JpGU-AGU Joint Meeting 2017

講演情報

[EJ] 口頭発表

セッション記号 H (地球人間圏科学) » H-CG 地球人間圏科学複合領域・一般

[H-CG30] [EJ] 堆積・侵食・地形発達プロセスから読み取る地球表層環境変動

2017年5月24日(水) 15:30 〜 17:00 106 (国際会議場 1F)

コンビーナ:清家 弘治(東京大学大気海洋研究所)、高柳 栄子(東北大学大学院理学研究科地学専攻)、成瀬 元(京都大学大学院理学研究科)、山口 直文(茨城大学 広域水圏環境科学教育研究センター)、座長:山口 直文(茨城大学 広域水圏環境科学教育研究センター)、座長:清家 弘治(東京大学大気海洋研究所)

15:45 〜 16:00

[HCG30-08] 瀬戸内区中部中新統におけるバーティソルの発見とそれが示す古風化・古気候条件

*葉田野 希1吉田 孝紀2 (1.信州大学大学院総合工学系研究科、2.信州大学理学部地球学コース)

キーワード:古土壌、バーティソル、化学風化、微地形、地化学、中期中新世

The description of paleosols, chemical and mineralogical analysis and sedimentary facies analysis were carried out for the Middle Miocene Seto Porcelain Clay Formation distributed in the Toyota City, Aichi Prefecture. The main paleosol characterized by hummock-and-swale structure showing gilgai microrelief and mukkara subsurface horizon is equivalent to Vertisol (Soil Survey Staff, 1999). This result indicates that climatic conditions in this period were subhumid to semiarid climates with a pronounced dry season.

The Seto Porcelain Clay Formation, the lower member of the Seto Group, distributed in the Aichi Prefecture, is considered to be deposited in the middle Miocene period (6-9 Ma) dated by the paleomagnetic data (Nakayama and Yoshikawa, 1990; Nakayama et al., 1995).
The Sedimentary facies analysis suggests that deposition occurred mainly in a lacustrine, backswamp and floodplain with meandering river channel.
Three paleosol horizons were developed in the stagnant water sediments and have been described and compared to modern soils; versitol-like (swelling clay soils), histosol-like (peaty soils) and inceptisol-like (young soils). Histosol-like paleosol and inceptisol-like paleosol were developed on lowland topography. Histosol-like paleosol, characterized by thick peaty horizon and reddish mottling showing subsurface-water gleization, ascribes to poor-drainage condition on the lower topography and high vegetation cover. Inceptisol-like paleosol, characterized by thin soil horizon and poor illuviated clay, ascribes to lower topography and rapid sedimentation with short exposure duration. These paleosols, therefore, reflect on the local topographic and/or sedimentary features, for example drainage condition, vegetation cover and sedimentation rate. On the other hand, the vertisol-like paleosol was developed on the flat terrace with gentle slope. The paleosol is characterized by illuviated clay-rich B horizon (Bt horizon, argillic horizon), hummock-and-swale structure showing gilgai microrelief and mukkara subsurface horizon (Paton, 1974). The strongly differentiated soil horizons of versisol-like paleosol reflect on the X-ray bulk and clay-fraction mineralogy and bulk chemistry of soil profiles. The paleosol shows vertical fluctuating of chemical weathering ratio (Al2O3 wt. % /Na2O wt. % and CIA value; Nesbitt and Young, 1982), mineral weathering ratio (kaolinite/feldspar ratio by intensity of XRD) and proportion of clay fraction in the soil horizons. Higher chemical and mineral weathering ratio and finer grain size in the Bt horizons than those in the Bw and C horizons suggest pronounced leaching of cation from surface soil horizons (O and A horizons) and their accumulation in sub-surface soil horizons (B and C horizons). Besides, the effects of parent material and grain size have been checked by using REE composition (especially by Eu anomaly) and clay minerals/quartz ratio by intensity of XRD and Al2O3 wt. % /SiO2 wt. %.
Above described vertisol-like paleosol, accordingly, indicates the typical soil type that represents the climatic division (zonal soil) in the period. The results are suggestion that the climatic conditions in this period were subhumid to semiarid climates with a pronounced dry season.

References
Nakayama, K. and Yoshikawa, S., 1990, Magnetostratigraphy of the late Cenozoic Tokai Group in central Japan. Journal of Geological Society of Japan 96, 967-976.
Nakayama, K., Yoshikawa, S. and Ito, T., 1995, Magnetostratigraphy of the Late Cenozoic Tokai Group in central Japan and its sedimentologic implications. Journal of Southeast Asian Earth Sciences 12, 95-104.
Nesbitt, H.W. and Young, G.M., 1982, Early Proterozoic climates and plate motions inferred from major element chemistry of lutites. Nature 299, 715-717.
Paton, T.R., 1974, Origin and terminology for gilgai in Australia. Geoderma 11, 221-242.
Soil Survey Staff, 1999, Keys to Soil Taxonomy. Pocahontas Press Inc., Blacksburg, Virginia, USA, 600 p.