Hydrogeochemical anomalies associated with the 2017 MW 5.5 Pohang earthquake in South Korea

Abstract

<p><span lang="EN-US">The 2017 M<sub>W</sub> 5.5 Pohang earthquakes, which were known as triggered by enhanced geothermal system (EGS) stimulations, had significant effects on the groundwater system. This study aimed to identify the hydrogeochemical anomalies and to understand the response mechanisms of groundwater system to the earthquake. For this, the environmental isotopes (<sup>222</sup>Rn, Sr, <sup>2</sup>H, and <sup>18</sup>O), major ions, and time-series data (groundwater level, temperature, and electrical conductivity) were analyzed. Principal component analysis (PCA) was also employed. The results from time-series data showed the anomalies in the groundwater wells located near the epicenter. The hydrochemical parameters including stable isotopes data of <sup>2</sup>H and <sup>18</sup>O showed the different change patterns among groundwater wells before/after the earthquakes, which were related to the distance from epicenter, faults, and seawater. The environmental isotopes, radon and strontium, suggested the possible mechanisms underlying the effects of earthquakes by spatial distributions, such as seawater intrusion, water-rock interactions, shallow and deep aquifer mixing, deep fluid upwelling, and bedrock fracture opening. With this, the main cluster of PCA results was also distributed along these isotope concentration gradients. </span></p> <p><span lang="EN-US">Our findings proved the usefulness of environmental isotopes and hydrogeochemical parameters to understand the earthquake-related changes in groundwater system. </span><span lang="EN-US">These studied parameters and the adopted methods would be positively applied for other earthquake zones.</span></p>