Aso volcano is located on the volcanic front at the northern end of the Kyushu-Ryukyu arc, and four large pyroclastic eruptions ranging from about 266 ka (Aso-1) to 89 ka (Aso-4) formed a large caldera. The volcanic activity can be divided into three stages in chronological order: the pre-Aso volcanic rocks (ca. 400-800 ka), the caldera-forming stage, and the post-caldera stage (e.g., Ono and Watanabe, 1985).
With some exceptions, volcanic products of the caldera-forming stage and the post-caldera stage are enriched in liquid-phase enrichment elements such as K₂O, but this is not the case for the Pre-Aso volcanic rocks. The upper limit of Sr isotopic ratios varies with time, with a lower limit of about 0.704 throughout the entire periods, and the reported upper limits of Sr isotopic ratios for different time periods are 0.704462 for pre-Aso volcanic rocks, 0.70422 for essential materials of pyroclastic flow deposits, and 0.704355 for volcanic products of post-caldera, except for some (e.g., Hunter, 1988; Furukawa et al, 2008; Miyoshi et al., 2011; Shinmura et al., 2013). It is highest in the pre-Aso, becomes lower in the caldera-forming stage, and rises again in the post-caldera stage. In this study, we measured the whole-rock chemical compositions and Sr isotopic ratios of six volcanic rocks from the Pre-Aso volcanic rocks before and after the Aso-1 eruption, and tried to clarify the changes in magma composition at the beginning of the entire Aso caldera eruption.
We collected three samples of pre-Aso volcanic rocks (Watanabe et al., 2021) from a stream on the approach to the Iwato Shrine in the Tateno Valley, two samples of Koga lava (Tajima et al., 2017) with an age of 275 ± 11 ka from a part of the east wall of the caldera, and one sample of Hokamaki lava (Aso-1/2 lava, Watanabe et al., 2021) from near the Seta Shrine in the Tateno Valley. All rocks are andesite. The chemical composition of the whole rock was determined by an X-ray fluorescence spectrometer installed at the Kitakyushu Museum of Natural History & Human History, and the Sr isotope ratio was determined by a thermal ionization mass spectrometer (TIMS) (Finnigan MAT262) at Tsukuba University and a TIMS (Thermo Fischer Scientific TRITON Plus TIMS) at Kumamoto University. The major elemental compositions of SiO₂ wt.%, K₂O wt.%, and Sr isotopic ratios (⁸⁷Sr/⁸⁶Sr) were 57-61, 2.3-3.0, 0.70422-0.70424 for the Pre-Aso volcanic rocks, 55-58, 1.8-2.7, 0.70405-0.70421 for the Koga lava, and 60, 2.9, 0.70399 for the Hokamaki lava, respectively.
The K₂O content in Koga and Hokamaki lava tends to be high relative to the SiO₂ content as in the post-caldera volcanic products. The Sr isotopic ratio of the Koga lava is almost equal to the upper limit of the Aso-1 pyroclastic flow deposits, and that of the Hokamaki lava is around the lower limit of the volcanic products from the pre-Aso volcanic rocks to the post-caldera stage. In addition, the amount of K₂O to SiO₂ is high in all three samples, which is not a characteristic of general pre-Aso volcanic rocks, but a characteristic of the post-caldera period. The Sr isotopic ratios of all three samples are slightly higher than the upper limit of the Aso-1 pyroclastic flow deposits, and much lower than the upper limit of 0.70446 for the entire Pre-Aso volcanic rocks, which is consistent with the post-caldera period characteristics. The age of the pre-Aso volcanic rocks in this study from the Tateno Valley, western part of Aso caldera, has not been measured, but in the area where these rocks are distributed, the pre-Aso volcanic rocks are in contact with Aso-1 and Aso-2 (Watanabe et al., 2021). Therefore, it is thought that these rocks are relatively young among the pre-Aso volcanic rocks and were active at a time close to that of Aso-1, and magma with similar properties existed underground in the western part of the caldera before the Aso-1 eruption, and that there was activity to erupt these magma before Aso-1 like Koga lava in the eastern part of caldera.