Melting, assimilation, storage, and homogenization (MASH) processes occur at the mantle–crust transition where hot basaltic magmas ascend from the mantle wedge reach neutrally buoyant point¹. The MASH zone segregates based on density differences with fractional crystallization and/or crustal melting creating cumulate at the lower crust and felsic melts transported to shallower crust¹. This crust–mantle interaction contributes to crustal evolution on Earth. In this study we discuss temporal development of the crust–mantle interaction using whole-rock major/trace element and Sr-Nd-Pb isotope data of Futamatayama volcano, Nasu volcano group, NE Japan.
The basement rocks of Futamatayama volcano include 1.4–1.0 Ma Shirakawa ignimbrites. Eruptive activity of Futamatayama volcano consists of two stages: Stage 1 (ca. 160–90 ka, 3.56 km³DRE) repeatedly ejected lava flows with a small volume pyroclastic flow; Stage 2 (between ca. 90 to 50 ka, 0.09 km³DRE) formed lava domes accompanied with pyroclastic flow². Eruption products commonly contain mafic enclaves hosted by more felsic rocks. Based on petrography and whole-rock compositions, the eruption products can be divided into four main rock types: F-1 (felsic magma in Stage 1), F-2, M-1, and M-2. Felsic types (F-1 and F-2) are andesite to dacite containing phenocrysts of plagioclase + clinopyroxene + orthopyroxene + opaque mineral ± quartz ± olivine. Mafic types (M-1 and M-2) are basalt to basaltic andesite including phenocrysts of plagioclase + clinopyroxene + orthopyroxene + opaque mineral ± olivine. Eruptive products of Stages 1 and Stage 2 form distinct linear trends indicative of magma mixing between M-1 and F-1 in Stage 1, M-2 and F-2 in Stage 2, respectively.
Mafic magmas (M-1 and M-2) show high Ba/Th, low Zr/Sm and Hf/Sm, depleted Sr-Nd isotope, that are characteristics of mantle-derived arc basalts. Identical incompatible element ratio (e.g., Ba/Nb, K₂O/Rb) of the most mafic samples from M-1 and M-2 indicate that the both mafic magmas are produced from a common mantle source. Higher Cr and Ni contents of M-1 (Cr = 200 ppm, Ni = 90 ppm at ~50 wt.% SiO₂) than those of M-2 (Cr = 30 ppm, Ni = 40 ppm at ~50 wt.% SiO₂) suggest that M-2 can be generated by olivine and pyroxene fractionation from the common primitive magma with M-1.
Felsic magmas (F-1 and F-2) show high Zr/Sm, low K₂O/Rb, Eu/Eu* features that can be explained by partial melting of lower crust with the presence of amphibole and plagioclase as melting residues. The Sr-Nd isotopic ratios of F-1 (⁸⁷Sr/⁸⁶Sr = 0.7047–0.7049, ¹⁴³Nd/¹⁴⁴Nd = 0.51270–0.51274) are similar to those of Kumado ignimbrite, which is a member of Shirakawa ignimbrites. Isotope composition of F-2 (⁸⁷Sr/⁸⁶Sr = 0.7045–0.7047, ¹⁴³Nd/¹⁴⁴Nd = 0.51274–0.51278) is consistent with that of M-1. These results suggest that, in Stage 1, mantle-derived M-1 magma intruded into (or underplated at) lower crust and partially melted pre-existing crustal material, which might be a common source of Kumado ignimbrite, produced F-1 magma. Also, M-1 magma formed cumulate (amphibolite or amphibole-bearing gabbro) in Stage 1. In Stage 2, F-2 magma might be produced by remelting of the cumulative lower crust by the intrusion of more differentiated mafic magma (M-2). Felsic and mafic endmember magmas mixed and erupted in each stage.

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