Abstract
Changes in the hydrochemical conditions of groundwater were evaluated following the construction of a large-scale underground facility at the Mizunami Underground Research Laboratory (MIU), Japan. The facility was constructed to a depth of 500 m in sedimentary and granitic rocks. Drawdown of the groundwater level in the range of several tens to hundreds of meters was observed up to hundreds of meters away from the shafts during the first ten years of facility construction and operation. Subsequent changes in groundwater chemistry occurred due to upconing of high-salinity groundwater from the deepest part of the shaft and the infiltration of low-salinity shallow groundwater. We predict that future deep groundwater chemistry in the vicinity of the MIU facility will resemble that of the present-day shallow groundwater. Multivariate statistical analysis provides fundamental insights into such a site. We found that the extent of hydrochemical variability related to MIU construction and operation was dependent on the distance from the facility shafts and galleries and on hydrogeological compartmentalization resulting from lithological boundaries (such as permeable conglomerates vs. more compact lithological units) and other features (such as faults or clay layers). We conclude that hydrochemical impact assessment of groundwater in low-permeability rock is essential prior to the construction of such a facility. This should include characterization of hydrogeological structures and compartments to propose suitable location of shafts and galleries.
Highlights
The characterization of hydrochemical features and processes in the bedrock of underground facilities is important for the engineering and geosciences fields
We predict that future deep groundwater chemistry in the vicinity of the Mizunami Underground Research Laboratory (MIU) facility will resemble that of the present-day shallow groundwater
We found that the extent of hydrochemical variability related to MIU construction and operation was dependent on the distance from the facility shafts and galleries and on hydrogeological compartmentalization resulting from lithological boundaries and other features
Summary
The characterization of hydrochemical features and processes in the bedrock of underground facilities is important for the engineering and geosciences fields. Environ Earth Sci (2015) 74:3041–3057 in the Aspo Hard Rock Laboratory, Sweden, showed that hydraulic disturbances occurred in the crystalline rock (Grenier et al 2009), leading to a drawdown of the groundwater level by tens of meters and the penetration of tritium containing groundwater into the laboratory (Laaksoharju et al 1999; Mahara et al 2001) Another case of groundwater level drawdown was observed at the Underground Research Laboratory in Manitoba, Canada, where 60 m drawdown of the groundwater level occurred around two shafts in the Lac du Bonnet granite batholith over a 25-year period of construction and operation at a depth of more than 420 m. Groundwater inflow along fractures and faults intersected by the shafts leads to the mixing of distinctly different saline groundwaters and significantly changes the water chemistry (Priyanto et al 2014)
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