Petrological and geochemical investigations were performed on the uniquely distributed Nanzaki ba... more Petrological and geochemical investigations were performed on the uniquely distributed Nanzaki basanite (0.43 Ma) in the northern part of the Izu–Bonin volcanic arc, Japan, to clarify its original magma chemistry, and to constrain the source mantle and formation process of the magma. The Nanzaki basanite (monogenetic volcano) is mainly composed of nepheline-bearing basanite lava and scoria. The mineral chemistries are characterized by high forsterite (Fo) contents of olivines, high Mg# (=Mg/(Mg + Fe)) values of clinopyroxenes, and low Cr# (=Cr/(Cr + Al)) values of spinels.Whole-rock major element contents have narrow variation ranges as follows: SiO2 (41.5–44.1%), MgO (10.2–13.1%), CaO (11.9–13.3%), and K2O (0.4–1.9%). Combined with these mineral and whole rock chemistries, the lowFeO*/MgO (0.81–1.09) values, high Ni and Cr contents, and narrowly distributed rare earth element (REE) patterns of theNanzaki basanite represent the primary (undifferentiated) chemical features of the magmas. The incompatible trace element characteristics, especially the high Sr, Ba, and REE contents and low K, Rb, Zr, Hf, and Ti contents, suggest that the basanite magmas were generated from an enriched mantle that was affected by metasomatism with carbonatite magma (or carbonate-melt). In addition, the slight enrichment of Pb, Cs and other alkaline elements in the basanites indicates the close concern of fluids, and the Sr–Nd isotope characteristics of the basanites (low 87Sr/86Sr and 143Nd/144Nd ratios relative to those of basaltic rocks in the volcanic front) are consistentwith across arc isotopic variations of the Izu–Bonin volcanic arc. Themetasomatismof the source mantle by carbonatite (or carbonate-rich)meltwas associated with and potentially facilitated by the infiltration and interaction of some volatile components (CO2, H2O) from the subducting slab. Thus, it is presumed that the enriched and metasomatizedmantle parts have been present, ubiquitously in some regions of the mantle wedge, and that the basaniticmagma, as in the Nanzaki, has been generated in close association with the unique tectonic regime, as in the northernmost part of the Izu–Bonin volcanic arc where three (or four) plates converged.
Petrological and geochemical investigations were performed on the uniquely distributed Nanzaki ba... more Petrological and geochemical investigations were performed on the uniquely distributed Nanzaki basanite (0.43 Ma) in the northern part of the Izu–Bonin volcanic arc, Japan, to clarify its original magma chemistry, and to constrain the source mantle and formation process of the magma. The Nanzaki basanite (monogenetic volcano) is mainly composed of nepheline-bearing basanite lava and scoria. The mineral chemistries are characterized by high forsterite (Fo) contents of olivines, high Mg# (=Mg/(Mg + Fe)) values of clinopyroxenes, and low Cr# (=Cr/(Cr + Al)) values of spinels.Whole-rock major element contents have narrow variation ranges as follows: SiO2 (41.5–44.1%), MgO (10.2–13.1%), CaO (11.9–13.3%), and K2O (0.4–1.9%). Combined with these mineral and whole rock chemistries, the lowFeO*/MgO (0.81–1.09) values, high Ni and Cr contents, and narrowly distributed rare earth element (REE) patterns of theNanzaki basanite represent the primary (undifferentiated) chemical features of the magmas. The incompatible trace element characteristics, especially the high Sr, Ba, and REE contents and low K, Rb, Zr, Hf, and Ti contents, suggest that the basanite magmas were generated from an enriched mantle that was affected by metasomatism with carbonatite magma (or carbonate-melt). In addition, the slight enrichment of Pb, Cs and other alkaline elements in the basanites indicates the close concern of fluids, and the Sr–Nd isotope characteristics of the basanites (low 87Sr/86Sr and 143Nd/144Nd ratios relative to those of basaltic rocks in the volcanic front) are consistentwith across arc isotopic variations of the Izu–Bonin volcanic arc. Themetasomatismof the source mantle by carbonatite (or carbonate-rich)meltwas associated with and potentially facilitated by the infiltration and interaction of some volatile components (CO2, H2O) from the subducting slab. Thus, it is presumed that the enriched and metasomatizedmantle parts have been present, ubiquitously in some regions of the mantle wedge, and that the basaniticmagma, as in the Nanzaki, has been generated in close association with the unique tectonic regime, as in the northernmost part of the Izu–Bonin volcanic arc where three (or four) plates converged.
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Papers by Yoji Arakawa
(0.43 Ma) in the northern part of the Izu–Bonin volcanic arc, Japan, to clarify its original magma chemistry,
and to constrain the source mantle and formation process of the magma. The Nanzaki basanite (monogenetic
volcano) is mainly composed of nepheline-bearing basanite lava and scoria. The mineral chemistries are characterized
by high forsterite (Fo) contents of olivines, high Mg# (=Mg/(Mg + Fe)) values of clinopyroxenes, and
low Cr# (=Cr/(Cr + Al)) values of spinels.Whole-rock major element contents have narrow variation ranges
as follows: SiO2 (41.5–44.1%), MgO (10.2–13.1%), CaO (11.9–13.3%), and K2O (0.4–1.9%). Combined with these
mineral and whole rock chemistries, the lowFeO*/MgO (0.81–1.09) values, high Ni and Cr contents, and narrowly
distributed rare earth element (REE) patterns of theNanzaki basanite represent the primary (undifferentiated)
chemical features of the magmas. The incompatible trace element characteristics, especially the high Sr, Ba, and
REE contents and low K, Rb, Zr, Hf, and Ti contents, suggest that the basanite magmas were generated from an
enriched mantle that was affected by metasomatism with carbonatite magma (or carbonate-melt). In addition,
the slight enrichment of Pb, Cs and other alkaline elements in the basanites indicates the close concern of fluids,
and the Sr–Nd isotope characteristics of the basanites (low 87Sr/86Sr and 143Nd/144Nd ratios relative to those of
basaltic rocks in the volcanic front) are consistentwith across arc isotopic variations of the Izu–Bonin volcanic arc.
Themetasomatismof the source mantle by carbonatite (or carbonate-rich)meltwas associated with and potentially
facilitated by the infiltration and interaction of some volatile components (CO2, H2O) from the subducting
slab. Thus, it is presumed that the enriched and metasomatizedmantle parts have been present, ubiquitously in
some regions of the mantle wedge, and that the basaniticmagma, as in the Nanzaki, has been generated in close association with the unique tectonic regime, as in the northernmost part of the Izu–Bonin volcanic arc where
three (or four) plates converged.
(0.43 Ma) in the northern part of the Izu–Bonin volcanic arc, Japan, to clarify its original magma chemistry,
and to constrain the source mantle and formation process of the magma. The Nanzaki basanite (monogenetic
volcano) is mainly composed of nepheline-bearing basanite lava and scoria. The mineral chemistries are characterized
by high forsterite (Fo) contents of olivines, high Mg# (=Mg/(Mg + Fe)) values of clinopyroxenes, and
low Cr# (=Cr/(Cr + Al)) values of spinels.Whole-rock major element contents have narrow variation ranges
as follows: SiO2 (41.5–44.1%), MgO (10.2–13.1%), CaO (11.9–13.3%), and K2O (0.4–1.9%). Combined with these
mineral and whole rock chemistries, the lowFeO*/MgO (0.81–1.09) values, high Ni and Cr contents, and narrowly
distributed rare earth element (REE) patterns of theNanzaki basanite represent the primary (undifferentiated)
chemical features of the magmas. The incompatible trace element characteristics, especially the high Sr, Ba, and
REE contents and low K, Rb, Zr, Hf, and Ti contents, suggest that the basanite magmas were generated from an
enriched mantle that was affected by metasomatism with carbonatite magma (or carbonate-melt). In addition,
the slight enrichment of Pb, Cs and other alkaline elements in the basanites indicates the close concern of fluids,
and the Sr–Nd isotope characteristics of the basanites (low 87Sr/86Sr and 143Nd/144Nd ratios relative to those of
basaltic rocks in the volcanic front) are consistentwith across arc isotopic variations of the Izu–Bonin volcanic arc.
Themetasomatismof the source mantle by carbonatite (or carbonate-rich)meltwas associated with and potentially
facilitated by the infiltration and interaction of some volatile components (CO2, H2O) from the subducting
slab. Thus, it is presumed that the enriched and metasomatizedmantle parts have been present, ubiquitously in
some regions of the mantle wedge, and that the basaniticmagma, as in the Nanzaki, has been generated in close association with the unique tectonic regime, as in the northernmost part of the Izu–Bonin volcanic arc where
three (or four) plates converged.