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Coastal Groundwater Dynamics in Lahaina Beaches, Hawaiʻi, and Implications for the Transport of Wildfire-Derived Contaminants
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| Type: | Resource | |
| Storage: | The size of this resource is 12.7 MB | |
| Created: | May 19, 2025 at 1:44 a.m. | |
| Last updated: | May 19, 2025 at 12:51 p.m. | |
| Published date: | May 19, 2025 at 12:51 p.m. | |
| DOI: | 10.4211/hs.fafd9b02ee3b4496830511342dab64a3 | |
| Citation: | See how to cite this resource |
| Sharing Status: | Published |
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| Views: | 31 |
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Abstract
The August 2023 wildfire in Lahaina, Maui, resulted in extensive environmental damage, including the release of untreated wastewater and combustion-derived pollutants such as nutrients and polycyclic aromatic hydrocarbons (PAHs) into the environment. This study investigates the seasonal dynamics of groundwater flow and solute transport within a tidally influenced beach aquifer affected by the wildfire. Utilizing field observations and a two-dimensional, density-dependent, variably saturated groundwater model calibrated with year-long data, we simulated groundwater flow and salinity distributions. Lagrangian particle tracking was subsequently employed to assess solute pathways and transit times under contrasting seasonal conditions. Results indicate that during the summer, the inland groundwater table in the beach is relatively higher, likely due to a delayed inland recharge signal, leading to predominantly seaward groundwater flow with rapid solute transport to the shoreline. Conversely, winter conditions, marked by enhanced tidal effects and wave activity, induce greater seawater infiltration, deeper recirculation cells, and a net inland-directed flow, leading to landward movement and retention of solutes within the aquifer. Extended transit times under these conditions enhance the potential for in-situ transformations, including sorption, microbial redox reactions, and mineral precipitation/dissolution, particularly affecting redox-sensitive species like phosphate, ammonium, and iron-bound contaminants. Spatial variability in nutrient concentrations across the beach subsurface underscores the role of tidal modulation in influencing solute export. These findings highlight the necessity of incorporating seasonal and tidal variability into coastal contaminant fate assessment and inform time-sensitive management strategies for post-wildfire recovery and the protection of nearshore ecosystems in Hawaiʻi and similar coastal regions.
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This resource is shared under the Creative Commons Attribution CC BY.
http://creativecommons.org/licenses/by/4.0/
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