3:30 PM - 3:45 PM
[AHW25-07] Shallow groundwater connectivity between upland and lowland, eastern Tokyo, Japan
Keywords:Upland, Lowland, Topographical boundary, Spring, Groundwater, Groundwater connectivity
This study aims to clarify groundwater connectivity between upland and lowland at topographical boundary, in urbanized area, eastern Tokyo.
In 2023 and 2024, spring, river and groundwater were corrected in the eastern part of Tokyo. Then, concentrations of inorganic dissolved ions and stable isotopic compositions of hydrogen (δ2H) and oxygen (δ18O) were analyzed.
Total anion and cation concentrations in spring were lower than that in groundwater, and the chemical characteristics in the spring and the groundwater changed from Ca-HCO3 dominant type to Na-HCO3 dominant type between upland and lowland. However, some spring and groundwater showed Ca-HCO3 dominant type both upland and lowland. The δ18O in spring was more than -8.0‰ and higher than that of groundwater. And δ18O of groundwater in eastern lowland was less than -9.0‰ and lower than that in upland ranging from -8.0 to -9.0‰.
The shallow groundwater shows solution characteristics of Ca-HCO3 dominant type and δ18O of approximately -8.0‰ in both upland and lowland areas, whereas the deep groundwater shows solution characteristics of Na-HCO3 dominant type and δ18O ranging from -8.0 to -9.0‰ in lowland.
This suggests that the shallow groundwater seems to have connectivity between upland and lowland in a zone with a depth of approximately 10 to 50 m, whereas the deep groundwater in lowland would be sourced from the water recharged at the mountainous area with low δ18O.
In 2023 and 2024, spring, river and groundwater were corrected in the eastern part of Tokyo. Then, concentrations of inorganic dissolved ions and stable isotopic compositions of hydrogen (δ2H) and oxygen (δ18O) were analyzed.
Total anion and cation concentrations in spring were lower than that in groundwater, and the chemical characteristics in the spring and the groundwater changed from Ca-HCO3 dominant type to Na-HCO3 dominant type between upland and lowland. However, some spring and groundwater showed Ca-HCO3 dominant type both upland and lowland. The δ18O in spring was more than -8.0‰ and higher than that of groundwater. And δ18O of groundwater in eastern lowland was less than -9.0‰ and lower than that in upland ranging from -8.0 to -9.0‰.
The shallow groundwater shows solution characteristics of Ca-HCO3 dominant type and δ18O of approximately -8.0‰ in both upland and lowland areas, whereas the deep groundwater shows solution characteristics of Na-HCO3 dominant type and δ18O ranging from -8.0 to -9.0‰ in lowland.
This suggests that the shallow groundwater seems to have connectivity between upland and lowland in a zone with a depth of approximately 10 to 50 m, whereas the deep groundwater in lowland would be sourced from the water recharged at the mountainous area with low δ18O.