The impact of low-temperature seasonal aquifer thermal energy storage (SATES) systems on chlorinated solvent contaminated groundwater: Modeling of spreading and degradation
Publication date
2013
Authors
Zuurbier, K.G.
Hartog, N.
Valstar, J.
Post, V.E.A.
Breukelen, B.M. van
Editors
Advisors
Supervisors
Document Type
Article
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(c) UU Universiteit Utrecht, 2013
Abstract
Groundwater systems are increasingly used for seasonal aquifer thermal energy storage
(SATES) for periodic heating and cooling of buildings. Its use is hampered in contaminated
aquifers because of the potential environmental risks associated with the spreading of
contaminated groundwater, but positive side effects, such as enhanced contaminant
remediation, might also occur. A first reactive transport study is presented to assess the effect
of SATES on the fate of chlorinated solvents by means of scenario modeling, with emphasis on
the effects of transient SATES pumping and applicable kinetic degradation regime.
Temperature effects on physical, chemical, and biological reactions were excluded as
calculations and initial simulations showed that the small temperature range commonly
involved (ΔTb15 °C) only caused minor effects. The results show that a significant decrease of
the contaminant mass and (eventually) plume volume occurs when degradation is described
as sediment-limited with a constant rate in space and time, provided that dense non-aqueous
phase liquid (DNAPL) is absent. However, in the presence of DNAPL dissolution, particularly
when the dissolved contaminant reaches SATES wells, a considerably larger contaminant
plume is created, depending on the balance between DNAPL dissolution and mass removal by
degradation. Under conditions where degradation is contaminant-limited and degradation
rates depend on contaminant concentrations in the aquifer, a SATES system does not result in
enhanced remediation of a contaminant plume. Although field data are lacking and existing
regulatory constraints do not yet permit the application of SATES in contaminated aquifers,
reactive transport modeling provides a means of assessing the risks of SATES application in
contaminated aquifers. The results from this study are considered to be a first step in
identifying the subsurface conditions under which SATES can be applied in a safe or even
beneficial manner.
Keywords
SATES, Groundwater, Remediation, Reactive transport modeling