EGU2020-7993
https://doi.org/10.5194/egusphere-egu2020-7993
EGU General Assembly 2020
© Author(s) 2020. This work is distributed under
the Creative Commons Attribution 4.0 License.

The research of Meinong earthquake induced hydrological anomalies and increased vertical permeability in southwestern Taiwan

Yan-Yao Lin1, Shih-Jung Wang2, and Wen-Chi Lai3
Yan-Yao Lin et al.
  • 1Graduate Institute of Applied Geology, National Central University, Taoyuan, Taiwan (yorkhp322917@gmail.com)
  • 2Graduate Institute of Applied Geology, National Central University, Taoyuan, Taiwan (sjwang1230@gmail.com)
  • 3Disaster Prevention Research Center, National Cheng Kung 9 University, Tainan, Taiwan (laiwenji@dprc.ncku.edu.tw)

Hydrological anomalies induced by the earthquakes are valuable research data to understand the hydrogeology structure. At the same time, a complete hydrogeological data is the key to the study of earthquake hydrology. In this research, we collected the anomalous hydrological data after the Mw 6.4 2016 Meinong Earthquake in Taiwan. The main purpose is to know the mechanism of hydrological changes triggered by earthquake and understand the local hydrogeological characteristics in the southern Taiwan.

From the distribution of the groundwater level change in the same location but different depths of aquifer, as well as the location of the rupture and liquefaction, it could be found that the co-seismic groundwater level change is large in Chianan Plain in the northwest of the epicenter and accompanied with a lot of ruptures and liquefactions located along the Hsinhua Fault. However, the observations in several wells around the Hsinhua Fault show a different water level change pattern compared with the other wells in Chianan Plain. Actually, these wells show that the co-seismic groundwater level decreases in the deep aquifer and increase in the shallow aquifer. It is shown that the Meinong Earthquake may enhance the connectivity between different aquifers near the fault zone and produce an increased vertical pressure gradient. The anomalous hydrological phenomenon also reflected in the river flow. Based on the river flow data we collected from five stations in the Zengwun River watershed, the river flow at two stations in the upstream dose not change after earthquake. There is a little increase at the midstream station. However, a large river flow increase is observed at the downstream station. After excluding the influence of rainfall, we think that the large amount of anomalous flow is caused by the rise of the co-seismic groundwater level between the middle and downstream sections, and a large amount of liquefaction in this area can prove this hypothesis.

The hypothesis of connectivity changes between different aquifers can be verified by analyzing the tidal response of different aquifers. Many studies have used the tide analysis to obtain the aquifer permeability and compressibility, and compared the changes in the analysis results before and after the earthquake. We think that if different aquifers are vertically connected after earthquake, the tidal analysis results should show a consistent permeability. Tidal analysis is executing now and the results will be provided at conference.

How to cite: Lin, Y.-Y., Wang, S.-J., and Lai, W.-C.: The research of Meinong earthquake induced hydrological anomalies and increased vertical permeability in southwestern Taiwan, EGU General Assembly 2020, Online, 4–8 May 2020, EGU2020-7993, https://doi.org/10.5194/egusphere-egu2020-7993, 2020