ALBERT

Description: The Havre Trough backarc basin in the southwest Pacific is in the rifting stage of development. We distinguish five types of basalt there based on their amount and kind of slab component: backarc basalts (BAB) with little or no slab component; modified BAB (mBAB) with slight amounts; reararc (RA) with more; remnants of the pre‐existing arc (Colville Ridge horsts, CRH); and arc front volcanoes within the Havre Trough. Previous sub‐arc mantle is quickly removed and replaced by more fertile mantle with less slab component. The ambient mantle is “Pacific” isotopically, and more enriched in Nb/Yb and Nd and Hf isotope ratios north of the Central Kermadec Discontinuity at 32°S than to the south. The contrast may reflect inheritance in the south of mantle that was depleted during spreading that formed the southern South Fiji Basin, and a higher degree of melting because of a wetter slab‐derived flux. The slab component also differs along strike, more like a dry melt in the north and a super‐critical fluid in the south. The mass fraction of slab component increases southward in the backarc as well as the arc front. Reararc volcanoes have the most slab component (1‐2%) and form indistinct ridges at high angles to, and 〈50 km behind, frontal volcanoes. Backarc basalts have less and occur throughout the basin. Slab components are distributed further into the backarc, and more irregularly, during the rifting than spreading stage of backarc basin development. The rifting stage is disorganized geochemically as well as spatially.

Description: Although previous findings support an origin of the Shatsky Rise igneous plateau (Northwest Pacific) through interaction of a mantle plume with a mid-ocean ridge triple junction, the evidence for the involvement of a mantle plume is equivocal. The identification of an intraplate hotspot track emanating from the plateau could solve this controversy. Here we present major and trace element geochemical data from two different bathymetric features that emanate from the youngest end of Shatsky Rise: Papanin Ridge and the Ojin Rise Seamount province. Combining our results with plate tectonic reconstructions, we conclude that Papanin Ridge represents a hotspot track formed by plume-ridge interaction. Whereas the southwestern part was formed along the path of the retreating Pacific-Farallon-Izanagi triple junction, the northeastern part was built by preferential drainage into its Pacific-Farallon branch. In contrast, the Ojin Rise Seamounts formed as a true intraplate hotspot track of the Shatsky plume tail. Our wide-ranging study reveals systematic spatial geochemical variations, consistent with a lithospheric thickness control on magma composition derived from melting a heterogeneous plume source. The recognition of two hotspot tracks and in particular of the Ojin Rise Seamounts as an intraplate hotspot track that is directly linked to Shatsky plateau volcanism both in terms of geochemistry and plate tectonic reconstructions confirms the long-disputed involvement of a mantle plume for the formation of Shatsky Rise.

Description: In the Comechingones pegmatitic field, central Argentina, leucogranite and pegmatite bodies crop out in a relatively narrow (25 × 10 km) belt, and were emplaced synkinematically with the main deformational event of the crustal-scale Guacha Corral shear zone during the Early Ordovician (~ 475 Ma). These leucogranites and pegmatites are geochemically evolved rocks with high silica and alkalis, low Fe2O3, MgO, TiO2 and CaO, and high ASI values. The leucogranites display quite variable Sr and Nd isotope compositions (initial 87Sr/86Sr ratios from 0.7048 to 0.7170, and εNd values from + 2.0 to − 3.1), some of which do not overlap with almost any other pre-Famatinian rock from the Sierras de Córdoba. The major and trace element geochemistry and the particular Sr and Nd isotope compositions of the leucogranites are here explained by the following processes: (1) water-fluxed partial melting of amphibolites at relatively low P–T conditions generating currently unexposed granodioritic melts with unradiogenic 87Sr/86Sr ratios and radiogenic εNd values; (2) fractionation of mostly plagioclase and monazite leading to compositions close to the leucogranite melts; and (3) assimilation of metasedimentary rocks with crustal isotopic signatures, modelled by assimilation and fractional crystallization processes. The major, trace and isotope compositions of the pegmatites suggest a derivation from partial melting of the same metasedimentary protoliths of the Sierras de Córdoba that were assimilated by leucogranite melts. We propose a feedback relationship among deformation, anatexis, magma evolution and mass transfer in the context of such a crustal-scale shear zone in the foreland of the Famatinian orogen.

Description: The late-tectonic 511.4 ± 0.6 Ma-old Nomatsaus intrusion (Donkerhoek batholith, Damara orogen, Namibia) consists of moderately peraluminous, magnesian, calc-alkalic to calcic granites similar to I-type granites worldwide. Major and trace-element variations and LREE and HREE concentrations in evolved rocks imply that the fractionated mineral assemblage includes biotite, Fe–Ti oxides, zircon, plagioclase and monazite. Increasing K2O abundance with increasing SiO2 suggests accumulation of K-feldspar; compatible with a small positive Eu anomaly in the most evolved rocks. In comparison with experimental data, the Nomatsaus granite was likely generated from meta-igneous sources of possibly dacitic composition that melted under water-undersaturated conditions (X H2O: 0.25–0.50) and at temperatures between 800 and 850 °C, compatible with the zircon and monazite saturation temperatures of 812 and 852 °C, respectively. The Nomatsaus granite has moderately radiogenic initial 87Sr/86Sr ratios (0.7067–0.7082), relatively radiogenic initial εNd values (− 2.9 to − 4.8) and moderately evolved Pb isotope ratios. Although initial Sr and Nd isotopic compositions of the granite do not vary with SiO2 or MgO contents, fSm/Nd and initial εNd values are negatively correlated indicating limited assimilation of crustal components during monazite-dominated fractional crystallization. The preferred petrogenetic model for the generation of the Nomatsaus granite involves a continent–continent collisional setting with stacking of crustal slices that in combination with high radioactive heat production rates heated the thickened crust, leading to the medium-P/high-T environment characteristic of the southern Central Zone of the Damara orogen. Such a setting promoted partial melting of metasedimentary sources during the initial stages of crustal heating, followed by the partial melting of meta-igneous rocks at mid-crustal levels at higher P–T conditions and relatively late in the orogenic evolution.

Description: Tertiary subvolcanic basic rocks are found as sills, dykes, and stocks in the southern flanks of the Central Alborz Magmatic Belt, north of Tehran. The rocks can be divided into two subvolcanic rock groups based on their geographic locations: (1) the western Kiga group and (2) an eastern group. The eastern group range from micromonzogabbro/diorite to microgabbro, whereas the Kiga group consists of micromozodiorite to micromonzogabbro. Mineral compositions, whole-rock major and trace elements show that these rocks have calc-alkaline affinities. The eastern group extends to higher MgO (4–10wt%) than the Kiga group (MgO= 4–5 wt%). With decreasing MgO, the contents of SiO2, TiO2, Al2O3, Na2O, and P2O5 increase and the contents of CaO and compatible trace elements (e.g., Co, Ni, Cr) decrease, consistent with olivine and clinopyroxene fractionation. At a given MgO, the Kiga rocks have higher FeOt, K2O, and P2O5 and extend to higher overall highly to moderately incompatible elements (Rb, Ba, Th, U, Nb, Ta, LREE, Sr, and Zr) and lower Al2O3 and Na2O. The depletion in Nb and Ta but enrichments in Rb, Ba, Th, U, K, Pb, and Sr, compared to N-MORB as well as high Th/Yb (at a given Nb/Yb or Ta/Yb), indicates a subduction zone origin for both subvolcanic groups of rocks. The initial Sr and Nd isotopic ratios of the subvolcanic rocks vary from 0.7048 to 0.7064 and 0.5126 to 0.5128, respectively. Furthermore, εNd (50 Ma) values (+0.64 to +5.19) associated with the two-stage model ages (0.42 to 0.78 Ga) of the samples infer a contribution of Cadomian-enriched lithospheric mantle in their source for this melt. The most evolved sample from the Kiga group has the lowest 143Nd/144Nd and highest 206Pb/204Pb and 208Pb/204Pb ratios. The isotope correlations could be explained by upper crustal assimilation/contamination by the more evolved samples or reflect source differences (i.e., higher amount of subducted sediments) in the Kiga source. In conclusion, we interpret that the subvolcanic rocks have formed in an active continental margin.

Description: The formerly continuous Vitiaz Arc broke into its Vanuatu and Fijian portions during a reversal of subduction polarity in the Miocene. Basaltic volcanism in Fiji that accompanied the breakup ranged from shoshonitic to low-K and boninitic with increasing distance from the broken edge of the arc that, presumably, marks the broken edge of the slab. The Sr-Pb-Nd isotope ratios of the slab-derived component in the breakup basalts most closely match those of the isotopically most depleted part of the Samoan seamount chain on the Pacific Plate that was adjacent to the site of breakup at 4–8 Ma, and differ from those of subsequent basalts in spreading segments of the surrounding backarc North Fiji and Lau Basins. Subduction of the Samoan Chain along the Vitiaz Trench Lineament may have controlled the limit of polarity reversal and, hence, where the double saloon doors (Martin, 2013) opened. Prior to breakup, Fijian volcanics were more similar isotopically to the Louisville Seamount Chain. Key Points - The breakup between Fiji and Vanuatu may have been triggered by subduction of Samoan seamounts - Shoshonitic to low-K and boninitic volcanism accompanied breakup with increasing distance from the break - The mantle source of later basalts in surrounding backarc basins and islands came from beneath the Pacific Plate north of the breakup site