Abstract
Abstract. Submarine groundwater discharge (SGD) has received increasing attention over the past 2 decades as a source of nutrients, trace elements and ocean pollutants that may alter coastal biogeochemical cycles. Assessing SGD flows and their impact on coastal marine environments is a difficult task, since it is not easy to identify and measure these water flows discharging into the sea. The aim of this study is to demonstrate the significant usefulness of the freely available thermal infrared (TIR) imagery of the Landsat 8 thermal infrared sensor (TIRS) as an exploratory tool for identifying SGD springs worldwide, from local to regional scales, for long-term analysis. The use of satellite thermal data as a technique for identifying SGD springs in seawater is based on the identification of thermally anomalous plumes obtained from the thermal contrasts between groundwater and sea surface water. In this study, we use the TIR remote sensing (TIR-RS) imagery provided by Landsat 8 at a regional scale and discuss the principle limiting factors of using this technique in SGD studies. The study was developed in karstic coastal aquifers in the Mediterranean Sea basin during different seasons and under diverse meteorological conditions. Although this study demonstrates that freely available satellite TIR remote sensing is a useful method for identifying coastal springs in karst aquifers both locally and regionally, the limiting factors include technical limitations, geological and hydrogeological characteristics, environmental and marine conditions and coastal geomorphology.
Highlights
Submarine groundwater discharge (SGD) is an important component of the hydrological cycle and has been commonly defined as any flow of water across the continental margin in the ocean–aquifer interface, regardless of fluid composition or driving force, with spatial scale lengths of meters to kilometers (Burnett and Dulaiova, 2003; Moore, 2010; Taniguchi et al, 2019)
This study demonstrates that freely available satellite thermal infrared (TIR) remote sensing is a useful method for identifying coastal springs in karst aquifers both locally and regionally, the limiting factors include technical limitations, geological and hydrogeological characteristics, environmental and marine conditions and coastal geomorphology
One of the main objectives of this study is to demonstrate the great usefulness of satellite TIR imagery at local and regional scales, identifying SGD springs not previously described in the scientific literature
Summary
Submarine groundwater discharge (SGD) is an important component of the hydrological cycle and has been commonly defined as any flow of water across the continental margin in the ocean–aquifer interface, regardless of fluid composition or driving force, with spatial scale lengths of meters to kilometers (Burnett and Dulaiova, 2003; Moore, 2010; Taniguchi et al, 2019). This definition includes meteoric fresh groundwater resulting from inland recharge, and seawater circulated through the sediments of coastal aquifers (Burnett and Dulaiova, 2003). According to Garcia-Orellana et al (2021), groundwater discharge pathways of SGD can be grouped into the following five different SGD pathways according to the characteristics of the processes: (1) terrestrial groundwater dis-
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