JpGU-AGU Joint Meeting 2020

講演情報

[E] ポスター発表

セッション記号 U (ユニオン) » ユニオン

[U-05] 人新世・第四紀の気候および水循環

コンビーナ:Chuan-Chou Shen(High-Precision Mass Spectrometry and Environment Change Laboratory, Department of Geosciences, National Taiwan University)、横山 祐典(東京大学 大気海洋研究所 高解像度環境解析研究センター)、窪田 薫(神戸大学大学院人間発達環境学研究科)、Li Lo(Department of Geosciences, National Taiwan University)

[U05-P05] High-resolution Holocene records of a stalagmite from maritime Japan

*雨川 翔太1狩野 彰宏1柏木 健司2森 大器3白石 史人4沈 川洲5,6,7 (1.東京大学大学院理学系研究科、2.富山大学理学部生物圏環境学科、3.九州大学地球社会統合科学府、4.広島大学理学研究科地球惑星システム学講座、5.国立台湾大学地球科学専攻高精度質量分析環境変動研究室、6.国立台湾大学地球環境研究センター、7.国立台湾大学フューチャーアース研究センター)

キーワード:石筍、安定同位体比、微量元素、東アジア夏季モンスーン、完新世

In East Asia, the climatic factor for the lowered meteoric water δ18O during mid-Holocene than the last glacial period is still controversial. Previous interpretations on stalagmite δ18O were recently re-examined with new records from the maritime Japan, in eastern part of the Asian monsoon region beyond the influence from Indian summer monsoon (Mori et al. 2018). However, their stalagmite presented limited records in the Holocene section because of low growth rate. Here, we report another stalagmite from the same cave (Kiriana cave in Mie Prefecture), which provides high-resolution records of stable isotopes and trace element during Holocene.
The ages of the 34-cm-long stalagmite were determined at 17 horizons through Uranium-Thorium dating method at the National Taiwan University. Stable isotopes were measured at 0.2-mm intervals using an isotope ratio mass spectrometer (Thermo Finnigan DeltaPlus) connected with an on-line gas separation and introduction system (GASBENCH II) at the Kyushu University. Trace element analysis was performed with inductivity coupled plasma optical emission spectrometer (iCAP7200, Thermo Fisher Scientific) at the Hiroshima University.
The stalagmite δ18O displays similar temporal patterns with the Chinese records but exhibits much smaller amplitude of δ18O than the Chinese records. This result supports the idea of Mori et al. (2018) that the stalagmite δ18O record from this cave is a superimposed signal of variations in air temperature and seawater δ18O, rather than the hydroclimatic control on meteoric water δ18O . On the other hand, δ13C of the stalagmite has more than 2‰ shift from mid- to late-Holocene with ~1‰ excursions in millennial timescale. The variation synchronized with Mg/Ca suggests that the δ13C change is largely affected by prior calcite precipitation (PCP) from the infiltrating water in the karst bedrock, which generally increases under a dry condition. Supposing that δ13C record of this stalagmite reflects PCP induced by precipitation change, we propose that precipitation or EASM variability is recorded more clearly in δ13C rather than δ18O of stalagmite in maritime Japan.