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Abstract

A numerical model of the complex interaction between fluid flow, heat transfer, and chemical reactions of the shallow, coastal, hydrothermal system of Waiwera (New Zealand) is used to test the proposed conceptual model of the field. Due to declining water levels, resulting from over-exploitation during the 1970s, the objective here was to set up a coupled fluid flow and heat transfer model to help in enabling a predictive and sustainable use of the resource. The presented conceptual model of the area is based on hydraulic, thermal, and chemical field observations, which date back as far as 1863. The numerical simulations were carried out with the reactive transport code SHEMAT. The inflow of geothermal water at the bottom of the reservoir prevents seawater from entering the aquifer. If seawater intrusion occurs, it is due to over-exploitation and happens in the upper parts of the aquifer. This is in contrast to common seawater-freshwater interfaces where seawater intrudes at the bottom. The numerical investigations emphasize that, after modifications of the production regime in the late 1980s, the system is recovering again. Additionally, geochemical calculations have been conducted to answer the question if dissolution or precipitation reactions might change the hydraulic properties of the geothermal aquifer. Mixing of fresh, geothermal, and seawater, although each of them in thermodynamic equilibrium with calcite, lead to calcite precipitation or dissolution. Nevertheless, the simulations show that the hydraulic properties of the aquifer are not significantly affected by dissolution or precipitation.