Multiple-indicator study of groundwater flow and chemistry and the impacts of river and paddy water on groundwater in the alluvial fan of the Tedori River, Japan

Yoshioka, Yumi; Nakamura, Kimihito; Nakano, Takanori; Horino, Haruhiko; Shin, Ki-Cheol; Hashimoto, Satoko; Kawashima, Shuichi

doi:10.1002/hyp.10785

Cited by 14 publications

(6 citation statements)

References 30 publications

(52 reference statements)

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“…River water infiltration provides considerable groundwater recharge to some aquifer systems. Some works have identified groundwater δ 18 O and δ 2 H values that are similar to those characterizing nearby river(s), implying river waters may replenish these aquifers (e.g., Ali et al, ; Baskaran et al, ; Darling et al, ; Iwasaki Yoshioka et al, ; Kebede et al, ; Leontiadis et al, ; Ma, Jin, et al, ; Navada et al, ; Shamsuddin et al, ). Other studies have compared precipitation, groundwater, and river water isotope compositions and concluded stream waters do not recharge the aquifer (e.g., Baganza River, Italy—Deiana et al, ).…”

Section: Recharge Sources and Elevationsmentioning

confidence: 95%

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: Recharge Sources and Elevationsmentioning

confidence: 95%

Global Isotope Hydrogeology―Review

Jasechko

2019

Reviews of Geophysics

215

124

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“…The study area is Tedori River in Ishikawa Prefecture, Japan (Figure 3). The main channel of Tedori River starts in the Hakusan Mountains at an elevation of 2702 m. The river channel has a length of 72 km and a basin area of 807 km 2 , and it pours into the Sea of Japan (Iwasaki Yoshioka et al, 2016). The alluvial fan of the river has an area of 170 km 2 , which is covered by paddy fields.…”

Section: Applicationmentioning

confidence: 99%

Statistical evaluation of a long‐memory process using the generalized entropic value‐at‐risk

Yoshioka,

Yoshioka

2023

Environmetrics

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The modeling and identification of time series data with a long memory are important in various fields. The streamflow discharge is one such example that can be reasonably described as an aggregated stochastic process of randomized affine processes where the probability measure, we call it reversion measure, for the randomization is not directly observable. Accurate identification of the reversion measure is critical because of its omnipresence in the aggregated stochastic process. However, the modeling accuracy is commonly limited by the available real‐world data. We resolve this issue by proposing the novel upper and lower bounds of a statistic of interest subject to ambiguity of the reversion measure. Here, we use the Tsallis value‐at‐risk (TsVaR) as a convex risk functional to generalize the widely used entropic value‐at‐risk (EVaR) as a sharp statistical indicator. We demonstrate that the EVaR cannot be used for evaluating key statistics, such as mean and variance, of the streamflow discharge due to the blowup of some exponential integrand. We theoretically show that the TsVaR can avoid this issue because it requires only the existence of some polynomial moment, not exponential moment. As a demonstration, we apply the semi‐implicit gradient descent method to calculate the TsVaR and corresponding Radon–Nikodym derivative for time series data of actual streamflow discharges in mountainous river environments.

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“…Maruyama et al [7] and Fujihara et al [8] conducted comprehensive studies on the mechanisms of snow accumulation and snowmelt in this basin. Furthermore, concerning the Tedori River alluvial fan, Iwasaki et al [9] and Yoshioka et al [10,11] analyzed the characteristics of the groundwater within the alluvial fan, utilizing data on groundwater levels, water quality, stable isotopic ratios and so on. Maruyama et al [12] provided insights into the water balance within alluvial fans, whereas Yoshioka et al [13] employed a 3D groundwater flow model (MODFLOW) to simulate groundwater systems under climate change conditions.…”

Section: Introductionmentioning

confidence: 99%

Impacts of High-Concentration Turbid Water on the Groundwater Environment of the Tedori River Alluvial Fan in Japan

Fujihara,

Otani,

Takase

et al. 2024

Water

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The occurrence of high-concentration turbid water due to a large landslide in the upper reaches of the Tedori River Basin in Japan in May 2015 led to a rapid decline in the groundwater levels within the alluvial fan. However, factors other than turbid water, such as changes in precipitation patterns, can have a significant impact on groundwater levels but have not been thoroughly investigated. By analyzing the relationship between river water and groundwater levels, we found that by 2018, conditions had returned to those observed prior to the turbidity events. Regarding seepage, we found that approximately 24% of the Tedori River’s discharge contributed to seepage before the turbidity event. In contrast, during the post-turbidity years, seepage decreased between 2015 and 2017 and returned to the pre-turbidity levels by 2018. Furthermore, by constructing a hydrological model and examining the contributions of turbidity and precipitation, we found that in 2015, turbidity contributed to 76% of the groundwater level changes, whereas precipitation accounted for 24%. In contrast, in 2016, turbidity contributed to 67%, while precipitation contributed to 33%. In essence, the first year was characterized by a significant contribution from turbidity, while precipitation also played a significant role in groundwater level fluctuations in the second year.

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Multiple-indicator study of groundwater flow and chemistry and the impacts of river and paddy water on groundwater in the alluvial fan of the Tedori River, Japan

Cited by 14 publications

References 30 publications

Global Isotope Hydrogeology―Review

Global Isotope Hydrogeology―Review

Statistical evaluation of a long‐memory process using the generalized entropic value‐at‐risk

Impacts of High-Concentration Turbid Water on the Groundwater Environment of the Tedori River Alluvial Fan in Japan

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