日本地球惑星科学連合2019年大会

講演情報

[E] ポスター発表

セッション記号 A (大気水圏科学) » A-HW 水文・陸水・地下水学・水環境

[A-HW22] 流域の物質輸送と栄養塩循環-源流域から沿岸海域まで-

2019年5月30日(木) 15:30 〜 17:00 ポスター会場 (幕張メッセ国際展示場 8ホール)

コンビーナ:小林 政広(国立研究開発法人森林研究・整備機構 森林総合研究所)、吉川 省子(農業・食品産業技術総合研究機構 農業環境変動研究センター)、安元 純(琉球大学 農学部 地域農業工学科)、Adina Paytan(University of California Santa Cruz)

[AHW22-P03] 島嶼沿岸地下水における季節的な水位変動にともなう流動系の変動について

*友澤 裕介1小野寺 真一1齋藤 光代2 (1.広島大学大学院総合科学研究科、2.岡山大学大学院環境生命科学研究科)

キーワード:安定同位体比、地下水、沿岸

In islands, freshwater water resources are valuable as living and agricultural use, and dug wells water and reservoirs had been utilized for more than 100 years. In order to use such water resources sustainably, it is important to evaluate groundwater flow as well as water budget.

In this research, we examined to confirm the seasonal variation in water stable isotopic ratios in observation boreholes at the coastal lowland in Ikuchi Island Hiroshima prefecture. Moreover, considering that the target area is coastal, Cl- concentration was analyzed to evaluate the influence of salt fresh water boundary.

The experimental site is located on Ikuchi Island in Hiroshima prefecture. The highest altitude is 456 m. The basement rock is mainly composed of granite. Annual average precipitation is 1058.8 mm. Observation boreholes are located at the coastal lowland in the southeastern part of the island. The upper site (Site U) with the altitude of 5.1 m asl has 3 boreholes with the depths of 2 m, 15 m, 30 m, the lower site (Site D) with 2.5 m asl has 8 with the depth of 1 m, 2 m, 3 m, 10 m, 15 m, 20 m, 30 m, 40 m, respectively. The water sampling was carried out from monthly to half year interval since 2015. Every samples were analyzed for water isotopic ratios by PICARO and anion component by ion chromatography. Especially samples in January in 2019 were analyzed for CFCs and SF6.

Based on the previous study (Saito and Onodera, 2007), the distinct altitude effect of isotopic ratio in precipitation has been confirmed. Due to spatial and temporal variations in isotopic ratios, recharge process to groundwater was suggested as follows, 1) recharge on site to shallow groundwater (2-3m deep) at D (δ18O: -7.8 to - 7.4 ‰), 2) river water contribution to the shallow groundwater (2-15m) at U (δ18O: - 8.3 to - 7.5 ‰), 3) recharge in the mountain slope with the altitude of about 360 m to deep groundwater (30m) at U (δ18O: - 8.4 to - 8.1 ‰), 4) recharge at 400 m on near the mountain top to deep groundwater (10-30 m) at D(δ18O: - 8.7 to - 8.4 ‰), 5) recharge of precipitation with lower isotope than in present to deeper groundwater (40 m) at D (δ18O: -8.9 to - 8.8 ‰)

The deepest groundwater (40m) at D had lower isotopic ratios with higher Cl- concentration (250 to 584 mg / L) during a lower water table in the winter. This indicated the seawater – fresh water boundary rose with water table according to Gyben-Hrzberg concept. These phenomena also suggest to cause the rise of deeper and older groundwater flow line. Consequently, we suggest the lower isotopic ratio in deeper groundwater indicates the immobile water which were recharged in the glacial period. Based on other tracers (CFC, SF 6), we will discuss more.