Response of a fractured bedrock aquifer to recharge from heavy rainfall events

Rathay, Sarah; Allen, D. M.; Kirste, Dirk

doi:10.1016/j.jhydrol.2017.07.042

Cited by 32 publications

(12 citation statements)

References 109 publications

(248 reference statements)

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“…Assessing annual recharge rates is important for estimating the extent to which groundwater pumping impacts groundwater storage and discharge (Theis, , ). Yet understanding recharge rates at shorter (i.e., seasonal) timescales is also important in order to (i) forecast changes to annual recharge rates under changing seasonal climate conditions (e.g., Ajami et al, ; Earman et al, ; Earman & Dettinger, ; Meixner et al, ; Niraula et al, ), (ii) develop more sophisticated conceptual models detailing hydrological processes and conditions conducive to groundwater replenishment (e.g., Alsaaran, ; Dripps, ; Dripps & Bradbury, ; Flerchinger et al, ; Gat & Tzur, ; Gates, Edmunds, Ma, et al, ; Hammarlund & Edwards, ; Liefert et al, ; Nasta et al, ; Pavlovskii et al, ; Rathay et al, ; Wilson & Guan, ; Zhang et al, ), (iii) interpret paleoclimate conditions from fossil groundwater and speleothem isotopic records (e.g., Bar‐Matthews et al, ; Benson & Klieforth, ; Denniston et al, ; Fairchild et al, ; Johnson, Hu, et al, ; Johnson, Ingram, et al, ; Jones et al, ; Simpson et al, ; Treble et al, ), and (iv) understand the ways that plants obtain water, and the relationships among vegetation, runoff, and recharge (e.g., Grossiord et al, ; Guswa & Spence, ; Kim & Jackson, ; Vico et al, ).…”

Section: Seasonal Biases In Groundwater Rechargementioning

confidence: 99%

Global Isotope Hydrogeology―Review

Jasechko

2019

Reviews of Geophysics

215

124

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Groundwater 18O/16O, 2H/1H, 13C/12C, 3H, and 14C data can help quantify molecular movements and chemical reactions governing groundwater recharge, quality, storage, flow, and discharge. Here, commonly applied approaches to isotopic data analysis are reviewed, involving groundwater recharge seasonality, recharge elevations, groundwater ages, paleoclimate conditions, and groundwater discharge. Reviewed works confirm and quantify long held tenets: (i) that recharge derives disproportionately from wet season and winter precipitation; (ii) that modern groundwaters comprise little global groundwater; (iii) that “fossil” (>12,000‐year‐old) groundwaters dominate global aquifer storage; (iv) that fossil groundwaters capture late‐Pleistocene climate conditions; (v) that surface‐borne contaminants are more common in younger groundwaters; and (vi) that groundwater discharges generate substantial streamflow. Groundwater isotope data are disproportionately common to midlatitudes and sedimentary basins equipped for irrigated agriculture, but less plentiful across high latitudes, hyperarid deserts, and equatorial rainforests. Some of these underexplored aquifer systems may be suitable targets for future field testing.

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Section: Seasonal Biases In Groundwater Rechargementioning

confidence: 99%

Global Isotope Hydrogeology―Review

Jasechko

2019

Reviews of Geophysics

215

124

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“…An additional complication arises because mountainous regions are frequently fractured (e.g., the Atlas Mountains) and contain a discontinuous aquifer (e.g., a karstic aquifer). The groundwater potential in mountainous aquifers is governed by several parameters (i.e., lithology, geomorphology, topography, secondary porosity, geological structures, fracture density, permeability, drainage pattern and density, groundwater recharge, piezometric level, slope, land use/cover and climatic conditions, and their interrelationships) [7].…”

Section: Introductionmentioning

confidence: 99%

Spatial Prediction of Groundwater Potentiality in Large Semi-Arid and Karstic Mountainous Region Using Machine Learning Models

Namous

Hssaisoune

Pradhan

et al. 2021

Water

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The drinking and irrigation water scarcity is a major global issue, particularly in arid and semi-arid zones. In rural areas, groundwater could be used as an alternative and additional water supply source in order to reduce human suffering in terms of water scarcity. In this context, the purpose of the present study is to facilitate groundwater potentiality mapping via spatial-modelling techniques, individual and ensemble machine-learning models. Random forest (RF), logistic regression (LR), decision tree (DT) and artificial neural networks (ANNs) are the main algorithms used in this study. The preparation of groundwater potentiality maps was assembled into 11 ensembles of models. Overall, about 374 groundwater springs was identified and inventoried in the mountain area. The spring inventory data was randomly divided into training (75%) and testing (25%) datasets. Twenty-four groundwater influencing factors (GIFs) were selected based on a multicollinearity test and the information gain calculation. The results of the groundwater potentiality mapping were validated using statistical measures and the receiver operating characteristic curve (ROC) method. Finally, a ranking of the 15 models was achieved with the prioritization rank method using the compound factor (CF) method. The ensembles of models are the most stable and suitable for groundwater potentiality mapping in mountainous aquifers compared to individual models based on success and prediction rate. The most efficient model using the area under the curve validation method is the RF-LR-DT-ANN ensemble of models. Moreover, the results of the prioritization rank indicate that the best models are the RF-DT and RF-LR-DT ensembles of models.

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“…They are discrete, exhibit anisotropy, have small pathways, and are less common (Coleman et al, 2015). The occurrence and movement of groundwater in fractured bedrock aquifers in a given area is very complicated and governed by many factors, such as lithology, landforms, topography, secondary porosity, geological structures, fracture density, aperture and connectivity, drainage pattern, groundwater recharge, groundwater table distribution, slope, land cover, climatic conditions, and their interrelationships (Levison et al, 2012;Rathay et al, 2018). In general, there is insufficient data regarding groundwater in fractured bedrock aquifers in mountainous environments worldwide due to a lack of piezometric wells in these high-elevation settings (Voeckler and Allen, 2012).…”

Section: Introductionmentioning

confidence: 99%

The effect of sample size on different machine learning models for groundwater potential mapping in mountain bedrock aquifers

Moghaddam

Rahmati

Panahi

et al. 2020

CATENA

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Machine learning models have attracted much research attention for groundwater potential mapping. However, the accuracy of models for groundwater potential mapping is significantly influenced by sample size and this is still a challenge. This study evaluates the influence of sample size on the accuracy of different individual and hybrid models, adaptive neuro-fuzzy inference system (ANFIS), ANFISimperial competitive algorithm (ANFIS-ICA), alternating decision tree (ADT), and random forest (RF) to model groundwater potential, considering the number of springs from 177 to 714. A well-documented inventory of springs, as a natural representative of groundwater potential, was used to designate four sample data sets: 100% (D1), 75% (D2), 50% (D3), and 25% (D4) of the entire springs inventory. Each data set was randomly split into two groups of 30% (for training) and 70% (for validation). Fifteen diverse geo-environmental factors were employed as independent variables. The area under the operating 2 receiver characteristic curve (AUROC) and the true skill statistic (TSS) as two cutoff-independent and cutoff-dependent performance metrics were used to assess the performance of models. Results showed that the sample size influenced the performance of four machine learning algorithms, but RF had a lower sensitivity to the reduction of sample size. In addition, validation results revealed that RF (AUROC=90.74-96.32%, TSS=0.79-0.85) had the best performance based on all four sample data sets, followed by ANFIS-ICA (AUROC=81.23-91.55%, TSS=0.74-0.81), ADT (AUROC=79.29-88.46%, TSS=0.59-0.74), and ANFIS (AUROC=73.11-88.43%, TSS=0.59-0.74). Further, the relative slope position, lithology, and distance from faults were the main spring-affecting factors contributing to groundwater potential modelling. This study can provide useful guidelines and valuable reference for selecting machine learning models when a complete spring inventory in a watershed is unavailable.

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Response of a fractured bedrock aquifer to recharge from heavy rainfall events

Cited by 32 publications

References 109 publications

Global Isotope Hydrogeology―Review

Global Isotope Hydrogeology―Review

Spatial Prediction of Groundwater Potentiality in Large Semi-Arid and Karstic Mountainous Region Using Machine Learning Models

The effect of sample size on different machine learning models for groundwater potential mapping in mountain bedrock aquifers

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