise for the first time the field relationships, petrography, mineralogy and geochemistry of ultramafic and mafic cumulates at Hawes Head, the largest exposure of ultramafic rocks in western Fiordland. We distinguish three related rock types at Hawes Head: hornblende peridotite (MgO 021Á35 wt%); hornblendite (MgO 015Á16 wt%); and pyroxenite (MgO 021 wt%). Petrogenetic relationships between the ultramafic rocks and the surrounding Misty Pluton of the Western Fiordland Orthogneiss are demonstrated by: (i) mutually cross-cutting relationships; (ii) similar mafic phases (e.g. pyroxene and amphibole) with elevated Mg-numbers (e.g. olivine Mg/(Mg'Fe) 00.77Á0.82); (iii) fractionation trends in mineral geochemistry; and (iv) shared depleted heavy rare earth element patterns. In addition, the application of solid/liquid partition coefficients indicates that olivine in the ultramafic rocks at Hawes Head crystallised from a magma with Mg/(Mg'Fe) 00.54Á0.57. The olivine grains therefore represent a plausible early crystallising phase of the adjacent Western Fiordland Orthogneiss (Mg/(Mg'Fe) 0 0.51Á0.55).

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“…With the presence of hornblende, the melt phase was also neglected due to its insignificant proportion (Poli and Schmidt, 2002) and no appropriate mixing model is available for present pseudosection calculation involving melt in mafic rocks. Although the mineral assemblages coexist with melt or fluid in the high-temperature pseudosection fields may be metastable (Daczko and Halpin, 2009), the phase relationships are more or less the same and the mineral-in/out lines may not vary too much observed from the results of experiments, petrologic studies and calculations (Pattison, 2003). 12% of the total Fe was assumed to be present as Fe 2 O 3 set in the data set Sun and McDonough, 1989), and quartz and H 2 O are set to be in excess.…”

Section: P-t Pseudosection Modelingmentioning

confidence: 99%

Petrology and metamorphic P–T path of high-pressure mafic granulites from the Jiaobei massif in the Jiao-Liao-Ji Belt, North China Craton

Tam

Zhao

Sun

et al. 2012

Lithos

168

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Evidence for melt migration enhancing recrystallization of metastable assemblages in mafic lower crust, Fiordland, New Zealand

Cited by 40 publications

References 72 publications

Crystallization of Heterogeneous Pelitic Migmatites: Insights from Thermodynamic Modelling

Crystallization of Heterogeneous Pelitic Migmatites: Insights from Thermodynamic Modelling

Petrogenesis and geochemical characterisation of ultramafic cumulate rocks from Hawes Head, Fiordland, New Zealand

Petrology and metamorphic P–T path of high-pressure mafic granulites from the Jiaobei massif in the Jiao-Liao-Ji Belt, North China Craton

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