Storage in confined aquifer: Spectral analysis of groundwater in responses to <scp>E</scp>arth tides and barometric effect

Shih, David Ching‐Fang

doi:10.1002/hyp.13131

Cited by 16 publications

(4 citation statements)

References 26 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The investigation performed by Xiao et al showed that the average decline rate of groundwater level during 2007-2013 was higher than during 2001-2006 in Beijing piedmont plain and the decline rate of groundwater level in the agricultural irrigation areas was lowest, compared with those in residential and industrial areas [19]. In addition, it was found that the dynamic change in groundwater level was usually of extremely complex nonlinear characteristics, such as periodicity and randomness [20]. Moreover, some influencing factors, e.g., rainfall and irrigation amount, vary periodically [21].…”

Section: Introductionmentioning

confidence: 99%

Dynamic Response Characteristics of Shallow Groundwater Level to Hydro-Meteorological Factors and Well Irrigation Water Withdrawals under Different Conditions of Groundwater Buried Depth

Cai

Huang

Xu³

et al. 2022

Water

View full text Add to dashboard Cite

Many irrigation districts along the Yellow River have been suffering shallow groundwater depression and agriculture-use water shortage. For comprehending response relationships of shallow groundwater level and various factors under different conditions of groundwater buried depth, the hydro-meteorological time series and the agricultural production data in Puyang area of Henan Province, China during 2006–2018 were collected for performing wavelet analysis of the relationship between the groundwater level and the four different factors, such as precipitation, air temperature, water stage of the Yellow River, and well irrigation water amount. It is shown that when the burial depth of groundwater varied from 0–10 m to over 10 m, the groundwater level was related with both the precipitation and air temperature from moderately to weakly and the delayed response times of the groundwater level to them extended from 2–4 months to more than 5 months. The groundwater level maintained a medium correlation with the well irrigation water amount as the burial depth increased, but the lag response time of groundwater level to well irrigation dramatically decreased when the burial depth exceeded 10 m. The dynamic response relationship between the groundwater and the water stage of the Yellow River was mainly affected by the distance away from the Yellow River rather than the burial depth and the influence of the river stage on the groundwater level was limited within the distance approximate to 20 km away from the Yellow River. The findings are expected to provide the reference for groundwater level prediction and groundwater resources protection.

show abstract

Section: Introductionmentioning

confidence: 99%

Dynamic Response Characteristics of Shallow Groundwater Level to Hydro-Meteorological Factors and Well Irrigation Water Withdrawals under Different Conditions of Groundwater Buried Depth

Cai

Huang

Xu³

et al. 2022

Water

View full text Add to dashboard Cite

show abstract

“…Nowadays, a great number of researchers try to put forward the relationship between earthquakes, groundwater levels, and chemistry in different situations by field observations and scientific studies especially (Wang et al, 2001;Sneed et al, 2003;Kitagawa et al, 2006;La Vigna et al, 2012;Shi and Wang, 2014;Manga and Wang, 2015;He and Singh, 2019;Lee et al, 2020;Senthilkumar et al, 2020). Effects of the earthquakes on groundwater response vary under the control of the aquifer with the factors such as lithology, hydrogeochemistry, permeability, porosity, pore pressure change, aquifer type, barometric pressure, tidal effects, fault zones, well properties, and earthquake characteristics (Bredehoeft, 1967;Roeloffs, 1988;Brodsky et al, 2003;Claesson et al, 2004;Falcone et al, 2012;Shi et al, 2015;Rutter et al, 2016;Yan et al, 2016;Liu et al, 2018;Petitta et al, 2018;Shih, 2018;Sun et al, 2019;Lee et al, 2020;Senthilkumar et al, 2020). When the waterrock interactions occurring in the groundwater aquifer system are examined, opened/closed cracks and fault planes, deformation by co-seismic strain and post-seismic hydrogeological conditions can be considered as primary controllers (Pasvanoglu et al, 2004;Charmoille et al, 2005;Skelton et al, 2008;Reddy et al, 2011;Woith et al, 2013;Skelton et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

Effects of seismic activity on groundwater level and geothermal systems in İzmir, Western Anatolia, Turkey: the case study from October 30, 2020 Samos Earthquake

Uzelli¹,

Bilgiç²,

Öztürk³

et al. 2021

Turkish J Earth Sci

View full text Add to dashboard Cite

The October 30, 2020 Samos earthquake (Mw 6.6) affected the Aegean Sea and environs, caused destruction and loss of life in the city of İzmir located 70 km away from the earthquake epicenter. Before this earthquake, water resources were monitored in the areas of Bayraklı, Gülbahçe, and Seferihisar. For this purpose, 10 groundwater monitoring wells were drilled in the Bayraklı area, where groundwater level, temperature, and electrical conductivity changes were monitored at 1-h intervals in 5 wells. Besides physical parameters such as groundwater levels, temperatures and electrical conductivities, hydrogeochemical cations, and anions measured in the study area. Change in the groundwater levels was observed before, during, and after the Samos earthquake. A trend of rising groundwater level was observed two days before the mainshock, to a height of 10 cm, and the level was maintained till the end of the earthquake. The water levels returned to its original height after about 7 to 10 days of the earthquake. Moreover, electrical conductivity (EC) values were changed because of the interaction with the surrounding rocks and well walls, mixing with different waters during the earthquake shaking. The essential anomalies were observed in the geothermal fields of Gülbahçe and Seferihisar. Due to this earthquake, new geothermal springs emerged along the NE-SW trending Gülbahçe and Tuzla faults, located about 50 to 20 km from the Samos earthquake epicenter, respectively. The new geothermal waters are in Na-Cl composition and similar to other geothermal springs in the region. While the recorded water temperatures in the new geothermal springs vary from 40 to 45 °C in Seferihisar, it was measured between 35 and 40 °C in Gülbahçe. Due to these anomalies, it is found essential to monitor the effect of the earthquake on the physical and chemical characteristics of the groundwater and its usefulness in earthquake predictions.

show abstract

“…Changes in groundwater level differ according to the aquifer type (confined or unconfined aquifer), as well as due to external stresses such as barometric pressure, precipitation, tidal effects, and earthquakes (Bredehoeft 1967;Weeks 1979;Roeloffs 1988;Healy and Cook 2002;Pacheco and Fallico 2015). Spectral analysis of groundwater level show different signal components for unconfined and confined aquifers (Rahi and Halihan 2013;Shih 2018). Groundwater levels have been used as indicators of crustal stress/strain (e.g.…”

Section: Introductionmentioning

confidence: 99%

Assessing aquifer responses to earthquakes using temporal variations in groundwater monitoring data in alluvial and sedimentary bedrock aquifers

Lee

Woo

Koh

et al. 2020

Geomatics, Natural Hazards and Risk

View full text Add to dashboard Cite

Water level and hydrochemical parameters from groundwater monitoring wells can be effectively used for interpreting changes in the groundwater system when aquifers are appropriately characterized. Groundwater levels in six paired monitoring wells of alluvial and sedimentary bedrock aquifers in the Gyeongju area, southeastern South Korea were analyzed to evaluate their abrupt changes due to earthquakes, and to identify the differences in responses of groundwater level to the earthquakes and precipitation based on confining conditions of the aquifers, which was verified by principal component analysis (PCA) of water level and major ion concentrations, and lithologic logs. When earthquakes occurred in 2016 near the study area, the different responses of groundwater level to the earthquakes were detected in the two well pairs under confined condition. In particular, wells with single screened interval showed dissimilar patterns in water level fluctuation and hydrochemical water type. The PCA results of groundwater levels and hydrochemical parameters also substantiated the different aquifer types in the two well pairs. These results suggest that groundwater monitoring data should be acquired and analyzed considering the well design and aquifer type to properly evaluate impacts of earthquakes on the aquifers, which can contribute to establishment of earthquake monitoring systems.

show abstract

Storage in confined aquifer: Spectral analysis of groundwater in responses to Earth tides and barometric effect

Cited by 16 publications

References 26 publications

Dynamic Response Characteristics of Shallow Groundwater Level to Hydro-Meteorological Factors and Well Irrigation Water Withdrawals under Different Conditions of Groundwater Buried Depth

Dynamic Response Characteristics of Shallow Groundwater Level to Hydro-Meteorological Factors and Well Irrigation Water Withdrawals under Different Conditions of Groundwater Buried Depth

Effects of seismic activity on groundwater level and geothermal systems in İzmir, Western Anatolia, Turkey: the case study from October 30, 2020 Samos Earthquake

Assessing aquifer responses to earthquakes using temporal variations in groundwater monitoring data in alluvial and sedimentary bedrock aquifers

Contact Info

Product

Resources

About