Your search keyword '"WATER shortages"' showing total 22,274 results

101. Advancements in CNT-based materials for optimized pharmaceutical removal via adsorption and photocatalysis.

Author

Malik, Adnan, Haider, Ali, Qamar, Muhammad Azam, Arooj, Yusra, Meriam Suhaimy, Syazwan Hanani, and Ahmad, Rehan

Subjects

*WATER purification, *WASTEWATER treatment, *CHEMICAL properties, *WATER use, *BATCH processing, *WATER shortages

Abstract

Water treatment plays a crucial role in meeting the growing demand for water and preventing future shortages. The unique and adaptable arbitrary, physical, and chemical properties of carbon nanotubes (CNTs) make them an attractive candidate for use in water treatment. CNTs are employed in environmental applications because of their exceptional adsorbent, mechanical, and chemical characteristics. Functional groups chemically or physically modify pure CNTs, improving their desalination and extraction capabilities. The advantages of CNT-based composites, such as antifouling performance, excellent selectivity, and higher water permeability, reassure us of their effectiveness in water treatment. This review comprehensively discusses the structural features and synthetic methods of CNTs. The functionalization and the pros and cons of functionalized CNT materials are also discussed. Pharmaceutical compounds are often manufactured using batch processes, resulting in the production of various products in wastewater. The occurrence of pharmaceutical compounds in drinking water arises from two distinct origins: the pharmaceutical industry’s manufacturing procedures and the widespread use of pharmaceutical compounds, which leads to their presence in urban and agricultural wastewater. This review discusses role of CNT-based nanomaterials in effectively removing pharmaceutical waste from wastewater through adsorption and photocatalytic processes. Lastly, the future approach is discussed to develop CNT-based nanomaterials better. [ABSTRACT FROM AUTHOR]

Published

2024

102. Harnessing Virtual Insights: A Computational Study on the Molecular Characterization of a Drought‐Inducible RNA‐Binding Protein for Enhancing Drought Tolerance in Mungbean (Vigna radiata L.).

Author

Rajkhowa, Sanchaita, Zaheen, Alaiha, Hussain, Safrina Zeenat, and Barthakur, Sharmistha

Subjects

*CROPS, *AGRICULTURE, *SUSTAINABILITY, *WATER shortages, *DROUGHT tolerance, *MUNG bean

Abstract

Abiotic stresses, particularly drought and salinity, significantly impact agricultural crop yields, with mung bean (Vigna radiata L.) being no exception. This annual green legume, vital to agricultural systems in Asia, is generally resilient to limited water supply; however, severe drought conditions at critical growth stages can drastically diminish both its quality and yield. Drought stress negatively affects various morpho‐physicochemical properties, impeding plant growth and highlighting the need for sustainable approaches to enhance mung bean's drought tolerance through improved farming practices. In this study, we focused on identifying and understanding the molecular mechanisms underlying drought tolerance in mung beans. We retrieved the target gene sequence from the NCBI database, but found no direct sequence similarity, which led to the use of homology modeling. The structure of a known protein (PDB ID: 5T9P) was identified as the most suitable template. Motif prediction using the Motif Search tool highlighted specific motifs relevant to drought stress responses. To investigate potential drought‐tolerance mechanisms, we screened ABA agonists using Density Functional Theory (DFT) analysis. Molecular docking and MD simulations revealed the interactions between these ligands and the modeled protein, shedding light on how they might influence drought tolerance. We performed molecular dynamics (MD) simulations to assess the stability and conformational dynamics of the modeled protein across different time scales. Our findings underscore the potential of ABA agonists to modulate physiological responses and enhance drought resistance. This research offers valuable insights into the conformational dynamics of drought‐related proteins in mung beans, elucidating the molecular underpinnings of drought response mechanisms. By advancing our understanding of these processes, our findings provide novel strategies for improving breeding approaches aimed at enhancing crop resilience against water scarcity and other abiotic stresses. This work promises to mitigate the detrimental effects of drought on mung bean yields and supports sustainable agricultural practices, thereby contributing to global food security. [ABSTRACT FROM AUTHOR]

Published

2024

103. Preparation of superhydrophobic/superhydrophilic sodium alginate aerogels for efficient oil absorption.

Author

Jiang, Yu-Hui, Zhu, Kai-Ruo, Xiao, Xin-Yu, and Zhai, Shang-Ru

Subjects

*CONTACT angle, *SUPERHYDROPHOBIC surfaces, *SODIUM alginate, *WATER shortages, *WASTE recycling

Abstract

The advanced treatment and resource utilization of oily wastewater are of great significance to solve water shortages and realize carbon peaking and carbon neutrality goals. The construction of biomass-based superwetting surfaces with recyclability, non-toxicity, and degradability is considered to be a promising strategy to overcome the unavoidable bottlenecks of "secondary pollution" and high costs in the current design of superhydrophobic structures. In this work, a strategy for preparing multifunctional sodium alginate (SA) superhydrophobic surfaces was proposed. By virtue of the synergistic mechanism of SA, SiO2 nanoparticles, pseudo-polyrotaxane and methyltrimethoxysilane, a superhydrophobic sponge with a green biomass-based carrier was prepared, which was constructed using a superhydrophobic elastomer with a three-dimensional network. The modified SA aerogel has a contact angle of 155.2° and even exhibits strong corrosion resistance in harsh environments with a water contact angle greater than 155°. Notably, the increase of green biomass-based materials provides a promising and sustainable development path for the preparation of hydrophobic substrates. [ABSTRACT FROM AUTHOR]

Published

2024

104. Frontiers of fortune: mobilising land, water, and collective identity for watermelon production in Southeastern Morocco.

Author

Fico, Jamie

Subjects

*MARKET volatility, *GROUP identity, *WATER shortages, *AGRICULTURE, *ARID regions

Abstract

Watermelon production has rapidly increased in Morocco over the last 15 years. Since its independence in 1956, Morocco has promoted the production of early-season fruits and vegetables for European supermarkets to boost the national economy and improve rural livelihoods. Today, the expansion of watermelon production in arid regions of the country has had profound impacts on local land and water resources. In Zagora, a pre-Sahara oasis region in the southeast of the country, watermelons have contributed to the overuse of aquifers, trapping farmers in cycles of accumulating debt, and increasing conflict over land. Drawing on interviews and participant observation with residents and officials from 2021-2023, this paper demonstrates how a pastoral community embraced watermelon production in an effort to engage with the agro-export sector that drives the country's agricultural growth. Yet rather than contributing to the overall development of the region, watermelon production has deepened gender and economic disparities within the community and privileged a small group of farmers with access to capital. Although authorities restricted watermelon production in 2023, larger investors simply moved production, leaving small farmers to confront the volatile market while trying to sustain land, water, and collective identity in the region. [ABSTRACT FROM AUTHOR]

Published

2024

105. Determinants of small-scale irrigation adoption in drought-prone areas of northcentral Ethiopia in the context of climate change.

Author

Eshetu, Amogne Asfaw and Mekonen, Abebe Arega

Subjects

IRRIGATION, CLIMATE change, HOUSEHOLDS, WATER shortages, CHI-squared test

Abstract

Introduction: One feasible way to prepare for the adverse effects of climate change in rainfed-dependent livelihood zones is through irrigation. This study examines small-scale irrigation practices and their determinants. Methods: Using structured survey questionnaires, interviews, and field observations, we used a cross-sectional survey design to collect data from 380 randomly selected households. The data analysis involved percentages, problem confrontation index, Chi-square test, independent samples t-test, and binary logistic regression model. Results: The findings revealed that river/stream diversion (40%), using nearby springs (19%), and hand-dug walls (18%) were the predominant types of irrigation. At the same time, water scarcity (PCI = 743), land shortage (PCI = 345), and labor (PCI = 212) were the main impediments to irrigation practices. The binary logistic regression model revealed educational status (OR = 1.239, p < 0.05), headship type (OR = 0.246, p < 0.05), age (OR = 0.943, p < 0.05), relative agroecological location (OR = 7.605; 13.929, p < 0.05), family size (OR = 1.936, p < 0.05), land size (OR = 8.609, p < 0.05), responsibility (OR = 2.069, p < 0.05), and crop failure (OR = 0.389, p < 0.05) as factors affecting the adoption of small-scale irrigation. Discussion: We recommend offering financial assistance to farmers with limited resources to acquire and install labor- and water-saving irrigation systems. Training and extension services on operating and maintaining smallscale irrigation technologies should be provided. Timely information sharing is also necessary to increase the use of irrigation on a small scale as a feasible adaptation to climate change. [ABSTRACT FROM AUTHOR]

Published

2024

106. Genome-Wide Analysis of Aquaporins Gene Family in Populus euphratica and Its Expression Patterns in Response to Drought, Salt Stress, and Phytohormones.

Author

Ndayambaza, Boniface, Si, Jianhua, Zhou, Dongmeng, Bai, Xue, Jia, Bing, He, Xiaohui, Wang, Chunlin, Qin, Jie, Zhu, Xinglin, Liu, Zijin, and Wang, Boyang

Subjects

*CHEMICAL processes, *GENE expression, *GENE families, *WATER shortages, *POST-translational modification

Abstract

Aquaporins (AQPs) play an essential role in membrane water transport during plant responses to water stresses centered on conventional upstream signals. Phytohormones (PHs) regulate plant growth and yield, working with transcription factors to help plants withstand environmental challenges and regulate physiological and chemical processes. The AQP gene family is important, so researchers have studied its function and regulatory system in numerous species. Yet, there is a critical gap the understanding of many of their molecular features, thus our full knowledge of AQPs is far-off. In this study, we undertook a broad examination of the AQP family gene in Populus euphratica via bioinformatics tools and analyzed the expression patterns of certain members in response to drought, salt, and hormone stress. A total of 22 AQP genes were examined in P. euphratica, and were categorized into four main groups, including TIPs, PIPs, SIPs, and NIPs based on phylogenetic analysis. Comparable exon–intron gene structures were found by gene structure examination, and similarities in motif number and pattern within the same subgroup was determined by motif analysis. The PeuAQP gene family has numerous duplications, and there is a distinct disparity in how the members of the PeuAQP family react to post-translational modifications. Abiotic stress and hormone responses may be mediated by AQPs, as indicated by the abundance of stress response elements found in 22 AQP genes, as revealed by the promoter's cis-elements prediction. Expression pattern analysis reveals that selected six AQP genes from the PIP subgroup were all expressed in the leaves, stem, and roots with varying expression levels. Moreover, qRT-PCR analysis discovered that the majority of the selected AQP members were up- or down-regulated in response to hormone treatment and abiotic stress. Remarkably, PeuAQP14 and PeuAQP15 appeared to be highly responsive to drought stress and PeuAQP15 exhibited a high response to salt stress. The foliar application of the phytohormones (SA, IAA, GA3, MeJA, and ABA) were found to either activate or inhibit PeuAQP, suggesting that they may mitigate the effects of water shortage of poplar water stress. The present work enhances our knowledge of the practical roles of AQPs in stress reactions and offers fundamental information for the AQP genes in poplar species. It also highlights a direction for producing new varieties of poplar species with drought, salt, and hormone tolerance and holds substantial scientific and ecological importance, offering a potential contribution to the conservation of poplar species in arid regions. [ABSTRACT FROM AUTHOR]

Published

2024

107. Comparative Genomics Analysis of the Populus Epidermal Pattern Factor (EPF) Family Revealed Their Regulatory Effects in Populus euphratica Stomatal Development.

Author

Jia, Mingyu, Wang, Ying, Jin, Hongyan, Li, Jing, Song, Tongrui, Chen, Yongqiang, Yuan, Yang, Hu, Honghong, Li, Ruting, Wu, Zhihua, and Jiao, Peipei

Subjects

*WATER efficiency, *WATER shortages, *PLANT adaptation, *DROUGHT tolerance, *ABSCISIC acid

Abstract

Drought stress seriously threatens plant growth. The improvement of plant water use efficiency (WUE) and drought tolerance through stomatal regulation is an effective strategy for coping with water shortages. Epidermal patterning factor (EPF)/EPF-like (EPFL) family proteins regulate stomatal formation and development in plants and thus contribute to plant stress adaptation. Here, our analysis revealed the presence of 14 PeEPF members in the Populus euphratica genome, which exhibited a relatively conserved gene structure with 1–3 introns. Subcellular localisation prediction revealed that 9 PeEPF members were distributed in the chloroplasts of P. euphratica, and 5 were located extracellularly. Phylogenetic analysis indicated that PeEPFs can be divided into three clades, with genes within the same clade revealing a relatively conserved structure. Furthermore, we observed the evolutionary conservation of PeEPFs and AtEPF/EPFLs in certain domains, which suggests their conserved function. The analysis of cis-acting elements suggested the possible involvement of PeEPFs in plant response to multiple hormones. Transcriptomic analysis revealed considerable changes in the expression level of PeEPFs during treatment with polyethylene glycol and abscisic acid. The overexpression of PeEPF2 resulted in low stomatal density in transgenetic lines. These findings provide a basis for gaining insights into the function of PeEPFs in response to abiotic stress. [ABSTRACT FROM AUTHOR]

Published

2024

108. Gleaning Rural Journalism: Rural Journalists' Agricultural and Environmental Reporting Utilizing Community Storytelling Networks☆.

Author

Walsh, Jessica, Perreault, Mildred F., Perreault, Greg, and Moon, Ruth

Subjects

*RURAL Americans, *ENVIRONMENTAL reporting, *WATER shortages, *WELLS, *RAINFALL

Abstract

Environmental concerns are growing in parts of the rural United States as drinking water wells become contaminated with agrichemicals, and climate change impacts such as drought and extreme rain events disrupt farming practices. Analyzing in‐depth interviews with 29 U.S. rural journalists, we explore the role rural journalists play when reporting on the environment as it relates to agricultural issues. Findings show that reporting about the environment—such as weather, climate change, water shortages, and droughts—appear in rural journalists' stories given those topics' relevance to their rural communities and the social systems forces exerting influence on journalists, yet rural journalists often do not perceive themselves as doing environmental reporting. Rural journalists also report lacking training and resources to do environmental reporting. This study points to the need for more support for rural journalists' environmental reporting as one way to build social change and maintain local community. [ABSTRACT FROM AUTHOR]

Published

2024

109. Nitrogen and molybdenum fertilization influence on enzymatic activity and productivity enhancement of forage sorghum under water deficit in the Brazilian semi-arid region.

Author

Henrique, Jamiles Carvalho Gonçalves de Souza, Oliveira, Alexandre Campelo de, Silva, Thieres George Freire da, Carvalho, Lucas Henrique Maciel, Souza, Evaristo Jorge Oliveira de, Fonseca, Glícia Rafaela Freitas da, Santos, Hugo Rafael Bentzen, and Cruz, Gabriel Henrique de Lima

Subjects

*ARID regions, *MOLYBDENUM, *NITROGEN, *SODIUM molybdate, *WATER efficiency, *SORGHUM, *WATER shortages, *DEFICIT irrigation

Abstract

Water scarcity, combined with low soil fertility, constitutes one of the main limiting factors in crop productivity in semi-arid regions. However, nutritional supplementation techniques with nitrogen (N) and molybdenum (Mo) can lead to positive enhancements in the production of these crops. The objective was to evaluate the effect of increasing doses of N in the presence and/or absence of Mo on the activity of antioxidant enzymes and the productive increase of forage sorghum subjected to water deficit in the semi-arid region. The experiment was conducted in the field using a randomized block design, with four replications, in a 5 × 2 × 3 factorial scheme, comprising five doses of N (urea): 0, 50, 100, 150, and 300 kg ha−1, two doses of Mo (sodium molybdate): 0 and 160 g ha−1, and three production cycles. The highest yields of green mass (GM) (47.98 Mg ha−1), dry mass (DM) (19.66 Mg ha−1), water use efficiency (WUE) (5.57 kg/m³), and N use efficiency (NUE) (0.26 kg2/g) occurred at the highest N dosage (300 kg ha−1 N). The highest contents and extraction of total N, Mo, chloride (Cl), and potassium (K) were found in regrowth 2 and at the highest N dose (300 kg ha−1). The interaction of N and Mo resulted in higher catalase (CAT) enzyme activity. The meteorological conditions during the cycles strongly influenced the nutrient contents and extraction. The results of the study provide support for producers to use N and Mo fertilization strategies to improve crop productivity, even under water deficit conditions. [ABSTRACT FROM AUTHOR]

Published

2024

110. Effect of Delayed Irrigation at the Jointing Stage on Nitrogen, Silicon Nutrition and Grain Yield of Winter Wheat in the North China Plain.

Author

Zheng, Hao, Sun, Jinyang, Liang, Yueping, Cao, Caiyun, Gao, Yang, Zhang, Junpeng, Dang, Hongkai, and Zheng, Chunlian

Subjects

WINTER grain, WATER shortages, GRAIN yields, SPRING, IRRIGATION

Abstract

Water scarcity is a key limitation to winter wheat production in the North China Plain, and it is essential to explore the optimal timing of spring irrigation to optimize N and Si uptake as well as to safeguard yields. The aim of this study was to systematically study the effect mechanism of nitrogen and silicon absorption of winter wheat on yield under spring irrigation and to provide a scientific basis for optimizing irrigation strategy during the growth period of winter wheat. In this experiment, the winter wheat 'Heng 4399' was used. Five irrigation periods, i.e., 0 d (CK), 5 d (AJ5), 10 d (AJ10), 15 d (AJ15), and 20 d (AJ20) after the jointing stage, were set up to evaluate the nitrogen (N) and silicon (Si) absorption and grain yield (GY). The results showed that delayed irrigation for 5–10 days at the jointing stage had increased the GY. With the delay of irrigation time, the N/Si content of the entire plant at the maturity period increased first and then decreased; among that, the maximum N contents appeared in AJ15 and AJ5 in 2015 and 2020, respectively, while the Si concentrations appeared in AJ5 and AJ10 in sequence. Compared with AJ15 and AJ20, the N accumulation of vegetative organs in AJ5 increased by 3.05~23.13% at the flowering stage, 14.12~40.12% after the flowering stage, and a 1.76~6.45% increase in the N distribution rate at maturity stage. A correlation analysis revealed that the GY was significantly and positively correlated with the N/Si accumulation at the anthesis and N translocation after the anthesis stage. In conclusion, under limited irrigation conditions, delaying watering for 5 to 10 days at the jointing stage can improve the nitrogen and silicon absorption and nutrient status of wheat plants and increase wheat yield. [ABSTRACT FROM AUTHOR]

Published

2024

111. Shading and Water Addition Alleviate the Elemental Limitations of the Early Restoration Community in a Stressful Environment.

Author

Chen, Fajun, Zhao, Gaojuan, Shen, Youxin, Zhu, Hong, Li, Zhenjiang, and Tan, Beilin

Subjects

FOREST restoration, WATER shortages, GERMINATION, PLANT communities, PLANT species

Abstract

Shading and water addition are essential management measures to improve seed germination and early seedling survival; however, little is known about their effects on leaf stoichiometry and nutrient status. We established 90 plant communities with shading and water addition gradients on a rocky hill; leaves of their dominant woody plant species were collected to measure elemental concentrations, and then, stoichiometric variation and nutrient status were analysed. The results showed that the overall effects of shading and water addition significantly altered the concentrations and ratios of nutrient elements; shading largely affected leaf K and P, while water addition mainly affected leaf N and P. The interactions between shading and water addition were significant for most species but disappeared at the community level. Consequently, the nutrient status in leaves was improved by promoting the concentrations and balances of nutrient elements. However, the responses to shading and water addition were marked by species-specific differences, with some plants forming a sensitive group and others distinguished by conservatism. Our findings show that management of the physical environment could improve nutrient element utilization in leaves and alleviate the nutrient limitations. For our site conditions, mild shading (25–35%) and adequate water addition (30 L·m−2) in the early stage of vegetation restoration is recommended to advance community assembly by improving nutrient physiology, directly diminishing the stress of water scarcity and excessive irradiation. These findings explore the underlying mechanisms of shading and water addition that could promote community development and provide guidance for restoration practice. [ABSTRACT FROM AUTHOR]

Published

2024

112. Detection and Measurement of Bacterial Contaminants in Stored River Water Consumed in Ekpoma.

Author

Tenebe, Imokhai T., Babatunde, Eunice O., Ogarekpe, Nkpa M., Emakhu, Joshua, Etu, Egbe-Etu, Edo, Onome C., Omeje, Maxwell, and Benson, Nsikak U.

Subjects

DRINKING water standards, COLIFORMS, WATER quality, KLEBSIELLA pneumoniae, WATER shortages, WATER harvesting

Abstract

This study was conducted in Ekpoma, a town dependent on rainwater and river water from nearby areas because of a lack of groundwater sources, and the physicochemical and bacteriological (heterotrophic plate count [HPC], total coliform count [TCC], and fecal coliform count [FCC]) properties of 123 stored river water samples grouped into five collection districts (EK1 to EK5). The results were compared with regulatory standards and previous regional studies to identify water quality trends. While most physicochemical properties met drinking water standards, 74% of samples had pH values > 8.5. Twenty-seven samples were fit for drinking, with EK4 having the highest number of bacterio-logically unsuitable samples. Ten bacterial species were identified, with Gram-negative short-rod species such as Escherichia coli, Klebsiella pneumoniae, and Salmonella typhimurium being predominant. HPC values varied from 367 × 10⁴ to 1320 × 10⁴ CFU/mL, with EK2 (2505 × 10⁴ CFU/mL) and EK5 (1320 × 10⁴ CFU/mL) showing particularly high counts. The TCC values ranged from 1049 × 10⁴ to 4400 × 10⁴ CFU/mL, and the FCC values from 130 × 10⁴ to 800 × 10⁴ CFU/mL, all exceeding WHO limits (1.0 × 102 CFU/mL). Historical data show no improvement in water quality, emphasizing the need for individuals to treat water properly before consumption. The findings provide baseline data for local water authorities and serve as a wake-up call for adequate water treatment, storage interventions, and community education on water security. Additionally, this study offers a practical process for improving the quality of water stored in similar regions. [ABSTRACT FROM AUTHOR]

Published

2024

113. Evaluating the Impact of Hotel Classification on Pool Water Consumption: A Case Study from Costa Brava (Spain).

Author

Arimany-Serrat, Núria and Gomez-Guillen, Juan-Jose

Subjects

SUSTAINABILITY, ECOTOURISM, TOURISM impact, ENVIRONMENTAL infrastructure, WATER shortages

Abstract

Swimming pools are key assets in the hotel industry. With climate change and water stress, more sustainable pools are needed in tourist areas. The study examines the relationship between hotel categories and the consumption of water in swimming pools in a Mediterranean coastal region facing water scarcity. The study focuses on the Costa Brava, with a focus on Lloret de Mar, a popular tourist destination. The research employs a combination of data analysis and the utilisation of evaporation models in order to estimate the consumption of water by swimming pools. The findings indicate that hotels in the higher categories, particularly those with three or four stars, contribute a notable proportion of the total water consumption due to their larger pool sizes and higher guest numbers. The study underscores the necessity for the implementation of sustainable water management strategies, particularly in the context of climate change. It recommends the utilisation of pool water-saving technologies as potential solutions. Furthermore, the paper highlights the broader environmental impact of tourism infrastructure on water resources and suggests policy measures to mitigate these effects. The research aligns with global sustainability goals such as the European Green Deal and the 2030 Agenda. [ABSTRACT FROM AUTHOR]

Published

2024

114. Assessment of Potential Aquifer Recharge Zones in the Locumba Basin, Arid Region of the Atacama Desert Using Integration of Two MCDM Methods: Fuzzy AHP and TOPSIS.

Author

Pocco, Víctor, Mendoza, Arleth, Chucuya, Samuel, Franco-León, Pablo, Huayna, Germán, Ingol-Blanco, Eusebio, and Pino-Vargas, Edwin

Subjects

WATER management, MULTIPLE criteria decision making, TOPSIS method, WATER supply, WATER shortages, GROUNDWATER recharge

Abstract

Natural aquifers used for human consumption are among the most important resources in the world. The Locumba basin faces significant challenges due to its limited water availability for the local population. In this way, the search for possible aquifer recharge zones is crucial work for urban development in areas that have water scarcity. To evaluate this problem, this research proposes the use of the hybrid Fuzzy AHP methodology in conjunction with the TOPSIS algorithm to obtain a potential aquifer recharge map. Ten factors that influence productivity and capacity in an aquifer were implemented, which were subjected to Fuzzy AHP to obtain their weighting. Using the TOPSIS algorithm, the delineation of the most favorable areas with high recharge potential was established. The result shows that the most influential factors for recharge are precipitation, permeability, and slopes, which obtained the highest weights of 0.22, 0.19, and 0.17, respectively. In parallel, the TOPSIS result highlights the potential recharge zones distributed in the Locumba basin, which were classified into five categories: very high (13%), high (28%), moderate (15%), low (28%), and very low (16%). The adapted methodology in this research seeks to be the first step toward effective water resource management in the study area. [ABSTRACT FROM AUTHOR]

Published

2024

115. Effects of Ditch Water and Yellow River Irrigation on Saline–Alkali Characteristics of Soil and Paddy.

Author

Fan, Liqin, Shen, Jingli, Wang, Xu, and Zhang, Yonghong

Subjects

METAL content of soils, IRRIGATION water, SOIL salinity, WATER shortages, BRACKISH waters, HEAVY metals

Abstract

This study examined the agricultural water resource shortage and abundant ditch water resources in the Yinbei region of Ningxia. The effects of ditch water and Yellow River irrigation on the saline–alkali characteristics of soil and paddy were investigated using field monitoring and indoor detection methods in Pingluo County, Ningxia (106°31′ E, 38°51′ N). In addition to monitoring ditch water, four treatment groups were established: direct ditch water irrigation (T1), mixed ditch water and Yellow River water irrigation (T2), alternate ditch water and Yellow River water irrigation (T3), and irrigation solely with Yellow River water (CK). The results show the following: (1) The salinity of ditch water samples collected from the experimental field during the rice growth period was less than 1.60 g/L, and the pH of the samples was lower than 8.62; thus, they were classified as mildly brackish water. The application of ditch water irrigation did not result in soil saline–alkali aggravation and the accumulation of excessive amounts of heavy metals in soils and paddies in Pingluo County, Ningxia. (2) The rice yields for the CK, T1, T2, and T3 treatments were 10,437.5, 8318.4, 9182.1, and 9016.2 kg/hm2, respectively. Compared with Yellow River irrigation, the rice yields for the T1, T2, and T3 treatments were 20.3, 12.1, and 13.6% lower than that of CK, respectively, with minimal differences observed among them. Hence, under the condition of a water resource shortage in the Yellow River region, ditch water can be appropriately applied for mixed or alternate irrigation to ensure food security. This research has revealed the influences of ditch water irrigation on the saline–alkali properties of soil and the heavy metal contents of paddies. [ABSTRACT FROM AUTHOR]

Published

2024

116. A Fully Connected Neural Network (FCNN) Model to Simulate Karst Spring Flowrates in the Umbria Region (Central Italy).

Author

De Filippi, Francesco Maria, Ginesi, Matteo, and Sappa, Giuseppe

Subjects

ARTIFICIAL neural networks, SPRING, GROUNDWATER management, RESOURCE exploitation, CLIMATE change, RAINFALL, WATER shortages

Abstract

In the last decades, climate change has led to increasingly frequent drought events within the Mediterranean area, creating an urgent need of a more sustainable management of groundwater resources exploited for drinking and agricultural purposes. One of the most challenging issues is to provide reliable simulations and forecasts of karst spring discharges, whose reduced information, as well as the hydrological processes involving their feeding aquifers, is often a big issue for water service managers and researchers. In order to plan a sustainable water resource exploitation that could face future shortages, the groundwater availability should be assessed by continuously monitoring spring discharge during the hydrological year, using collected data to better understand the past behaviour and, possibly, forecast the future one in case of severe droughts. The aim of this paper is to understand the factors that govern different spring discharge patterns according to rainfall inputs and to present a model, based on artificial neural network (ANN) data training and cross-correlation analyses, to evaluate the discharge of some karst spring in the Umbria region (Central Italy). The model used is a fully connected neural network (FCNN) and has been used both for filling gaps in the spring discharge time series and for simulating the response of six springs to rainfall seasonal patterns from a 20-year continuous daily record, collected and provided by the Regional Environmental Protection Agency (ARPA) of the Umbria region. [ABSTRACT FROM AUTHOR]

Published

2024

117. The Potential of RainWater Harvesting Systems in Europe – Current State of Art and Future Perspectives.

Author

Wartalska, Katarzyna, Grzegorzek, Martyna, Bełcik, Maciej, Wdowikowski, Marcin, Kolanek, Agnieszka, Niemierka, Elżbieta, Jadwiszczak, Piotr, and Kaźmierczak, Bartosz

Subjects

GREENHOUSE gases, LARGE scale systems, WATER shortages, WATER management, CLIMATE change

Abstract

Water scarcity and climate change led to changes in water management, especially in urban areas. RainWater Harvesting (RWH) is a promising technique that allows the collection and reuse of rainwater, as well as protecting sewage systems from overload. This article reviews the current state of RWH in Europe, including advantages, implementation, potential efficiency, usage requirements, quality, and treatment processes. The main findings include the importance of RWH as a sustainable water management technique, the historical background and renewed interest in RWH systems in recent years, the positive impact of RWH on reducing energy consumption and greenhouse gas emissions, the versatility of rainwater usage, and the potential cost savings and benefits in various regions. RWH systems are gaining popularity in Europe, particularly in Germany, Austria, and Switzerland. Climate change and precipitation patterns affect rainwater availability and quality. RWH can be used for various purposes, including drinking, but requires proper purification for health safety. It is also being implemented in new locations like airports and large buildings. RWH systems have a high potential to overcome undesired results of climate change. Among that, numerous aspects still need to be considered in the future that allow the application of RWH systems on a larger scale. [ABSTRACT FROM AUTHOR]

Published

2024

118. The Potential use of Reclaimed Water for Irrigation Purposes: Is it Overestimated?

Author

Expósito, Alfonso, Díaz-Cano, Esther, and Berbel, Julio

Subjects

WATER management, CLIMATE change adaptation, WATER use, CIRCULAR economy, WATER shortages

Abstract

The use of reclaimed water is expected to increase in the coming years, mainly in water-scarce areas. In the European Union (EU), an increase in the use of reclaimed water is expected to play a significant role within the European circular economy strategy and climate change adaptation policies with the aim to enhance overall sustainability of water resource management. While several institutions have offered estimations of the potential of reclaimed water reuse in the EU context, these estimations tend to overestimate potential reuse volumes since they fail to fully consider the following important issues: (a) the role of return flows in basins where cascade reuse is crucial in maintaining downstream uses (including ecological flows); (b) the availability of abundant (and cheaper) conventional resources; and (c) the economic productivity of water as an indicator of users' willingness to pay for reclaimed water. This study focuses on the Spanish case since this is currently the EU member state with the highest potential for reclaimed water reuse. Findings show that previous estimations of reusable water volumes in Spain may have overestimated potential volumes. The proposed analysis can be extrapolated to other EU regions, where realistic estimations of the potential of reclaimed water might be much needed. [ABSTRACT FROM AUTHOR]

Published

2024

119. Molasses-based waste water irrigation: a friend or foe for carrot (Daucus carota L.) growth, yield and nutritional quality.

Author

Nijabat, Aneela, Mubashir, Muhammad, Mahmood ur Rehman, Muhammad, Siddiqui, Manzer H., Alamri, Saud, Nehal, Javeria, Khan, Rahamdad, Zaman, Qamar uz, Haider, Syda Zahra, Akhlaq, Muhammad, and Ali, Aamir

Subjects

*SEWAGE, *SEWAGE purification, *CHEMICAL oxygen demand, *WATER shortages, *IRRIGATION farming, *CARROTS

Abstract

Management of molasses-based wastewater generated in yeast and sugar industries is a major environmental concern due to its high chemical oxygen demand and other recalcitrant substances. Several strategies have been used to reduce the inland discharge of wastewater but the results are not satisfactory due to high operating cost. However, reuse of molasses-based wastewater irrigation in agriculture has been a major interest nowadays to reduce the freshwater consumption. Thus, it is crucial to monitor the impacts of molasses-based waste water irrigation on growth, metabolism, yield and nutritional quality of crops for safer consumer's health. In present study, carrot seeds of a local cultivar (T-29) were germinated on filter paper in Petri dishes under controlled conditions. The germinated seeds were then transplanted into pots and irrigated with three different treatments normal water (T0), diluted molasses-based wastewater (T1), and untreated molasses-based wastewater (T2), in six replicates. Results revealed that carrot irrigated with untreated molasses-based waste water had exhibited significant reductions in growth, yield, physiology, metabolism, and nutritional contents. Additionally, accumulation of Cd and Pb contents in carrot roots irrigated with untreated molasses-based waste water exceed the permissible limits suggested by WHO and their consumption may cause health risks. While, diluted molasses-based waste water irrigation positively enhanced the growth, yield of carrot plants without affecting the nutritional quality. This strategy is cost effective, appeared as most appropriate alternative mean to reduce the freshwater consumption in water deficit regions of the world. [ABSTRACT FROM AUTHOR]

Published

2024

120. Simultaneous Fresh Water Collection and Li+ Selective Adsorption Enabled by A Salt‐Resistant Separated Solar Evaporator.

Author

Chen, Kai, Li, Lingxiao, Li, Bucheng, Yang, Yanfei, Zhu, Keyu, and Zhang, Junping

Subjects

*FRESH water, *WATER shortages, *ADSORPTION capacity, *SALT, *FULLER'S earth

Abstract

Solar‐driven interfacial evaporation (SIE) of brine may solve the fresh water shortage issue but suffers from salt‐fouling. Meanwhile, adsorption can extract valuable lithium (Li) from brine but is hampered by low adsorption capacity/rate, additional energy input and low selectivity, etc. Here, as a proof‐of‐concept, the design of a separated solar evaporator (S‐evaporator) is reported for simultaneously efficient fresh water collection and Li+ selective adsorption by SIE of brine, accomplishing their complementation using only sunlight. The S‐evaporator consists of a tilted n‐shaped H2TiO3‐modified fabric and a photothermal sheet on it. The superhydrophilic fabric transports brine to the photothermal sheet and provides affluent sites for Li+ adsorption. The photothermal sheet promotes SIE and enhances Li+ adsorption by significantly increasing the fabric's temperature. Consequently, simultaneous fresh water collection and Li+ selective adsorption are realized by the S‐evaporator. Under 1 kW m−2 illumination, the S‐evaporator shows long‐term stable evaporation rate (1.51 kg m−2 h−1) for 20 wt% brine, high Li+ adsorption capacity (20.09 mg g−1), good Li+ adsorption selectivity from real brine and good cycle stability. The S‐evaporator has great application potential for efficiently extracting fresh water and Li+ from brine as demonstrated by the large SIE setup in real outdoor conditions. [ABSTRACT FROM AUTHOR]

Published

2024

121. Dissecting the Superior Drivers for the Simultaneous Improvement of Fiber Quality and Yield Under Drought Stress Via Genome‐Wide Artificial Introgressions of Gossypium barbadense into Gossypium hirsutum.

Author

Han, Bei, Zhang, Wenhao, Wang, Fengjiao, Yue, Pengkai, Liu, Zhilin, Yue, Dandan, Zhang, Bing, Ma, Yizan, Lin, Zhongxu, Yu, Yu, Wang, Yanqin, Zhang, Xianlong, and Yang, Xiyan

Subjects

*EXTREME weather, *WATER shortages, *SEA Island cotton, *GENE silencing, *MEMBERSHIP functions (Fuzzy logic), *COTTON

Abstract

Global water scarcity and extreme weather intensify drought stress, significantly reducing cotton yield and quality worldwide. Drought treatments are conducted using a population of chromosome segment substitution lines generated from E22 (G. hirsutum) and 3–79 (G. barbadense) as parental lines either show superior yields or fiber quality under both control and drought conditions. Fourteen datasets, covering 4 yields and 4 quality traits, are compiled and assessed for drought resistance using the drought resistance coefficient (DRC) and membership function value of drought resistance (MFVD). Genome‐wide association studies, linkage analysis, and bulked segregant analysis are combined to analyze the DR‐related QTL. A total of 121 significant QTL are identified by DRC and MFVD of the 8 traits. CRISPR/Cas9 and virus‐induced gene silencing techniques verified DRR1 and DRT1 as pivotal genes in regulating drought resistant of cotton, with hap3‐79 exhibiting greater drought resistance than hapE22 concerning DRR1 and DRT1. Moreover, 14 markers with superior yield and fiber quality are selected for drought treatment. This study offers valuable insights into yield and fiber quality variations between G. hirsutum and G. barbadense amid drought, providing crucial theoretical and technological backing for developing cotton varieties resilient to drought, with high yield and superior fiber quality. [ABSTRACT FROM AUTHOR]

Published

2024

122. The Wine Quality of Merlot Relies in Irrigation Supplementation and Spotlights Sustainable Production Constraints in Mediterranean‐Type Ecosystems.

Author

Ribalta-Pizarro, Camila, Muñoz, Paula, Munné-Bosch, Sergi, and Wilkinson, Kerry

Subjects

*SUSTAINABILITY, *GRAPE quality, *WATER management, *WATER shortages, *MEDITERRANEAN climate, *VINEYARDS

Abstract

Background and Aims. The Mediterranean climate has been traditionally favorable for winemaking and irrigation practice has been historically avoided and even forbidden, but current productive scenarios are suffering radical changes because of global warming. Therefore, seeking sustainable approaches to improve water availability is key to obtaining high‐quality wines and maintain its style, without affecting yields. Methods and Results. Here, we aim to evaluate the effect of irrigation in Merlot vineyards, on grapes production and quality, and also on wine acceptability. Field‐grown grapevines from cv. "Merlot" were subjected to two different water supplies in the field: (i) nonirrigated plants and (ii) irrigated plants with 50% of crop evapotranspiration, from veraison to commercial harvest. We assessed water stress markers such as leaf relative water content, leaf hydration, and the maximum efficiency of photosystem II photochemistry, as well as grape and wine quality parameters, wine acceptability, and preference with a panel composed of 100 participants. Furthermore, we performed a systematic review study for comparison, including 9 published reports on Merlot grapevines subjected to different water regimes, oriented to improve irrigation decisions, yield, and/or quality. Results showed that half water supply on grapevines not only induced an increase in the volume and weight of grapes, but the resulting wines had a lower total acidity and showed more desirable chromatic properties, increasing colour intensity and hue, and decreasing brightness. Sensory analysis revealed that 63% of the untrained panel preferred wines from the irrigation treatment. Integrating previously reported data, it is observed that water scarcity is favorable for quality only when compared with fully irrigated vineyards. Conclusions. It is concluded that a half irrigation can be enough to improve grape quality under Mediterranean conditions, without affecting yield components and enhancing sensory characteristics that can improve wine acceptance by consumers. Water management approaches to sustainably provide this extra amount of water to irrigate field‐grown grapevines under the current context of climate change are discussed. Significance of the Study. The present study's findings provide valuable information regarding water management in Mediterranean vineyards and its effects on the suitability of these areas to maintain high‐quality wine production. [ABSTRACT FROM AUTHOR]

Published

2024

123. Optimizing irrigation and nitrogen application strategies to improve sunflower yield and resource use efficiency in a cold and arid oasis region of Northwest China.

Author

Xietian Chen, Hengjia Zhang, Shouchao Yu, Chenli Zhou, Anguo Teng, Lian Lei, Yuchun Ba, and Fuqiang Li

Subjects

SUSTAINABILITY, WATER efficiency, IRRIGATION management, LEAF area index, WATER shortages, FERTIGATION, MICROIRRIGATION

Abstract

In arid regions, water scarcity, land degradation and groundwater pollution caused by excessive fertilization are the main constraints to sustainable agricultural production. Optimizing irrigation and fertilizer management regime is an effective means of improving crop water and fertilizer productivity as well as reducing negative impacts on the ecosystem. In order to investigate the effects of different irrigation and nitrogen (N) fertilizer rates on sunflower growth, yield, and water and N use efficiency, and to determine the optimal water and N management strategy, a two-year (2021 and 2022) field experiment with under-mulched drip irrigation was conducted in the Hexi Oasis area of Northwest China. The experiment design comprised three irrigation levels (W1, 55%-65% FC, where FC represents field water capacity; W2, 65%-75% FC; W3, 75% -85% FC) and three N application levels (N1, 120 kg ha-1; N2, 180 kg ha-1; N3, 240 kg ha-1), resulting in a total of nine treatments. The findings indicated that increasing irrigation and N application rates led to improvements in leaf area index (15.39%-66.14%), dry matter accumulation (11.43%-53.15%), water consumption (ET, 1.63%-42.90%) and sunflower yield (6.85%-36.42%), in comparison to the moderate water deficit and low N application (W1N1) treatment. However, excess water and N inputs did not produce greater yield gains and significantly decreased both water use efficiency (WUE) and nitrogen partial factor productivity (NPFP). Additionally, a multiple regression model was developed with ET and N application as explanatory variables and yield, WUE and NPFP as response variables. The results based on the regression model combined with spatial analysis showed that an ET range of 334.3-348.7 mm and N application rate of 160.9-175.3 kg ha-1 achieved an optimal balance between the multiple production objectives: yield, WUE and NPFP. Among the different irrigation and N management strategies we evaluated, we found that W2N2 (65%-75% FC and 180 kg N ha-1) was the most fruitful considering yield, resource use efficiency, etc. This result can serve as a theoretical reference for developing appropriate irrigation and N fertilization regimes for sunflower cultivation in the oasis agricultural area of northwest China. [ABSTRACT FROM AUTHOR]

Published

2024

124. Ultra-high freshwater production in multistage solar membrane distillation via waste heat injection to condenser.

Author

Poredoš, Primož, Gao, Jintong, Shan, He, Yu, Jie, Shao, Zhao, Xu, Zhenyuan, and Wang, Ruzhu

Subjects

SOLAR stills, MEMBRANE distillation, WATER shortages, TECHNOLOGICAL innovations, VAPOR pressure, WASTE heat

Abstract

Passive solar membrane distillation (MD) is an emerging technology to alleviate water scarcity. Recently, its performance has been enhanced by multistage design, though the gains are marginal due to constrained temperature and vapor pressure gradients across the device. This makes condenser cooling enhancement a questionable choice. We argue that condenser heating could suppress the marginal effect of multistage solar MD by unlocking the moisture transport limit in all distillation stages. Here, we propose a stage temperature boosting (STB) concept that directs low-temperature heat to the condensers in the last stages, enhancing moisture transport across all stages. Through STB in the last two stages with a heat flux of 250 W m−2, a stage-averaged distillation flux of 1.13 L m−2 h−1 S−1 was demonstrated using an 8-stage MD device under one-sun illumination. This represents an 88% enhancement over the state-of-the-art 10-stage solar MD devices. More notably, our analysis indicates that 16-stage STB-MD devices driven by solar energy and waste heat can effectively compete with existing photovoltaic reverse osmosis (PV-RO) systems, potentially elevating freshwater production with low-temperature heat sources. Multistage solar membrane distillation is facing challenges with current system designs due to constrained temperature and vapor pressure gradients. Here, the authors propose a stage temperature-boosting concept that enhances moisture transport with up to 88% improvement in overall distillate flux. [ABSTRACT FROM AUTHOR]

Published

2024

125. Optimising the effectiveness of osmotic desalination process by using graphene-based nanomaterials.

Author

Jain, Harshita

Subjects

SUSTAINABILITY, WATER shortages, WATER purification, WATER management, WASTE recycling, SALINE water conversion

Abstract

This work examines how graphene-based nanoparticles can be integrated into membranes to improve the effectiveness of water treatment in osmotic desalination processes. This is important since sustainable practices can help address the world's water scarcity. Water treatment, desalination, and resource recovery are areas where osmotic desalination shows great potential. However, membrane performance constraints frequently impede its efficacy. High mechanical strength, superior hydrophilicity, and the ability to lessen internal concentration polarisation are just a few of the remarkable qualities that make graphene-based nanoparticles stand out. In order to increase the membranes' overall functionality, these nanoparticles were created and added to them. Comparing the study to conventional membranes, the main goals were to increase water flux rates and salt ion rejection capacities. It was shown by experimental results that the membranes strengthened with graphene-based nanoparticles performed better. They outperformed conventional membranes in terms of water flow growth and salt ion rejection rates improvement. In order to advance osmotic desalination technologies towards more effective and sustainable water treatment options, this study highlights the revolutionary potential of graphene-based nanoparticles. Graphene-based nanoparticles provide an attractive option for tackling major water issues worldwide by improving membrane characteristics that are essential for osmotic desalination, such as permeability and selectivity. Water management techniques that are environmentally sustainable are supported by their integration into membranes, which also enhances performance metrics. This study opens the door for creative approaches to resource recovery and water treatment by providing important insights into the creation of cutting-edge materials specifically designed for osmotic desalination applications. [ABSTRACT FROM AUTHOR]

Published

2024

126. Sustainability of water resources in Caribbean small island developing states: an overview.

Author

Forde, Martin S., Cashman, Adrian, and Mitchell, Kerry

Subjects

WATER management, SUSTAINABILITY, WATER supply, SUSTAINABLE investing, WATER shortages

Abstract

A key to achieving the 17 Sustainable Development Goals is the sustainable provisioning of clean water and sanitation services. The sustainable management of water resources strengthens resilience, protects livelihoods, fosters economic growth, and contributes to poverty reduction. This paper reviews the challenges faced by Caribbean Small Island Developing States (SIDS) with a focus on water resource management. While the Caribbean region is seemingly blessed with water resources, with more than 90% of Caribbean residents having access to improved water, it faces challenges due to inefficient management and diverse geographical realities, creating spatial disparities. Furthermore, economic and physical scarcity coexist with some islands lacking proper infrastructure and others nearing the exhaustion of natural freshwater reserves. Climate change intensifies these issues through variable precipitation patterns and extreme weather events. Additionally, the region's dependence on tourism and susceptibility to environmental pressures necessitates a focus on targets related to SDGs 1 and 8. To address increasing water stress within the region, it is becoming increasingly urgent to identify root causes and develop targeted solutions that consider socioeconomic and environmental factors. The promotion of Integrated Water Resource Management is a key strategy for encouraging increased investment in climate-resilient infrastructure and fostering sustainable financing practices. Article Highlights: Caribbean islands face water scarcity due to climate change, population growth, and outdated infrastructure. Effective water management strategies are crucial for ensuring access to clean water and supporting local economies. Collaborative efforts and investments in resilient infrastructure can enhance water security across the region. [ABSTRACT FROM AUTHOR]

Published

2024

127. Techno-economic analysis of a pressure retarded osmosis (PRO) - seawater reverse osmosis (SWRO) hybrid: a case study.

Author

Ahmed, Amr, Alghamdi, Ahmed, Ahmed, Sultan, and Ruiz-García, Alejandro

Subjects

REVERSE osmosis in saline water conversion, HYBRID systems, WATER shortages, REVERSE osmosis, NET present value, SALINE water conversion

Abstract

This study offers a thorough techno-economic evaluation of a hybrid desalination system merging Pressure Retarded Osmosis (PRO) with Seawater Reverse Osmosis (SWRO) process. The primary aim is to determine the feasibility and economic viability of the hybridized approach to conventional SWRO methods. Diverse scenarios are studied based on parameters such as PRO module costs, energy savings achievable and payback period. Our findings reveal the potential for energy savings through the PRO-SWRO hybrid system. For instance, in scenarios where PRO membrane costs are low, such as $450 per element, and electricity prices are relatively high at $0.12 per kilowatt-hour, energy savings of up to 7% are attainable compared to standalone SWRO setups. This potential could be amplified with increasing salinity levels in the feed solution and higher draw solution pressures. The study extends beyond theoretical analysis, offering practical solutions for the design and implementation of sustainable desalination solutions; by studying the interaction between various parameters and their impact; on both energy consumption and economic viability. The current study estimates the membrane break-even costs of a PRO-SWRO hybrid system by estimating and equating the Net Present Value (NPV) of the SWRO system (base configuration) with the NPV of the PRO-SWRO hybrid. This research lays a solid foundation for the development of hybrid desalination systems capable of addressing water scarcity challenges in a cost-effective and environmentally sustainable manner. [ABSTRACT FROM AUTHOR]

Published

2024

128. Using exploratory modeling to challenge narratives of risk governance in Mexico City.

Author

Eakin, Hallie, Bojórquez-Tapia, Luis A., Miquelajauregui, Yosune, Grave, Ileana, Hernandez Aguilar, Bertha, and Janssen, Marco A.

Subjects

*WATER shortages, *MUNICIPAL water supply, *MUNICIPAL government, *FLOOD risk, *DECISION making

Abstract

Achieving more sustainable adaptation to social-environmental change demands the transformation of the narratives that provide the rationale for risk governance. These narratives often reflect long-standing beliefs about social and political relationships, ascribe actions and responsibilities, and specify solutions to risk. When such solutions are implemented through material investments in landscapes, these narratives become embedded in physical infrastructure with long legacies. Dominant narratives can mask a range of divergent problem framings. By masking alternatives, narratives can contribute to the persistence of unsustainable governance trajectories. Decision-support tools have begun to represent narratives as drivers of system dynamics; making narratives visible can reveal opportunities for more sustainable governance. We present the results of the project "The Dynamics of Multi-Scalar Adaptation in the Megalopolis", a dynamic, exploratory model of socio-hydrological risks in Mexico City that was designed to both endogenize and simultaneously challenge the dominant narratives that characterize water-risk governance in the city. Qualitative data characterize dominant narratives at city and borough scales. An agent-based model, informed by multicriteria decision analysis and coupled with hydrological, urbanization, and climatic model inputs, permitted the development of exploratory governance scenarios designed to challenge dominant narratives. Scenarios revealed how dominant narratives may contribute to the persistence of vulnerability "hotspots" in the city, despite stated goals of equity and vulnerability alleviation. Participatory workshops with representatives of the city government illustrate how making such narratives visible through exploratory modeling can lead to a questioning of prior assumptions and causal relations, recognition of a need for intersectoral collaboration, and insights into potential management strategies. [ABSTRACT FROM AUTHOR]

Published

2024

129. RECONSTRUCTING YEMEN: LONG-TERM AND WAR-RELATED CONSTRAINTS TO SOCIO-ECONOMIC DEVELOPMENT.

Author

Lackner, Helen

Subjects

*POSTWAR reconstruction, *HUMANITARIAN assistance, *WATER shortages, *CLIMATE change, *INFRASTRUCTURE (Economics)

Abstract

Many of the proposals for post-war reconstruction of Yemen are founded upon idealistic and unrealistic visions of the state of the country. This article, by contrast, focuses on the multiple and complex problems which will have to be faced once Yemen returns to a semblance of recognisable governance. It lists the different types of constraints which will have to be addressed, both intrinsic and international. Internally, there are both long-standing factors which are unrelated to the war situation and others which are largely war-related. Externally there are factors which depend on the country's international partners, such as the states of the Gulf Cooperation Council (GCC) and multilateral and international financial institutions. In the first category, water scarcity and other climate change factors are the most fundamental, followed by demographic issues including social infrastructure, the age pyramid and the overall discrepancy between the growing size of the population and the available natural resources. War – related constraints are primarily of two kinds: the deep and serious fragmentation of the country, and the socio-economic impact of years of dependence on humanitarian aid. Equally important, are the development strategies imposed by the external financiers and the likelihood that the available financing will be well below both need and expectation. Throughout, the article briefly outlines suggestions to address these constraints, insofar as this can be done in ignorance of the outcome of the war. [ABSTRACT FROM AUTHOR]

Published

2024

130. ارزیابی و بهینه سازی اتصال هیدرولوژیکی با هدف مدیریت منابع آب در حوزه آبخیز سامیان.

Author

زینب حزباوی and نازیلا علائی

Subjects

*WATER management, *WATER shortages, *MOLECULAR connectivity index, *FUNCTIONAL connectivity, *CENTER of mass

Abstract

Water scarcity has become a critical issue in some regions. Accordingly, increasing attention has been given to the structural and functional connectivity of river networks as the primary source of surface water supply, while this can be a potential watershed-scale management solution. However, assessment of hydrological connectivity remains understudied in Iran. This pioneering research aimed to evaluate and optimize the hydrological connectivity in the Samian Watershed to enhance protection and management of water resources and improve hydrological performance. The results showed that the hydrological network in the Samian Watershed with a total length of 1254.73 km had 173 links and 176 nodes. The river chain node ratio (β), actual bonding degree (γ), Index of Integration of Connectivity (IIC), and Probability of Connectivity (PC) were calculated to be 0.983, 0.331, 5.66, and 1.151, respectively. The hydrological structure of the Samian Watershed in the plain areas exhibited weak connectivity. After optimization, the center of gravity of water circulation shifted southward at different connectivity levels. Increasing the optimization level up to Level 4 resulted in an improvement in the hydrological connectivity indices within the Samian Watershed. While the overall connectivity showed a sudden increase after the 4th optimization level, the IIC increased but then decreased beyond Level 4. Therefore, it is recommended to optimize the hydrological connectivity in the Samian Watershed up to Level 4 for effective management of water resources. [ABSTRACT FROM AUTHOR]

Published

2024

131. Antirrhinum majus Bitkisinin Gelişim Parametreleri Üzerine Kısıntılı Sulamanın Etkisi.

Author

SEZEN, Işık, KARAHAN, Ayşe, AKPINAR KÜLEKÇİ, Elif, and YAĞANOĞLU, Sevda

Subjects

*ORNAMENTAL plants, *WATER shortages, *SUSTAINABLE consumption, *CITIES & towns, *WATER use

Abstract

It is predicted that the majority of the world's population will live in cities in 2050. Rapid population growth in cities brings environmental problems. All these problems change the climate negatively. Changes and decreases in the precipitation regime due to climate change cause drought problems. Considering the world average, it is seen that 70% of usable water is consumed for irrigation purposes. Türkiye's average is 72%. As the development level of countries increases, water consumption for irrigation purposes decreases. It is known that a large amount of water consumed for irrigation purposes is used in green areas in urban landscaping works. For this reason, developed countries have started to apply techniques such as limited irrigation and rational use of water in their parks and gardens. They had to tend to use the less water consumed by plants in larger areas, reduce the usage areas of plants that consume more water, and use plants in planting areas by zoning them according to their water needs. The highest water consumption is from grass plants and seasonal flowers, which are indispensable for green areas in cities. Although the highest water consumption is in green areas where ornamental plants are used in urban areas, very few academic studies have been conducted on water shortage in ornamental plants. The purpose of this research; The aim of the study is to observe the change in the development parameters of the Antirrhinum majus plant, the most commonly used seasonal flower that causes excessive water consumption in green areas in cities, by subjecting it to restricted irrigation. In this context; Four different irrigation rates were applied: 25%, 50%, 75% and 100%. 18 development parameters were examined to determine the effect of different irrigation applications. As a result of the research; It was observed that in Antirrhinum majus plant, 17 out of 18 growth parameters showed more development in 75% water application than in 100% water application. These results show that the 75% (25% reduction) application is more advantageous. When using the Antirrhinum majus plant in urban areas, it is recommended to reduce water by 25%. In this case, significant water savings will be achieved in the urban landscape. It is recommended that Antirrhinum majus plants, whose development is not affected by water shortages, are frequently used in urban landscapes. [ABSTRACT FROM AUTHOR]

Published

2024

132. The Ideal Hand Hygiene Method in the Age of Water Scarcity: A Systematic Review and Meta-analysis.

Author

Sridhar, Lingam, Phadnis, Rohit, Tiruchirapalli, Krishna Sahitha, Hussain, Faiz, Kurumella, Subrahmanya Narayan Dora, and Chappidi, Sarath Chandra

Subjects

*HAND care & hygiene, *WATER shortages, *META-analysis, *EPIDEMIOLOGY, *POSTOPERATIVE care

Abstract

In modern times, surgical site infections (SSIs) are defined as infections occurring within 30 days after surgery (or 1 year in patients with implants) at the incision or deep tissue level. Purulent drainage should be observed and organisms from the site should be isolated for epidemiological purposes. Most of the factors contributing to SSIs are patient-related, as the majority of infections are caused by endogenous flora. It has also been suggested that unclean operating hands due to glove contamination do not affect rates of postoperative infections. While the traditional surgical scrub has so far stood the test of time, it is important to consider its environmental impact. There have been multiple attempts to reduce the carbon footprint of the surgical hand scrub, including usage of a different model of tap but there is an easier option available to us: hand rubbing. It takes up significantly less water, as reported by some of the studies given above. It is also particularly beneficial in resource-limited settings. All studies except one reported that hand rub solutions are also more affordable, making them accessible in poorer countries and hospitals. Our study results similarly suggest that waterless hand rubbing is at least as effective as hand scrubbing in preventing SSIs, and is a viable solution to address water scarcity concerns. [ABSTRACT FROM AUTHOR]

Published

2024

133. Effects of Different Irrigation Levels on Sugar Beet and Potential Use of Crop Water Stress Index in Irrigation Scheduling.

Author

Irik, H. A., Kaymaz, E., Samutoglu, H. Neslihan, Gurkan, O. F., and Unlukara, A.

Subjects

*WATER management, *LEAF area index, *WATER shortages, *MICROIRRIGATION, *IRRIGATION water, *IRRIGATION scheduling

Abstract

With the increasing world population, global warming, and climate change, water scarcity significantly limits water use in crop production. Therefore, timely and accurate determination of water stress is very important for the correct and effective management of existing water resources and minimizing harmful effects on crop production. Two years of experiments were conducted in the water-limited region in Türkiye to investigate the possible use of the Crop Water Stress Index (CWSI) as a remote sensing technology in sugar beet irrigation scheduling. Four different Irrigation levels (I50: 50% deficit, I75: 25% deficit, I100: full irrigation, and I125: 25% excess irrigation) were applied to sugar beet by drip irrigation system. The amount of applied irrigation water and crop evapotranspiration varied between 238-540 and 350-580 mm in 2021, and between 324- 807 and 502-829 mm in 2022. In both years, the highest beed yields were obtained from I100 treatments (83 and 130 t ha-1) and the lowest from I50 treatments (66.7 and 67.4 t ha-1). Water Productivity (WP) and Irrigation Water Productivity (IWP) in both years decreased significantly by excessive irrigation. CWSI values ranged between 0.16-0.98 in 2021 and between 0.02-0.71 in 2022. CWSI was significantly related to yield and Leaf Area Index (LAI). According to the results, CWSI could be used successfully in sugar beet irrigation scheduling and yield estimation. [ABSTRACT FROM AUTHOR]

Published

2024

134. Optimizing Rice (Oryza sativa L.) Irrigation to Introduce the Optimum Genotype for Grain Yield and Quality Promotion.

Author

Habibi, M., Mazloom, P., Nasiri, M., Eftekhari, A., and Moballeghi, M.

Subjects

*IRRIGATION management, *WATER shortages, *RICE, *GRAIN yields, *WATER consumption

Abstract

Utilizing new irrigation techniques to introduce cultivars into paddy fields experiencing water scarcity is one way to combat water shortage and increase water productivity. To this end, this experiment was conducted as a strip plot in a randomized complete block design with three independent replications over two years (2016 and 2017) at the Rice Research Institute of Iran, Amol, Iran. Ten rice genotypes (V1 to V10) were subjected to three types of irrigation systems, including conventional Flood Irrigation (FI) and Alternate Wetting and Drying (AWD) at 10 (AWD10) and 20 (AWD20) cm below the soil surface. These results demonstrate that AWD10 and AWD20 methods reduced water consumption by 20 and 17%, respectively, compared to the conventional methods. This decreased water usage resulted in 1.4 and 0.2% yield losses compared to the conventional flood irrigation system. Moreover, milling recovery in flood irrigation (68.7%) was lower than AWD10 and AWD20 methods (69.6 and 69.8%, respectively). In conclusion, Neda, Shiroodi, and 8611 rice genotypes showed a better response to AWD irrigation, and may be considered as suitable genotypes for increasing water productivity in paddy fields. [ABSTRACT FROM AUTHOR]

Published

2024

135. 农业补贴对新疆棉花灌溉用水效率的影响 —农户耕地经营规模的中介效应.

Author

杨传艳 and 马琼

Subjects

*WATER efficiency, *AGRICULTURAL subsidies, *WATER shortages, *AGRICULTURAL development, *AGRICULTURAL policy

Abstract

Water resources are a prerequisite constraint for agricultural development, and their utilization efficiency has a significant impact on economic and social development. Effectively measuring the impact of agricultural subsidies on irrigation water use efficiency is important for assessing agricultural subsidy policies and improving water use efficiency. To assess the impact of agricultural subsidies and farmland operation scale on cotton irrigation water use efficiency on the basis of research data of 312 farm households in Xinjiang, China, in 2023, we used the transcendental logarithmic stochastic frontier production function model and analyzed the nonlinear impacts of agricultural subsidies and farmland operation scale on the irrigation water use efficiency of Xinjiang cotton with the Tobit model. The results showed that the average cotton irrigation water use efficiency of the farmers was 0.560, and the loss of efficiency was relatively serious. The agricultural subsidies and farmland operation scale of the farmers had a direct inverted“U”effect on the cotton irrigation water use efficiency. The farmland operation scale had a mediating effect on the impact of agricultural subsidies on cotton irrigation water use efficiency. The study shows that, to improve irrigation water use efficiency in the context of the coexistence of severe water scarcity and low water use efficiency in Xinjiang, policy efforts should be increased in terms of promoting moderate agricultural subsidies and guiding farmers to operate on an appropriate scale. [ABSTRACT FROM AUTHOR]

Published

2024

136. Improving the Growth and Productivity of Two Varieties of Mung Bean (Vigna radiata L.) by using Different Cultivation Methods and Dates.

Author

Ali, M. A., Khaleel, A. T., and Khaleel, S. T.

Subjects

*LEAF area index, *AGRICULTURE, *WATER shortages, *SEED yield, *ENVIRONMENTAL quality, *MUNG bean

Abstract

Background: Mung bean is characterized by its ability to withstand water scarcity due to its short life span, so it can be introduced into agricultural rotation systems and despite especially when there is a lack of humidity and contemporary environmental changes. Despite the importance of this crop, its productivity rate in Iraq is still low compared to global production. The dates and methods of cultivation of the mungbean crop must be determined accurately to suit the specifications of local varieties adapted to the changing environmental conditions. Methods: The field study was applied in two fields: the first in Nineveh Governorate and the second in Erbil Governorate / Republic of Iraq. Three factors included, first: two varieties of local mung bean (black and green), second: different cultivation methods (furrow and lines) and the third: planting dates (May 15, June 15 and July 15). The study was designed as a factor experiment a design (R.C.B.D) with three replicates. Result: The first variety superior significantly in the two sites with the qualities of plant height, leaf area, leaf area index, seed yield, biological yield and harvest index. From the results of the dates, we note a significant superiority of the first date number of seeds.pod-1 while the third date significantly outperformed the germination percentage for the two sites. First planting method significant superiority in most of the studied characterists and for the two research sites. Significant superiority was recorded for the interactions of research factors and their levels. [ABSTRACT FROM AUTHOR]

Published

2024

137. Adoption Pattern of Direct-Seeded Rice Systems in Three South Asian Countries during COVID-19 and Thereafter.

Author

Kaur, Simerjeet, Ahmed, Sharif, Awan, Tahir Hussain, Ali, Hafiz Haider, Singh, Rajbir, Mahajan, Gulshan, and Chauhan, Bhagirath Singh

Subjects

*COVID-19 pandemic, *UPLAND rice, *COVID-19, *RICE seeds, *TRAVEL restrictions, *WATER shortages

Abstract

COVID-19 has caused a deep economic impact on the lives of small and marginal farmers due to travel restrictions, market closures, and social distancing requirements. Due to COVID-induced labor scarcity and water shortage in India, direct-seeded rice (DSR) has emerged as a viable alternative to puddled transplanted rice (PTR). However, there was plenty of labor available in Pakistan and Bangladesh for rice cultivation during COVID-19 times. Therefore, both countries did not observe the shift from PTR to DSR. The cost of inputs, such as seed, fertilizer, pesticide, and fuel, was high due to a supply–demand conflict during the COVID-19 pandemic in three countries. Farmers faced weed problems and physical and/or economical non-availability of suitable machinery for DSR cultivation during the COVID-19 pandemic. In the later years of 2022 and 2023 (post-COVID), the area under DSR decreased by 88% in India, while it remained stagnant in Pakistan and Bangladesh. [ABSTRACT FROM AUTHOR]

Published

2024

138. Artificial water point use by large African mammals in a small enclosed savannah‐woodland reserve: Insights from an 8‐year study.

Author

Nieman, Willem A. and Leslie, Alison J.

Subjects

*ECOLOGICAL integrity, *WILDLIFE refuges, *HUMAN settlements, *WATER shortages, *WATER supply

Abstract

Maintaining water availability is crucial for sustaining wildlife populations in African savannah ecosystems, especially in semi‐arid regions where natural surface water sources are limited. The establishment of Artificial Water Points (AWPs) has become a common management strategy in protected areas to mitigate the effects of water scarcity. This study investigated the spatio‐temporal patterns of mammal visitation to AWPs in Majete Wildlife Reserve, Malawi, over an eight‐year period using motion‐triggered camera traps. The study documented a total of 34 medium‐ to large‐sized mammal species, with warthog, waterbuck, impala and yellow baboon being the most frequently captured. Temporal analysis reveals diurnal visitation patterns, with peak activity during mid‐day hours, and seasonal variations, with most species exhibiting increased visitation during the hot‐dry season. Spatial analysis identifies preferences for AWPs proximate to perennial rivers and tourist infrastructure, emphasising the role of habitat features and human presence in AWP utilisation. Management implications include the need for tailored strategies addressing species‐specific behaviours and habitat conditions, alongside ongoing monitoring efforts to ensure the sustainability of wildlife populations and ecological integrity. Despite the inherent limitations of camera trap methodology, this study provides valuable insights into AWP management strategies essential for conserving biodiversity in semi‐arid environments. [ABSTRACT FROM AUTHOR]

Published

2024

139. Transition toward Sustainability in the Moroccan Food System: Drivers, Outcomes, and Challenges.

Author

Benayad, Asmaa, Bikri, Samir, Hindi, Zakia, Lafram, Amina, Belfakira, Chaimaa, Yassif, Fatima-Zahra, El Bilali, Hamid, and Aboussaleh, Youssef

Subjects

*WORLD hunger, *EVIDENCE-based policy, *SUSTAINABLE development, *WATER shortages, *GREY literature

Abstract

Nowadays, food systems are undergoing major transformations to achieve the 2030 Sustainable Development Goals (SDGs). However, there are a lack of comprehensive reviews on this topic in developing countries. This work highlights food systems' transition towards sustainability, focusing on Morocco. It was carried out through searching, selecting, evaluating, and synthesizing existing relevant scholarly and gray literature. In Morocco, a meaningful transition towards sustainability is being guided and carried out on several levels, despite numerous challenges, e.g., inability to cope with the detrimental effects of climate change and escalating water scarcity constitute fundamental problems. However, there are conflicting views on the outcomes of food system transformation. Some studies showed that Morocco has increased its agri-food export and reduced poverty to less than 5% of the population over the past decade; the proportion of wasted and malnourished children has declined from 25 to 15% and 4 to 3%, respectively, and the 2023 Global Hunger Index (GHI) showed a score of 9.0. Other studies showed that North Africa has entered a food security crisis; specifically, food inflation has reached unprecedented levels in Morocco. This paper provides valuable insights for policymakers and planners to design evidence-based policies and strategies to boost sustainable development in Morocco. [ABSTRACT FROM AUTHOR]

Published

2024

140. Are Water Use Efficiency and Effectiveness Relatively Lower in Arid Zones? Comparative Analyses of the Water Productivity of Typical Crops.

Author

Zhang, Yanfei, Long, Aihua, Zhang, Pei, Deng, Xiaoya, and Gu, Xinchen

Subjects

*WATER efficiency, *WATER use, *WATER shortages, *ARID regions, *WATER management

Abstract

Agriculture is the largest water user of all sectors. In arid regions in particular, achieving efficient water use in agriculture is an important way to solve water scarcity. However, the difference in water use efficiency between arid and humid regions has long been a focus of academic debate. Many studies consider water use efficiency to be higher in humid areas due to the abundance of water resources. This view is based on the fact that less irrigation in humid areas may lead to higher crop yields and better conditions for agricultural production; however, it ignores the efforts of researchers and agricultural workers in arid zones who have attempted to develop efficient water-saving technologies, as well as the effect of natural conditions on agricultural production. Correctly evaluating the efficiency of agricultural water use in arid zones is important for achieving efficient use of water resources, as well as for water management decisions. This study calculates the yield structure and water productivity of typical crops in both arid and humid regions in China based on the footprint theory and other methodologies. This approach allows for an accurate assessment of irrigation water benefits in various regions, providing a scientific basis for improving agricultural water use efficiency under different climatic conditions. The study results indicate that the average reliance on blue water for wheat and cotton gradually increases from 49.9% to 93.6% as regional aridity intensifies, ranging from the Central China Humid Region to the Northwest China Arid Region. Similarly, the average contribution of blue water to crop yield rises from 31.0% to 100%, while irrigation water productivity increases from 0.27 kg·m−3 to 0.53 kg·m−3. Finally, this study concludes that, in arid zones with lower precipitation and more hours of sunshine, a higher dependence on blue water for crop growth and development leads to a higher productivity of irrigation water. In addition, in arid zones, the focus should be on optimizing the use of irrigation water and improving irrigation technology and efficiency, while, in humid zones, there should be more use of natural precipitation to efficiently reduce dependence on irrigation water. [ABSTRACT FROM AUTHOR]

Published

2024

141. Genotype and Nitrogen Source Influence Drought Stress Response in Oil Palm Seedlings.

Author

Ruiz-Romero, Rodrigo, De la Peña, Marlon, Ayala-Díaz, Iván, Montoya, Carmenza, and Romero, Hernán Mauricio

Subjects

*WATER shortages, *SUSTAINABLE agriculture, *AGRICULTURE, *PLANT performance, *ROOT development, *DROUGHT management, *OIL palm

Abstract

As a significant global source of vegetable oil, the oil palm's ability to withstand abiotic stresses, particularly drought, is crucial for sustainable agriculture. This is especially significant in tropical regions, where water scarcity is becoming more common. Nitrogen, a vital nutrient, plays an essential role in various physiological and biochemical processes in plants, directly influencing growth and stress tolerance. This study investigates the interaction between nitrogen sources (ammonium vs. nitrate) and drought stress in oil palm (Elaeis guineensis) seedlings, which is critical in enhancing productivity in this economically important crop. The experiment evaluated five commercial oil palm genotypes, which were supplied with nitrogen solutions (15 mM NH4+ or NO3−) for 46 days, followed by 30 days of progressive drought. The results showed that drought conditions universally reduced the biomass, with ammonium-fed plants exhibiting greater shoot biomass sensitivity than nitrate-fed plants. Drought also significantly decreased the chlorophyll a, PhiPS2, and root-reducing sugar levels—critical indicators of photosynthetic efficiency and overall plant health. The effects on the root architecture were complex, with ammonium nutrition differentially influencing the lateral root length under well-watered versus drought conditions, highlighting nitrogen forms' nuanced role in root development. Importantly, substantial genotypic variability was observed in most traits, affecting the responses to both the nitrogen source and drought stress. This variability suggests that certain genotypes may be better suited to cultivation in specific environmental conditions, particularly drought-prone areas. In conclusion, this study underscores the intricate interplay between nitrogen nutrition, genotypic variability, and drought tolerance in oil palm seedlings. These findings highlight the need to integrate these factors into agricultural management strategies to improve resilience and productivity in oil palm plantations. [ABSTRACT FROM AUTHOR]

Published

2024

142. The Effects of Bio-Fertilizer by Arbuscular Mycorrhizal Fungi and Phosphate Solubilizing Bacteria on the Growth and Productivity of Barley under Deficit of Water Irrigation Conditions.

Author

Alotaibi, Mashael M., Aljuaid, Alya, Alharbi, Maha Mohammed, Qumsani, Alaa T., Alzuaibr, Fahad Mohammed, Alsubeie, Moodi S., Ismail, Khadiga Ahmed, Gharib, Hany S., and Awad-Allah, Mamdouh M. A.

Subjects

*PHOSPHATE fertilizers, *DROUGHT tolerance, *VESICULAR-arbuscular mycorrhizas, *WATER shortages, *IRRIGATION water, *BARLEY, *BIOFERTILIZERS

Abstract

Bio-fertilizers are the most important and effective method used to reduce the quantities of chemical fertilizers consumed and reduce dependence on them in agricultural production to avoid their harmful effects on the environment and public health as well as reduce the cost of agricultural production in light of increasing pollution and under adverse conditions for production and climate change. A bio-fertilizer depends primarily on the use of beneficial microorganisms such as arbuscular mycorrhizal fungi (AMF) to improve the uptake of nutrients, improve plant growth, productivity, and grain yield. Crop production faces many challenges, and drought is one of the majority of the significant factors limiting crop production worldwide, especially in semi-arid regions. The objective of this study was to evaluate the effects of AMF and phosphate solubilizing bacteria (PSB), plus three rates of the recommended dose of phosphorus (RDP) fertilizer on yield, yield components, and nutrients uptake, in addition to evaluating the beneficial effects of these combinations to develop Phosphorus (P) management under three levels of irrigation water, i.e., three irrigations (normal or well-watered), two irrigations (moderate drought), and one irrigation (severe drought) on barley (Hordeum vulgare L.). The results showed that the treatment with AMF bio-fertilizer yielded the highest values of plant height, spike length, spike weight, number of grains/spike, 1000-grain weight, grain yield, straw yield, biological yield, and harvest index. Moreover, the grain and straw uptake of nitrogen (N), P, and potassium (K) (kg ha−1) in the two seasons under the three levels of irrigation, respectively, were superior followed by the inoculation by PSB. While the treatment without bio-fertilizer yielded the lowest values of these traits of barley, the treatment with bio-fertilizer yielded the increased percentage of the grain yield by 17.27%, 17.33% with applying AMF, and 10.31%, 10.40% with treatment by PSB. Treatment with AMF or PSB (Phosphorien), plus rates of phosphorus fertilizer under conditions of irrigation water shortage, whether irrigation was performed once or twice, led to an increase in grain yield and other characteristics compared to the same fertilization rates without inoculation. The results of this study showed that the use of bio-fertilizers led to an increase in plant tolerance to drought stress, and this was demonstrated by an increase in various traits with the use of treatments that include bio-fertilizers. Therefore, it is suggested to inoculate the seeds with AMF or PSB plus adding phosphate fertilizers at the recommended dose under drought conditions. [ABSTRACT FROM AUTHOR]

Published

2024

143. Water Relations and Physiological Response to Water Deficit of 'Hass' Avocado Grafted on Two Rootstocks Tolerant to R. necatrix.

Author

Moreno-Pérez, Ana, Barceló, Araceli, Pliego, Clara, and Martínez-Ferri, Elsa

Subjects

*PLANT transpiration, *LEAF area, *WATER shortages, *PHOTOSYNTHETIC rates, *ROOT rots, *AVOCADO

Abstract

Avocado (Persea americana Mill.) cultivation has spread to many countries from the tropics to the Mediterranean region, where avocado crops commonly face water shortages and diseases, such as white root rot (WRR) caused by Rosellinia necatrix. The use of drought- and WRR-tolerant rootstocks represents a potential solution to these constraints. In this research, water relations and the morpho-physiological response of avocado 'Hass' grafted on two selections of R. necatrix-tolerant rootstocks (BG48 and BG181) were evaluated under well-watered (WW) and at two soil-water-availability conditions (WS, ~50% and ~25% field capacity). Under WW, scion water use was markedly affected by the rootstock, with BG48 displaying a water-spender behavior, showing higher water consumption (~20%), plant transpiration rates (~30%; Eplant) and leaf photosynthetic rates (~30%; AN) than BG181, which exhibited a water-saving strategy based upon a trade-off between leaf-biomass allocation and tight stomatal control of transpiration. This strategy did not reduce biomass, with BG181 plants being more water use efficient. Under WS, BG48 and BG181 exhibited a drought-avoidance behavior based on distinct underlying mechanisms, but increases in leaf mass area (~18–12%; LMA), and decreases in Eplant (~50–65%), plant hydraulic conductance (~44–86%; Kh) and leaf water potential (~48–73%; Ψw) were observed in both rootstocks, which aligned with water stress severity. After rewatering, photosynthetic rates fully recovered, suggesting some ability of these rootstocks to withstand water stress, enabling the 'Hass' variety to adapt to region-specific constraints. [ABSTRACT FROM AUTHOR]

Published

2024

144. Water restriction alters seed bank traits and ecology in Atlantic Forest seasonal forests under climate change.

Author

Dias, Patrícia Borges, Horn Kunz, Sustanis, Pezzopane, José Eduardo Macedo, Xavier, Talita Miranda Teixeira, Zorzanelli, João Paulo Fernandes, Toledo, João Vitor, Gomes, Lhoraynne Pereira, and Gorsani, Rodrigo Gomes

Subjects

*WATER restrictions, *CLIMATE change, *SOIL seed banks, *WATER shortages, *WATER consumption, *FOREST regeneration

Abstract

The soil seed bank (SSB) is one of the key mechanisms that ensure the perpetuity of forests, but how will it behave in the scenarios projected for the future climate? Faced with this main question, still little explored in seasonal tropical forests, this study evaluated the germination, ecological attributes, and functional traits of the SSB in a seasonal forest in the Atlantic Forest. Forty‐eight composite samples of the SSB were collected from 12 plots, distributed across four treatments, each with 12 replicates. The samples were placed in two climate‐controlled greenhouses, establishing two environments of controlled climatic conditions, both with two levels of water, as follows: Cur: current scenario without water restriction; Cur_WR: current scenario with water restriction; RCP8.5: future scenario without water restriction; RCP8.5_WR: future scenario with water restriction. The germinants were identified, and their ecological attributes and functional traits were obtained. Leaf area and biomass production, differences in abundance, richness, and diversity were evaluated, along with analysis of variance to assess the interaction between water levels and scenarios. All ecological attributes and functional traits evaluated drastically decreased in the future projection with water restriction, with this restriction being the main component influencing this response. The increased temperature in the future scenario significantly raised water consumption compared to the current scenario. However, persistent water restrictions in the future could undermine the resilience of seasonal forests, hindering seed germination in the soil. Richness and abundance were also adversely affected by water scarcity in the future scenario, revealing a low tolerance to the projected prolonged drought. These changes found in the results could alter the overall structure of seasonal forests in the future, as well as result in the loss of the regeneration potential of the SSB due to decreased seed viability and increased seedling mortality. [ABSTRACT FROM AUTHOR]

Published

2024

145. Assessing seed pellet formulations to improve native plant restoration under water‐limited conditions.

Author

Munro, Thomas P., Erickson, Todd E., Nimmo, Dale G., and Price, Jodi N.

Subjects

*SOIL infiltration, *NATIVE species, *SUPERABSORBENT polymers, *WATER shortages, *WATER supply

Abstract

Water scarcity, a challenge expected to worsen with climate change, significantly hinders native plant community restoration. Enhancing seed‐based restoration requires methods to increase the water availability for seeds and seedlings. Surfactants and superabsorbent polymers (SAPs) can improve soil water‐holding capacity and infiltration, but their use in seed enhancements remains underexplored. We investigated whether pellets containing surfactants or SAPs could improve seedling emergence of two native species (Rytidosperma caespitosum and Chrysocephalum apiculatum) common in temperate grasslands in south‐eastern Australia under different watering treatments. We used a randomized block design with five watering treatments to simulate predicted changes in precipitation for south‐eastern Australia: ambient, two reducing overall water volume, and two reducing watering frequency while increasing watering volume to maintain ambient treatment water volume. We explored four enhanced pellets (two containing surfactants and two containing SAPs) and non‐pelleted seeds. Our results showed that watering events with larger volumes but reduced frequency increased seedling emergence. Under these conditions, block co‐polymer surfactants further increased seedling emergence of C. apiculatum, while synthetic SAP pellets promoted emergence of R. caespitosum. Block co‐polymer surfactants decreased R. caespitosum emergence, and both SAPs reduced C. apiculatum emergence under reduced watering frequency. A 50% reduction in overall water volume significantly reduced seedling emergence for both species, regardless of seed enhancement. These findings suggest that surfactants and SAP pellets can improve the success of seed‐based restoration under ambient conditions and when rainfall events are larger in volume but reduced in frequency, but not when the overall volume of rainfall is reduced. [ABSTRACT FROM AUTHOR]

Published

2024

146. South-to-North Water Diversion Halting Long-Lived Subsidence in Tianjin, North China Plain.

Author

Jiang, Zhongshan, Zhu, Juyan, Guo, Haipeng, Qiu, Keshan, Tang, Miao, Yang, Xinghai, and Liu, Jinyu

Subjects

*URBAN community development, *WATER management, *LAND subsidence, *GLOBAL Positioning System, *WATER supply, *WATER shortages, *WATER diversion

Abstract

The South-to-North Water Diversion Project in China is the world's largest water transfer project, aiming to address water shortages in northern China by channeling water from the water-rich southern regions. Water resources in Tianjin have long been in severe deficit, with excessive groundwater extraction causing significant surface subsidence, negatively impacting urban infrastructure and economic development. As a result, Tianjin has become a key beneficiary of this water diversion project. To investigate the current situation of surface subsidence, we obtained the vertical displacement time series from 21 GNSS stations across Tianjin from 2011 to 2021 and analyzed overall subsidence changes and rehabilitation status. Results indicate that no clear surface subsidence was observed in the northern regions of Tianjin due to groundwater extraction mainly in unconfined aquifers. The southwestern region experienced the most significant surface subsidence due to overexploitation of deep groundwater, with peak cumulative subsidence exceeding 600 mm during the study period. The central, eastern, and southeastern coastal regions also faced severe surface subsidence with cumulative amounts ranging from 100 mm to 400 mm. The alleviation of subsidence predominantly benefits from continuous water supply from the South to North Water Diversion Project, which resulted in most stations significantly slowing down or even stabilizing their settlement rates after 2018. Therefore, the South-to-North Water Diversion Project plays a crucial role in addressing the persistent water resource shortage and mitigating long-term surface subsidence in Tianjin by ensuring a continuous water supply and significantly reducing the need for groundwater extraction. Our findings indicate positive measures, such as water diversion projects and water management policies, can serve as valuable references for other regions around the world facing similar water scarcity and groundwater overexploitation. [ABSTRACT FROM AUTHOR]

Published

2024

147. Development Status of Solar-Driven Interfacial Steam Generation Support Layer Based on Polymers and Biomaterials: A Review.

Author

Yan, Haipeng, Wang, Pan, Li, Lingsha, Zhao, Zixin, Xiang, Yang, Guo, Haoqian, Yang, Boli, Yang, Xulin, Li, Kui, Li, Ying, He, Xiaohong, and You, Yong

Subjects

*WATER pollution, *WATER supply, *INTERFACE stability, *WATER purification, *WATER shortages

Abstract

With the increasing shortage of water resources and the aggravation of water pollution, solar-driven interfacial steam generation (SISG) technology has garnered considerable attention because of its low energy consumption, simple operation, and environmental friendliness. The popular multi-layer SISG evaporator is composed of two basic structures: a photothermal layer and a support layer. Herein, the support layer underlies the photothermal layer and carries out thermal management, supports the photothermal layer, and transports water to the evaporation interface to improve the stability of the evaporator. While most research focuses on the photothermal layer, the support layer is typically viewed as a supporting object for the photothermal layer. This review focuses on the support layer, which is relatively neglected in evaporator development. It summarizes existing progress in the field of multi-layer interface evaporators, based on various polymers and biomaterials, along with their advantages and disadvantages. Specifically, mainly polymer-based support layers are reviewed, including polymer foams, gels, and their corresponding functional materials, while biomaterial support layers, including natural plants, carbonized biomaterials, and other innovation biomaterials are not. Additionally, the corresponding structure design strategies for the support layer were also involved. It was found that the selection and optimal design of the substrate also played an important role in the efficient operation of the whole steam generation system. Their evolution and refinement are vital for advancing the sustainability and effectiveness of interfacial evaporation technology. The corresponding potential future research direction and application prospects of support layer materials are carefully presented to enable effective responses to global water challenges. [ABSTRACT FROM AUTHOR]

Published

2024

148. ANSYS Fluent-CFD analysis of a continuous single-slope single-basin type solar still.

Author

Srishti and Paras, Aditya Kumar

Subjects

*COMPUTATIONAL fluid dynamics, *WATER shortages, *WATER depth, *ARTIFICIAL intelligence, *CLIMATE change

Abstract

The present study endeavours to substantially contribute towards alleviating the global water scarcity problem. The task entailed designing a computational model of a renewable energy-based evaporator. Using ANSYS Fluent, the CFD simulations of a three-dimensional conventional continuous single slope, single basin solar still were carried out in summer at 23.79°N, 86.43°E coordinates. With the optimized inclination condensation angle of 29° and water depth at 1 cm, the solar still recorded the highest hourly drinking water, about 1.5 kg m-2, at 11:00 h. The continuous production resulted in a water collection rate of 8.6 kg m-2 day-1, encompassing the production of all previous models. Additionally, compared with the literature correlation for solar still simulated mass, the Power model calculation was the closest, with a 12.4% variation. Furthermore, the study showcases that CFD is an economical, efficient, and easily diagnosable technique for designing solar stills. [ABSTRACT FROM AUTHOR]

Published

2024

149. Enhancing Profitability of Wheat with Eco-friendly Nitrogen Management Under Restricted Irrigation for Small-scale Farming in India.

Author

Tripathi, S. C., Kumar, Nitesh, and Venkatesh, Karnam

Subjects

*IRRIGATION farming, *WHEAT, *AGRICULTURE, *WATER shortages, *GRAIN yields, *WHEAT farming, *UREA as fertilizer

Abstract

The majority of farmers (85%) in Asia operate on small plots (< 2 ha) under low-input conditions to support their livelihoods. Wheat production in India faces challenges due to water scarcity and suboptimal nitrogen (N) management practices. To address this problem, a multi-location (9) field experiment comprising of 9 treatments by including nano and prilled urea alone or in combination was conducted under restricted irrigation conditions (only two irrigations i.e., first at crown root initiation stage and 2nd at flag leaf stage) during 2021–2022 and 2022–2023 in randomised block design with three replications in three agro-climatic regions (NWPZ- North Western Plains Zone, NEPZ- North Eastern Plains Zone and CZ- Central Zone) of India. Results indicated that combining recommended nitrogen (RDN) i.e., 90 kg/ha with two sprays of 5% urea increased grain yield by 4.1% and 41.9% in NWPZ and NEPZ, respectively, over RDN alone. Two sprays of nano urea at tillering and jointing stages significantly outperformed the control (Zero N), increasing grain yield by 14.5%, 34.0%, and 19.2% in NWPZ, NEPZ, and CZ, respectively. Moreover, RDN with two sprays of nano urea increased the grain yield and agronomic efficiency by 12.1% and 12.0% in CZ and 25.2% and 24.6% in NEPZ over RDN alone, respectively. From a net benefit perspective, RDN with two sprays of 5% urea was 6.7 and 70.4% higher in NWPZ and NEPZ over RDN under restricted irrigation. In CZ, applying RDN with two sprays of nano urea provided 15.5% higher net benefit over RDN. The recommendation for wheat cultivation in small-scale farming systems in India under restricted irrigation conditions suggests adopting a nitrogen management approach combining RDN with two sprays of 5% urea in NWPZ and NEPZ or with two sprays of nano urea in NEPZ and CZ improved the productivity, profitability and agronomic efficiency. [ABSTRACT FROM AUTHOR]

Published

2024

150. Contribution of soil sustainable management to improve coffee nutrition and mitigate water scarcity.

Author

Vilela, Marina Scalioni, Castanheira, Dalyse Toledo, Carvalho, Milene Alves de Figueiredo, Guimarães, Rubens José, Cruvinel, Arthur Henrique, and Nascimento, Pedro José Cintra

Subjects

*SOIL management, *WATER shortages, *SOIL conditioners, *CONTROLLED release of fertilizers, *PLANT nutrition, *FERTIGATION

Abstract

The soil can be managed to improve plant nutrition and resilience under water scarcity. The objective of this study was to evaluate the contribution of soil conditioners, controlled-release fertilizers, and water availability levels to mitigate water scarcity and improve the nutrition of coffee plants. The experiment was conducted in a greenhouse under a randomized block design with four replicates in a factorial scheme (2 irrigation levels × 2 fertilizer types × 5 soil conditioners) of analysis of variance. The factors under study were two irrigation levels (low—40% of water holding capacity, and high—80% of water holding capacity), fertilizer type (conventional and controlled-release), and soil conditioners (coffee husk, gypsum, water-retaining polymer, organic compost, and control without soil conditioner), The characteristics assessed were soil fertility, soil moisture, and nutrient foliar contents. Multivariate analytical methods were used to interpret the results. Soil moisture, chemical attributes, and leaf nutrient contents were analyzed. There was a similarity in the clusters formed by the controlled-release fertilizer treatments, which contribute to plant nutrition. Even under water restriction, the treatments with coffee husk and organic compost were clustered along with soil moisture, favoring the absorption of nutrients. Soil cover with organic compounds improved soil moisture, even under low water availability, which favored plant fertility and nutrition. [ABSTRACT FROM AUTHOR]

Published

2024