Shikotsu volcano started large-scale eruption at 60ka, and erupted scoria fall and scoria flow (Shadai pyroclastic flow=Shadai pfl) deposits. The volcano repeated explosive eruptions every several thousands years, and after 10ky dormancy, caldera-forming eruption took place at 40ka. Eruptive volume of pre-caldera eruption is less than 50km³ and that of caldera-forming eruption is ca. 400km³ (Yamagata, 1994). We collect samples of Shadai pfl from continuous boring core, 5km-south of lake Shikotsu (JMA-V05), and clarify petrological characters to compare with those of caldera-forming eruption.
The boring core consists of soil (0-1.8m), reworked deposits (1.80-2.60m depth), Shadai pfl (2.60m-3.40m), reworked deposits (3.40m-4.25m), Shadai pfl (4.25m-18.15m), reworked deposits (18.15m-19.90m) and Shadai pfl (19.90m-101.00m), and the lowest part of pfl cannot be seen (Takarada and Furukawa, 2010). Shallow part of Shadai pfl (<18.15m) is non-welded. Juvenile materials consist mainly of banded pumice and small amount of white pumice. Weakly to strongly welded parts exist in the deeper part (53.40m-72.00m and >80.90m are strongly welded). Most of the juveniles of these parts are scoria and banded pumice.
Juvenile materials of Shadai pfl are SiO₂=53-62wt% andesite and dacite. They contain 20-40vol% phenocrysts of plagioclase, orthopyroxene, clinopyroxene and oxides (sometimes accompanying olivine). Banded pumice is heterogeneous in microscopic order. They usually make linear trends on Harker diagrams. SiO₂ contents of white pumice are SiO₂>60wt%, and most of scoria are SiO₂<56wt%. Furthermore, SiO₂ contents changes with depth. Rocks of <18.15m consist only of SiO₂=60-62wt% dacites, but SiO₂-poor materials appear from 19.90m. Andesites of SiO₂<53wt% are often found in 53.40m-72.00m and compositional range becomes the maximum. Then, SiO₂ contents concentrate to 55-62wt% in >72.00m. REE contents increase with SiO₂, however chondrite-normalized REE patterns are scattered in LREE. Ratios of MREE/LREE and HREE/LREE, together with Y/Rb, Zr/Rb and Ba/Rb, decrease as increasing SiO₂. Isotopic ratios of Sr and Nd are nearly constant for wide SiO₂ range.
Existence of banded pumice, heterogeneous texture under microscope and linear compositional trends suggest that Shadai pfl is produced mainly by magma mixing of mafic and felsic magmas. Difference of compositional range of each depth reflects that mixing ratios has changed with time. According to the constant isotopic ratios and decreasing of MREE-HREE/LREE, Y/Rb, Zr/Rb, Ba/Rb with increasing SiO₂, end-member magmas cannot be produced by simple crystal differentiation but by different degree of partial melting from the same crustal material.
Caldera-forming eruption of 40ka started with phreato-magmatic eruption and then occurred plinian eruption to flowed down the pyroclastic flow. The juveniles are classified into 2 types; dacitic to rhyolitic A-type (<5vol% phenocrysts, SiO₂=74-78wt%) and andesitic to dacitic P-type (7-45wt% phenocrysts, SiO₂=57-72wt%). A-type rocks can be seen throughout the caldera-forming eruption, but P-type exists only in the upper unit of pyroclastic flow (Nakagawa et al., 2013). Phenocryst assemblage is plagioclase, orthopyroxene, clinopyroxene, hornblende and oxides. There are evidences of magma mixing for both A and P types, however end-member magmas are different from each other. Nakagawa et al. (2010) shows that felsic magma of Shadai pfl is similar to P-type dacite of caldera-forming eruption, and suggests that the felsic magma mixes with mafic magma of low Sr isotope. As we reanalyze REE compositions and isotopic ratios of caldera-forming eruption, Sr isotopic ratio of Shadai pfl is slightly lower and Nd ratio is higher than caldera-forming eruption and Nd isotope of these eruptions make parallel trends. These suggest that origin of these eruptions is different and new magma should be produced after pre-caldera eruption.