Water

29 pages, 76370 KB

Open AccessArticle

Hydrogeochemical and GIS-Integrated Evaluation of Drainage Water for Sustainable Irrigation Management in Al-Jouf, Saudi Arabia

by Raid Alrowais, Mahmoud M. Abdel-Daiem, Mohamed Ashraf Maklad, Wassef Ounaies and Noha Said

Water 2026, 18(1), 78; https://doi.org/10.3390/w18010078 (registering DOI) - 27 Dec 2025

Abstract

This study evaluates the quality and irrigation suitability of drainage water in the Al-Jouf Region, Saudi Arabia, where water scarcity necessitates the reuse of nonconventional resources. Eighteen drainage water samples were analyzed for physicochemical parameters and irrigation indices, including electrical conductivity (EC), sodium [...] Read more.

This study evaluates the quality and irrigation suitability of drainage water in the Al-Jouf Region, Saudi Arabia, where water scarcity necessitates the reuse of nonconventional resources. Eighteen drainage water samples were analyzed for physicochemical parameters and irrigation indices, including electrical conductivity (EC), sodium percentage (Na⁺%), sodium adsorption ratio (SAR), magnesium hazard (MH), Kelly’s ratio (KR), permeability index (PS), and irrigation water quality index (IWQI). Multivariate statistical tools were applied to identify dominant hydrogeochemical processes. Inverse Distance Weighting (IDW) interpolation in ArcGIS Desktop 10.8 was employed to map significant physicochemical data and irrigation indicators. Results revealed that while EC values indicated low to moderate salinity (0.74–25.2 μS/cm), most samples showed high Na⁺%, SAR, and KR, classifying them as doubtful to unsuitable for irrigation. The IWQI ranged from 84.47 to 1617.87, indicating poor to inferior quality due to evaporation, fertilizer leaching, and sodium accumulation. Furthermore, the results highlight the importance of precise geographic modeling in determining whether drainage water is suitable for long-term agricultural use in arid regions such as Al-Jouf. Sustainable reuse of such drainage water requires freshwater blending, gypsum application, and the cultivation of salt-tolerant crops, aligning with Saudi Vision 2030 objectives for sustainable water management in arid regions. Full article

(This article belongs to the Section Water Quality and Contamination)

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24 pages, 2004 KB

Open AccessReview

Biofilm Control in Wastewater Treatment: A Review Regarding the Application of Quorum Sensing and Quenching Processes and Future Perspectives

by Ioannis Masatlis, Alexandros Chatzis and Anastasios Zouboulis

Water 2026, 18(1), 77; https://doi.org/10.3390/w18010077 (registering DOI) - 27 Dec 2025

Abstract

Wastewater treatment (WWT) is among the main challenges in environmental engineering. However, conventional wastewater treatment methods are limited by several aspects, mostly related to efficiency, excessive energy requirements, and surplus sludge production. Thus, the alternative use of biofilms (instead of suspended biomass/activated sludge [...] Read more.

Wastewater treatment (WWT) is among the main challenges in environmental engineering. However, conventional wastewater treatment methods are limited by several aspects, mostly related to efficiency, excessive energy requirements, and surplus sludge production. Thus, the alternative use of biofilms (instead of suspended biomass/activated sludge systems) has garnered particular interest, especially due to their ability to sustain high microbial activity and withstand extreme conditions. This review aims to provide an interdisciplinary and comprehensive approach to understanding the main interactions occurring in biofilms, emphasizing, specifically, the quorum sensing (QS) and the quorum quenching (QQ) mechanisms, as well as to address their relative applications in controlling biofouling problems, e.g., during the operation of membrane bioreactors (MBRs). The review summarizes and analyzes the latest developments, highlights the relevant research gaps in the literature, and links microbiological knowledge with related technological applications. Full article

(This article belongs to the Section Wastewater Treatment and Reuse)

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Graphical abstract

17 pages, 761 KB

Open AccessArticle

Multicriteria Analysis of the Effects of Sewage Sludge Conditioning Prior to the Dewatering Process

by Stanisław Miodoński, Aleksy Ruszkowski, Bartłomiej Pietura and Mateusz Muszyński-Huhajło

Water 2026, 18(1), 76; https://doi.org/10.3390/w18010076 (registering DOI) - 27 Dec 2025

Abstract

Dewatering of sewage sludge is a key operational element of wastewater treatment plants and has major economic implications, as it entails the costs of thickening, transport, and disposal. The aim of this study was to determine the influence of selected polyelectrolytes and their [...] Read more.

Dewatering of sewage sludge is a key operational element of wastewater treatment plants and has major economic implications, as it entails the costs of thickening, transport, and disposal. The aim of this study was to determine the influence of selected polyelectrolytes and their dosages on dewatering efficiency and to present an innovative, multicriteria method of result evaluation using radar charts. In this research, 10 different polyelectrolytes were assessed in terms of sludge dewaterability, considering conditioning parameters including Specific Resistance to Filtration (SRF), Capillary Suction Time (CST), and centrifugation performance. The results were presented in the form of radar charts, enabling both an overall evaluation of the effectiveness of each product and an assessment of their suitability for specific dewatering technologies, such as belt filter presses and centrifuges. The analysis showed that polyelectrolytes with higher cationic charge provided better dewatering performance. The proposed visualization method allows us to analyze the effects across different conditioners and technologies. The best sludge conditioning effect (maximum radar chart area) was achieved with Praestol 665, a polyelectrolyte with a high cationic charge level. This method is a practical tool for selecting the optimal agent for sewage sludge dewatering. Full article

(This article belongs to the Section Wastewater Treatment and Reuse)

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27 pages, 1768 KB

Open AccessArticle

Origin and Hydrogeochemical Evolution of Jety-Oguz Mineral Waters (Issyk-Kul Basin, Tien Shan)

by Ekaterina I. Baranovskaya, Natalia А. Kharitonova, George А. Chelnokov, Farid S. Salikhov and Irina A. Tarasenko

Water 2026, 18(1), 75; https://doi.org/10.3390/w18010075 (registering DOI) - 26 Dec 2025

Abstract

This article presents a comprehensive study of the nitrogen-radon thermal mineral waters of the Jety-Oguz area, located in the southeastern part of the Issyk-Kul intermountain artesian basin (Northern Tien Shan). Based on new data from chemical and isotopic (δ¹⁸O, δD) analyses [...] Read more.

This article presents a comprehensive study of the nitrogen-radon thermal mineral waters of the Jety-Oguz area, located in the southeastern part of the Issyk-Kul intermountain artesian basin (Northern Tien Shan). Based on new data from chemical and isotopic (δ¹⁸O, δD) analyses of natural waters (lake, river, and mineral) and the chemical composition of the water-bearing rocks, we identify the formation mechanisms of mineral waters with diverse composition, total dissolved solids (TDS), and temperature. Three main genetic types have been identified: (1) saline, high-TDS (up to 12.8 g/L) chloride sodium-calcium thermal waters (up to 32 °C). These waters are of meteoric origin and circulate within Middle Carboniferous carbonate rocks, acquiring their unique composition at depths of up to 3.0 km, where reservoir temperatures reach ~105 °C; (2) chloride-sulfate sodium-calcium waters (0.5 g/L, fresh, 22 °C), formed in alluvial deposits within the zone of active water exchange; and (3) low-TDS (1.8 g/L, brackish) waters of mixed composition, resulting from the mixing of a deep fluid with infiltrating meteoric waters. Isotopic data confirm a meteoric origin for all studied waters, including the high-TDS thermal types. The chemical composition diversity is attributed to several processes: mixing between the deep, high-TDS fluid and low-TDS infiltration waters, intense dissolution of evaporite rocks, and water–rock interaction. These findings are crucial for understanding the genesis of mineral waters in the Tien Shan intermountain basins and provide a scientific basis for their sustainable balneological exploitation. Full article

(This article belongs to the Special Issue Isotope Hydrology: Tracing Water’s Journey and Water–Rock Interactions in a Changing World)

30 pages, 10800 KB

Open AccessArticle

Influence Mechanism of Particle Diameter and Volume Fraction on the Solid–Liquid Two-Phase Flow Performance of Semi-Open Impeller Sewage Pumps

by Hongliang Wang, Ang Li, Chuan Wang, Shuai Liu, Yansheng Shi, Hao Yu, Xi Wang and Xuanwen Jia

Water 2026, 18(1), 74; https://doi.org/10.3390/w18010074 (registering DOI) - 26 Dec 2025

Abstract

Semi-open impeller sewage pumps are widely used in fields such as municipal wastewater treatment. However, they often face performance degradation and operational instability when conveying solid–liquid two-phase flows containing solid particles. This study aims to systematically elucidate the influence mechanisms of particle diameter [...] Read more.

Semi-open impeller sewage pumps are widely used in fields such as municipal wastewater treatment. However, they often face performance degradation and operational instability when conveying solid–liquid two-phase flows containing solid particles. This study aims to systematically elucidate the influence mechanisms of particle diameter (0.5–3.0 mm) and volume fraction (1–20%) on the external characteristics and internal flow field of semi-open impeller sewage pumps, providing a theoretical basis for optimizing their design and operational stability. Using an 80WQ4QG-type sewage pump as the research subject, this study employed a combination of numerical simulation and experimental research. The standard k-ε turbulence model coupled with the Discrete Phase (Particle) approach was adopted for multi-condition solid–liquid two-phase flow simulations. Furthermore, two-way analysis of variance (two-way ANOVA) was utilized to quantify the main effects and interaction effects of the parameters. The results indicate that the pump head and efficiency generally exhibit a decreasing trend with increasing particle diameter or volume fraction, with particle diameter exerting a more pronounced effect (p < 0.01). When the particle diameter increased to 3.0 mm, the head decreased by 5.66%; when the volume fraction rose to 20%, the head decreased by 4.17%. It is noteworthy that the combination of a 0.5 mm particle diameter and a 20% volume fraction resulted in an abnormal increase in head, suggesting a possible flow pattern optimization under specific conditions. Analysis of the internal flow field reveals that coarse particles (≥1.5 mm) intensify the pressure gradient disparity between the front and rear shroud cavities of the impeller, thereby increasing the axial thrust. A high volume fraction (≥10%) promotes pronounced flow separation in the volute tongue region and exacerbates the risk of localized erosion at the outlet. Full article

(This article belongs to the Section Hydraulics and Hydrodynamics)

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41 pages, 2178 KB

Open AccessArticle

Synergistic Development Mechanism Between Reservoir Resettlers’ Livelihoods and Host Regions

by Weiwei Zhang, Kaiwen Yao, Dan Zhang, Lantao Tu, Youping Peng and Hao Sun

Water 2026, 18(1), 73; https://doi.org/10.3390/w18010073 (registering DOI) - 26 Dec 2025

Abstract

The sustainability of reservoir resettlement depends on the synergistic development of resettlers’ livelihoods and host regions; however, existing studies lack an integrated analytical framework. Combining the Sustainable Livelihoods Framework with synergistic development theory, this study establishes a dual-system evaluation model comprising the Regional [...] Read more.

The sustainability of reservoir resettlement depends on the synergistic development of resettlers’ livelihoods and host regions; however, existing studies lack an integrated analytical framework. Combining the Sustainable Livelihoods Framework with synergistic development theory, this study establishes a dual-system evaluation model comprising the Regional Development Support (RDS) and Resettlers’ Livelihood Development (RLD) indices. Using survey data from 289 households across 10 counties in Zhejiang’s QC Reservoir project, we apply composite weighting, coupling coordination modeling, and spatial analysis to evaluate the levels of synergistic development and examine spatial patterns. The findings reveal that (1) there is significant gradient differentiation in the Synergistic Development Index (SDI), with scores ranging from 0.134 to 0.738; (2) spatial autocorrelation is weak (Moran’s I = −0.089), reflecting industrial heterogeneity; and (3) four distinct coordination types are identified, with employment–industry mismatch and ecological constraints being the primary limiting factors. This study provides a diagnostic framework for assessing resettlement outcomes and offers guidance for formulating differentiated policy interventions. Full article

(This article belongs to the Section Water Resources Management, Policy and Governance)

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28 pages, 4088 KB

Open AccessArticle

Research on the Evaluation Method of Urban Water Resources Resilience Based on the DPSIR Model: A Case Study of Dalian City

by Mengmeng Gao, Nan Yang, Yi Wang and Qiong Liu

Water 2026, 18(1), 72; https://doi.org/10.3390/w18010072 (registering DOI) - 26 Dec 2025

Abstract

Under global climate change and urbanization, enhancing urban water resources resilience (WRR) is crucial. As a typical water-scarce city, Dalian in China faces significant challenges in water security. However, systematic assessments of WRR that integrate spatial and temporal dimensions remain limited. This study [...] Read more.

Under global climate change and urbanization, enhancing urban water resources resilience (WRR) is crucial. As a typical water-scarce city, Dalian in China faces significant challenges in water security. However, systematic assessments of WRR that integrate spatial and temporal dimensions remain limited. This study develops a novel evaluation framework integrating the Driving Force-Pressure-State-Impact-Response (DPSIR) model with the resilience process encompassing the pre-disturbance, during-disturbance, and post-disturbance to quantify the spatiotemporal evolution of WRR in Dalian from 2010 to 2022. The comprehensive Water Resources Resilience Index (WRRI) was calculated using the entropy weight method. The Geodetector and an obstacle degree model were used to identify key driving factors and obstacles. Results indicate an average WRRI of 0.47 with significant fluctuations. Spatially, resilience displayed a “high in the south, low in the north” pattern, with most areas at low-to-moderately low levels. Socio-economic factors such as water resources development and utilization rate, water use per 10,000 yuan of GDP, and proportion of the tertiary industry in GDP, along with natural factors like per capita water resources, were identified as the primary drivers. Obstacle factors varied spatially, reflecting distinct water management challenges across different counties. This study highlights the importance of integrating the resilience process into WRR evaluation and provides a scientific basis for developing targeted strategies to enhance urban water security and sustainable resource management. Full article

(This article belongs to the Special Issue From Theory to Practice: Implementing Resilience, Adaptation and Drivers of Change Frameworks in Water Basin Management)

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16 pages, 1120 KB

Open AccessArticle

Spatial Heterogeneity in Economic Benefits of Water Use: Sectoral Analysis of Chinese Cities in 2017

by Yuan Liang, Shaofeng Jia, Lihua Lan, Zikun Song, Jiabao Yan, Wenbin Zhu, Yan Han, Wenhua Liu, Kailibinuer Abulizi and Jieming Deng

Water 2026, 18(1), 71; https://doi.org/10.3390/w18010071 - 25 Dec 2025

Abstract

Spatial heterogeneity in economic benefits of water use provides crucial evidence for the evaluation of water diversion projects and the spatial equilibrium of water resource allocation. Using city-level data from 2017 on the sectoral water use and value added in 334 Chinese cities, [...] Read more.

Spatial heterogeneity in economic benefits of water use provides crucial evidence for the evaluation of water diversion projects and the spatial equilibrium of water resource allocation. Using city-level data from 2017 on the sectoral water use and value added in 334 Chinese cities, we estimated the economic benefits of water use in the agricultural, industrial, and service sectors using the allocation coefficient method. We then revealed the spatial heterogeneity combining an exploratory spatial data analysis (ESDA) method. For the agricultural sector, the high economic benefit of water use regions are primarily concentrated on both sides of the “Hu Huanyong Line”; regions with high economic benefit of industrial water use are mainly found in the North China Plain, the middle and lower Huanghe River basin, the Yangtze River Delta, the Pearl River Delta, Chongqing and Chengdu, and the economic benefit of service water use is higher in the north than in the south. ESDA provides significant evidence for the analysis of spatial heterogeneity with regard to the economic benefits of water use in China. Based on the fundamental distribution of water resources and the spatial heterogeneity in the economic benefits of water use, potential water diversion areas can be preliminarily identified. The Haihe River Basin in the North China Plain and some areas in the southeast coastal region are potential receiving areas, and the eastern regions of Southwest China with abundant water resources and lower elevations, along with the middle and lower reaches of the Yangtze River are potential source areas. Further research about marginal benefits and water use costs, along with dynamic updates, is required for water resource allocation of China. Full article

(This article belongs to the Section Water Use and Scarcity)

27 pages, 4765 KB

Open AccessArticle

A New Methodological Framework for the Determination of Water Resource Classes and Resource Quality Objectives: A Case Study for the Mzimvubu to Tsitsikamma Water Management Area 7 (WMA7)

by Lawrence Humbulani Mulangaphuma and Nebo Jovanovic

Water 2026, 18(1), 70; https://doi.org/10.3390/w18010070 - 25 Dec 2025

Abstract

The current paper determined water resource classes and Resource Quality Objectives (RQOs) for significant water resources in the Mzimvubu to Tsitsikamma Water Management Area 7 (WMA7) to facilitate sustainable use of the water resources while maintaining ecological integrity. A novel stepwise quantitative and [...] Read more.

The current paper determined water resource classes and Resource Quality Objectives (RQOs) for significant water resources in the Mzimvubu to Tsitsikamma Water Management Area 7 (WMA7) to facilitate sustainable use of the water resources while maintaining ecological integrity. A novel stepwise quantitative and qualitative method was developed to ensure water resource protection in the study area. The methodological approach is proposed as a model framework that could be adopted as guideline and transferable to other catchments in the implementation of Resource Directed Measures (RDMs). The method used water quality and quality components of water resources to determine the classes and RQOs. The study’s major findings were that nineteen Integrated Units of Analysis (IUAs) were delineated, and ninety-five Resource Units were identified and prioritized for both surface and groundwater. Driving water quality variables (nutrients, electrical conductivity, and Escherichia coli) were observed and primary water users (irrigation, settlements, and wastewater treatment works) were identified per Integrated Units of Analysis. Five water resource scenarios were developed and evaluated to capture a likely water resource condition for the present and future. The scenario analysis showed impact is expected under any of the operational scenarios assessed at selected reaches. The water resource classes were determined, with eleven IUAs classified as Class lll, seven IUAs as Class ll, and one IUA as Class l. Water quality and quantity RQOs were set to ensure that both river and groundwater resources are compliant and protected. Therefore, the study recommends that this methodological framework, where classes and RQOs were determined, needs to be implemented and tested. Full article

(This article belongs to the Special Issue Global Water Risks Across Shared River Corridors in Transboundary Basins)

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12 pages, 1645 KB

Open AccessArticle

Study on Improving the Purification Function of Constructed Wetlands with Construction Waste Substrates by Acid–Base Substrate Configuration

by Ying Cai, Yumei Gu, Miao Zhang, Ying Wei, Rixiu Zhou and Dehua Zhao

Water 2026, 18(1), 69; https://doi.org/10.3390/w18010069 - 25 Dec 2025

Abstract

Construction and demolition waste, when used as the substrates of constructed wetlands, provide notable environmental benefits: purification performances and substantial economic advantages compared with conventional substrates such as gravels. However, the high effluent pH induced by waste concrete severely restricts its practical application [...] Read more.

Construction and demolition waste, when used as the substrates of constructed wetlands, provide notable environmental benefits: purification performances and substantial economic advantages compared with conventional substrates such as gravels. However, the high effluent pH induced by waste concrete severely restricts its practical application in such systems. The body of research focused on overcoming this limitation is rather limited. To address this limitation, this study proposed a strategy based on the configurations of acid alkaline substrates. A pilot-scale vertical flow constructed wetland experiment was carried out to evaluate the feasibility of this approach through three treatments: (1) waste concrete alone (Concrete), (2) waste concrete as the upper layer combined with perlite (an acidic substrate (Concrete + Perlite)), and (3) a uniform mixture of waste concrete and perlite (Mixed). The results demonstrate that the Concrete treatment exhibited a persistent high pH problem, where the effluent pH values remained above 9, even after five months of operation. In contrast, the Concrete + Perlite and Mixed treatments effectively mitigated the excessive effluent pH (<8.2). Relative to the Concrete treatment, both the Concrete + Perlite and Mixed treatments significantly enhanced the removal efficiencies of chemical oxygen demand (COD) (from 43.7% to above 68.5%), total nitrogen (TN) (from 31.8% to above 86.5%), and ammonium nitrogen (NH₄⁺-N) (from 96.7% to 96.9%), whereas the removal efficiency of total phosphorous (TP) showed only a slight decrease. No significant differences in pollutant removal performance were observed between the Concrete + Perlite and Mixed treatments. Moreover, the Concrete + Perlite and Mixed treatments substantially increased the bacterial diversity within the substrate biofilm compared with the Concrete treatment, although differences in the bacterial community composition between the Concrete + Perlite and Mixed were relatively minor. Overall, configuring pH-balanced substrates through the combination of acidic and alkaline matrices provided effective and sustainable integrity for promoting the resource of construction and demolition waste in constructed wetlands. Full article

(This article belongs to the Special Issue Advanced Technologies in Water and Wastewater Treatment)

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19 pages, 4440 KB

Open AccessArticle

A Flexible Python Module for Reservoir Simulations with Seasonally Varying and Constant Flood Storage Capacity

by Xiaodong Hao, Yali Hao, Xiaohui Sun and Li Tang

Water 2026, 18(1), 68; https://doi.org/10.3390/w18010068 - 25 Dec 2025

Abstract

Storage-oriented reservoir schemes are effective for large-scale hydrological modeling, yet two important limitations remain. First, although some reservoirs seasonally adjust flood storage capacity (FSC), no global study has examined whether constant or seasonally varying FSC performs better. Second, these schemes rely on empirical [...] Read more.

Storage-oriented reservoir schemes are effective for large-scale hydrological modeling, yet two important limitations remain. First, although some reservoirs seasonally adjust flood storage capacity (FSC), no global study has examined whether constant or seasonally varying FSC performs better. Second, these schemes rely on empirical operational-zone parameterization, but its impact on simulation accuracy has never been systematically assessed. This study presents an open-source Python module integrating three leading storage-oriented schemes (S25, Z17, H22) with both constant and seasonally varying FSC options. Evaluated using daily observations from 289 global reservoirs via Nash-Sutcliffe Efficiency (NSE), constant FSC significantly outperforms seasonal variation, increasing median outflow NSE by 0.18–0.47 and reducing storage error magnitude by 38–61%, and is selected as optimal for 84% of reservoirs. Sensitivity analysis across eight alternative zoning schemes shows that, under constant FSC, outflow remains stable, whereas seasonal FSC sharply increases sensitivity. Storage simulation is more sensitive overall, yet constant FSC consistently yields the smallest errors. This work provides the first global comparison of FSC strategies and the first systematic assessment of operational zone parameter uncertainty. It strongly recommends constant FSC with H22 or S25 as the default for large-scale modeling. The released module offers a flexible, reproducible platform for the community. Future extensions may incorporate demand-driven rules and hybrid calibration to further improve performance in data-rich regions. Full article

(This article belongs to the Section Hydrology)

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12 pages, 2336 KB

Open AccessArticle

Estimation of Soil Water Flux Using the Heat Pulse Technique and Vector Addition in Saturated Soils of Different Textures

by Fuyun Lu, Zhi Zhao, Qinghua Pan, Yuping Zhang, Dongye Lu and Yang Wu

Water 2026, 18(1), 67; https://doi.org/10.3390/w18010067 - 25 Dec 2025

Abstract

Soil water flux is a key parameter for understanding water and heat transport processes in the vadose zone. The heat pulse technique (HPT) has shown considerable potential for predicting soil water flux. Traditional three-needle probe methods, the maximum dimensionless temperature difference (MDTD [...] Read more.

Soil water flux is a key parameter for understanding water and heat transport processes in the vadose zone. The heat pulse technique (HPT) has shown considerable potential for predicting soil water flux. Traditional three-needle probe methods, the maximum dimensionless temperature difference (MDTD) method and the ratio of downstream to upstream temperature increases (Ratio) method, can only measure water flux along the probe alignment. To enhance the applicability of the HPT method, the five-needle probe with vector addition allows for the measurement of soil water flux in any direction within the plane perpendicular to the needles. However, its applicability across different soil textures remains unclear. The objective of this study was to evaluate the applicability of the MDTD and Ratio methods when combined with vector addition across different soil textures. Experimental results show that the vector MDTD and Ratio methods improve water flux measurement accuracy compared with traditional three-needle methods, confirming the reliability of the vector HPT approach. Specifically, the mean absolute percentage error (MAPE) of the vector MDTD method decreased by 1.69%, 1.04%, and 1.80% in sand, sandy loam, and silt loam, respectively, compared with the traditional MDTD method. In contrast, the MAPE of the vector Ratio method varied by +8.83%, −6.73%, and −18.20% in the same soils, relative to the traditional Ratio method. Examining the root mean square error (RMSE) of each method yields a similar conclusion. Similarly to traditional HPT methods, the measurement accuracy of the vector HPT approach is influenced by soil texture, water flux range, and probe spacing. Notably, because the vector HPT method involves four probe spacings, namely the distances between the heating needle and the temperature-sensing needles, it can exacerbate the instability of the resultant water flux measurements. These findings may facilitate the broader application of the HPT method. Full article

(This article belongs to the Section Soil and Water)

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13 pages, 12941 KB

Open AccessArticle

Isolation and Identification of Pseudoalteromonas agarivorans LJ53, a Pathogenic Bacterium Causing Bleaching Disease in Saccharina japonica

by Ying Ouyang, Ruojing Tu, Jiapeng Li, Xianzhen Zhou, Chenhui Zhong, Lijun Fu and Jiangwei Li

Water 2026, 18(1), 66; https://doi.org/10.3390/w18010066 - 25 Dec 2025

Abstract

As a major export crop in China, Saccharina japonica cultivation suffers from significant economic losses due to disease outbreaks, with pathogen identification remaining a critical bottleneck for mariculture. In this study, a dominant bacterial strain, LJ53, was isolated from the diseased farmed S. [...] Read more.

As a major export crop in China, Saccharina japonica cultivation suffers from significant economic losses due to disease outbreaks, with pathogen identification remaining a critical bottleneck for mariculture. In this study, a dominant bacterial strain, LJ53, was isolated from the diseased farmed S. japonica. Artificial challenge assay confirmed that this strain is the direct causative agent of bleaching symptoms on sporophytes. Based on morphological characteristics and 16S rRNA gene-based phylogeny, it was identified as Pseudoalteromonas agarivorans LJ53. Ultrastructural observation revealed that this strain destroyed host cells and caused typical pathological changes such as chloroplast disintegration. Interestingly, metagenomic analysis showed no significant difference in the relative abundance of this pathogen between healthy and diseased S. japonica tissues. However, the co-occurrence network of the disease community exhibited increased connectivity, altered modularity, and features characteristic of microbial dysbiosis. This dysbiosis disrupts the water ecological balance by destabilizing microbial symbiosis and nutrient cycling, which are essential for overall ecosystem resilience. As a result, these imbalances can exacerbate disease transmission and weaken the self-regulating capacity of marine environment, highlighting the need for integrated management strategies to restore equilibrium. These findings provide a theoretical basis for elucidating the mechanisms of bacterial diseases in S. japonica and developing future control strategies. Full article

(This article belongs to the Special Issue Aquaculture Productivity and Environmental Sustainability)

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17 pages, 2166 KB

Open AccessArticle

Submerged Plant Restoration Modulates Carbon-Water Interface Dynamics: Enhanced Carbon Sequestration Coupled with Eutrophication Control

by Ran Tao, Yinfei Wang, Zhiwei Zhang, Ting Chen, Dejian Zhou, Yimin Zhang, Huiyang Qiu and Yuexiang Gao

Water 2026, 18(1), 65; https://doi.org/10.3390/w18010065 - 25 Dec 2025

Abstract

This study investigates the dynamics of carbon flux at the water–air interface during the ecological restoration of eutrophic water bodies. A controlled simulation of the eutrophic aquatic environment was carried out. A series of experiments was established, centered on submerged aquatic plants as [...] Read more.

This study investigates the dynamics of carbon flux at the water–air interface during the ecological restoration of eutrophic water bodies. A controlled simulation of the eutrophic aquatic environment was carried out. A series of experiments was established, centered on submerged aquatic plants as key agents for carbon sequestration and enhancement of carbon sink capacity, supplemented by biological manipulation techniques aimed at pollution reduction and algal control. Results show that restoration systems based on submerged plants significantly enhance carbon sequestration, whereas systems relying solely on filter-feeding fish tend to increase the carbon emission burden. The submerged plant-only treatment (HV) exhibited the highest carbon absorption capacity (−72.53 mg·m⁻²·h⁻¹), followed by submerged plant + fish + snail (HSXB) and submerged plant + fish (HSX) treatments. CH₄ emissions were initially higher in the combined biological treatments but were eventually surpassed by the control group as algal cell density increased. Carbon sink potential and CH₄ emissions were strongly correlated with algal cell density and chlorophyll a concentration. While combination treatments (HSX and HSXB) effectively suppressed algal proliferation, the submerged plant-only treatment demonstrated superior nutrient removal efficiency. The findings provide theoretical support for ecologically based management strategies that simultaneously address eutrophication control and carbon sequestration in freshwater ecosystems, contributing to both water quality improvement and climate change mitigation. Full article

(This article belongs to the Special Issue Nutrient Cycling and Pollution Migration Mechanisms in Eutrophic Lake Basins)

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19 pages, 4674 KB

Open AccessArticle

Comparative Analysis of Rainfall-Based and Discharge-Based Early Warning Methods for Flash Floods

by Yanhong Dou, Junyao Wen, Xiangning Liu, Ronghua Liu and Jichao Sun

Water 2026, 18(1), 64; https://doi.org/10.3390/w18010064 - 25 Dec 2025

Abstract

Against the backdrop of increasingly evident climate change and frequent extreme weather events, flash floods have emerged as a major challenge for flood disaster prevention and mitigation in China. Flash flood early warning systems are crucial means to address this challenge, primarily comprising [...] Read more.

Against the backdrop of increasingly evident climate change and frequent extreme weather events, flash floods have emerged as a major challenge for flood disaster prevention and mitigation in China. Flash flood early warning systems are crucial means to address this challenge, primarily comprising rainfall-based warnings (RW) and discharge-based warnings (DW). To support precise flash flood warnings, this study compares the effectiveness of RW and DW and summarizes their applicable scenarios through both case study analysis and model simulations. The results demonstrate that DW outperforms RW under the following scenarios: ① During persistent moderate-intensity rainfall events when antecedent soil moisture is moderate to high, RW is prone to missed or delayed warnings. ② When rainfall exhibits significant spatial heterogeneity, RW tends to produce false alarms. Conversely, RW outperforms DW in the following scenarios: ① For localized short-duration heavy rainfall events, DW is prone to missed or delayed warnings. ② In basins where numerous small- and medium-sized reservoirs exist upstream without operational data, DW is prone to false alarms. ③ When sparse or unevenly distributed rain gauges result in poor representativeness of areal rainfall, DW is prone to missed warnings. To enhance flash flood disaster management, future warning systems should integrate both RW and DW approaches to deliver more timely, reliable, and scientifically grounded warning information for local authorities. Full article

(This article belongs to the Special Issue Hydrological Hazards: Monitoring, Forecasting and Risk Assessment)

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27 pages, 860 KB

Open AccessReview

State Regulation and Strategic Management of Water Resources and Wastewater Treatment at the Regional Level: Institutional and Technological Solutions

by Rabiga M. Kudaibergenova, Asparukh B. Bolatbek, Magbat U. Spanov, Elvira A. Baibazarova, Seitzhan A. Orynbayev, Nazgul S. Murzakasymova and Arman A. Kabdushev

Water 2026, 18(1), 63; https://doi.org/10.3390/w18010063 - 24 Dec 2025

Abstract

Regional water systems face growing pressure from climate variability, water scarcity, and increasingly complex wastewater pollution. These challenges require governance models that integrate institutional coordination with effective technological solutions. This review is based on a structured analysis of peer-reviewed literature indexed in Scopus, [...] Read more.

Regional water systems face growing pressure from climate variability, water scarcity, and increasingly complex wastewater pollution. These challenges require governance models that integrate institutional coordination with effective technological solutions. This review is based on a structured analysis of peer-reviewed literature indexed in Scopus, Web of Science, and ScienceDirect, covering publications from approximately 2014 to 2025. The findings show that clearly defined institutional roles, basin-level coordination, stable financing mechanisms, and active stakeholder participation significantly improve governance outcomes. Technological advances such as membrane filtration, advanced oxidation processes, nature-based treatment systems, and digital monitoring platforms enhance treatment efficiency, resilience, and opportunities for resource recovery. Regions differ widely in their ability to adopt these solutions, mainly due to variations in governance coherence, investment capacity, and climate-adaptation readiness. The review highlights the need for policy frameworks that align institutional reforms with technological modernization, including the adoption of basin-based planning, digital decision-support systems, and circular water-economy principles. These measures provide actionable guidance for policymakers and regional authorities seeking to strengthen long-term water security and wastewater management performance. Full article

(This article belongs to the Section Water Resources Management, Policy and Governance)

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17 pages, 1326 KB

Open AccessArticle

Analyzing the Effectiveness of Water Reclamation Processes in Terms of Costs and Water Quality in Taiwan

by Shahbaz Abbas, Lin-Han Chiang Hsieh, Yu-Hsien Yang, Irfan Nawaz and Wen-Li Lu

Water 2026, 18(1), 62; https://doi.org/10.3390/w18010062 - 24 Dec 2025

Abstract

The use and promotion of reclaimed water have become global trends and have been widely adopted in countries such as Singapore, Israel, Japan, and the United States. In recent years, Taiwan has also been promoting demonstration plants for reclaimed water by enacting the [...] Read more.

The use and promotion of reclaimed water have become global trends and have been widely adopted in countries such as Singapore, Israel, Japan, and the United States. In recent years, Taiwan has also been promoting demonstration plants for reclaimed water by enacting the Reclaimed Water Resources Development Act. Since the demonstration plants apply different reclamation processes, the costs and quality of the reclaimed water vary. This study aims to analyze the cost effectiveness of reclaimed water under three different scenarios, based on operational costs and water quality data from three demonstration plants: the Fongshan River Reclaimed Water Plant, the Shui Nan Water Resource Recovery Center, and the Futian Water Resource Recovery Center. The result shows that the most cost-effective scenario is either the high-cost-high-quality scenario or the low-cost-low-quality one. The moderate scenario is not preferred in terms of cost effectiveness. If the consideration is simply the total cost as a society, the high-cost-high-quality scenario might be preferred. But if “who pays for the cost” is taken into consideration, the low-cost-low-quality scenario is preferred since the cost would be mostly shouldered by the industrial users, rather than the government. The result can not only be used as a reference for the determination of the unified price and water quality standard for reclaimed water in Taiwan in the future but also shed light on the determination of water reclamation processes globally. Full article

(This article belongs to the Section Water Resources Management, Policy and Governance)

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23 pages, 16845 KB

Open AccessArticle

Hydraulic Instability Characteristics of Pumped-Storage Units During the Transition from Hot Standby to Power Generation

by Longxiang Chen, Jianguang Li, Lei Deng, Enguo Xie, Xiaotong Yan, Guowen Hao, Huixiang Chen, Hengyu Xue, Ziwei Zhong and Kan Kan

Water 2026, 18(1), 61; https://doi.org/10.3390/w18010061 - 24 Dec 2025

Abstract

Against the backdrop of the carbon peaking and neutrality (“dual-carbon”) goals and evolving new-type power system dispatch, the share of pumped-storage hydropower (PSH) in power systems continues to increase, imposing stricter requirements on units for higher cycling frequency, greater operational flexibility, and rapid, [...] Read more.

Against the backdrop of the carbon peaking and neutrality (“dual-carbon”) goals and evolving new-type power system dispatch, the share of pumped-storage hydropower (PSH) in power systems continues to increase, imposing stricter requirements on units for higher cycling frequency, greater operational flexibility, and rapid, stable startup and shutdown. Focusing on the entire hot-standby-to-generation transition of a PSH plant, a full-flow-path three-dimensional transient numerical model encompassing kilometer-scale headrace/tailrace systems, meter-scale runner and casing passages, and millimeter-scale inter-component clearances is developed. Three-dimensional unsteady computational fluid dynamics are determined, while the surge tank free surface and gaseous phase are captured using a volume-of-fluid (VOF) two-phase formula. Grid independence is demonstrated, and time-resolved validation is performed against the experimental model–test operating data. Internal instability structures are diagnosed via pressure fluctuation spectral analysis and characteristic mode identification, complemented by entropy production analysis to quantify dissipative losses. The results indicate that hydraulic instabilities concentrate in the acceleration phase at small guide vane openings, where misalignment between inflow incidence and blade setting induces separation and vortical structures. Concurrently, an intensified adverse pressure gradient in the draft tube generates an axial recirculation core and a vortex rope, driving upstream propagation of low-frequency pressure pulsations. These findings deepen our mechanistic understanding of hydraulic transients during the hot-standby-to-generation transition of PSH units and provide a theoretical basis for improving transitional stability and optimizing control strategies. Full article

(This article belongs to the Special Issue Recent Advances in Hydraulic Machinery and Its Application in Marine Engineering)

21 pages, 11748 KB

Open AccessArticle

Numerical Analysis of the Dynamic Response of a Prestressed Reinforced Concrete Retaining Dam Under the Impact of Debris Flow Block Stones

by Yongbo Tie, Wei Jiang, Min Wang and Yong Zheng

Water 2026, 18(1), 60; https://doi.org/10.3390/w18010060 - 24 Dec 2025

Abstract

Debris flow is a common geological disaster in mountainous areas, characterized by its sudden onset, frequent occurrence, and high destructive power. Retaining dams are one of the most commonly used measures for debris flow prevention and are widely applied in debris flow management [...] Read more.

Debris flow is a common geological disaster in mountainous areas, characterized by its sudden onset, frequent occurrence, and high destructive power. Retaining dams are one of the most commonly used measures for debris flow prevention and are widely applied in debris flow management projects. This study investigates the impact resistance of retaining dams in high-altitude cold regions by establishing a three-dimensional numerical model of the retaining dam. The results show that the impact depth, resultant impact force, and acceleration of the prestressed reinforced concrete retaining dam with embedded prestressed reinforcement are significantly lower than those of the concrete retaining dam. The prestressed reinforced concrete retaining dam with embedded prestressed reinforcement can improve its impact resistance, effectively mitigating the impact of debris flow block collisions. The impact depth and resultant impact force of the prestressed reinforced concrete retaining dam both increase with the steel ball’s impact speed, impact angle, and impact mass, while they decrease with an increase in the shape coefficient of the steel ball. The effects of different parameters of the steel ball on the impact depth and resultant impact force of the barrier vary. The research findings provide a scientific basis for the design of barriers in the prevention and control of debris flows in high-altitude cold regions. Full article

(This article belongs to the Special Issue Theory and Technology of Water-Induced Geological Disaster Prevention and Water Resource Utilization in Mines)

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