Your search keyword '"WATER shortages"' showing total 21,844 results

201. Precision Climate Farming for Sustainable Beauty: A Microgreens Case Study.

Author

Lad, Vaijnath D. and Shukla, Philip G.

Subjects

SUSTAINABLE agriculture, PRECISION farming, CONSUMER behavior, TRANSGENIC seeds, WATER shortages, VERTICAL farming, VEGETABLE oils, PLANT extracts, OLIVE oil

Abstract

The article introduces precision climate farming as a method to sustainably cultivate and optimize plant extracts for cosmetic use. It discusses the cultivation of arugula and cress microgreens under controlled environmental conditions to enhance their antioxidant properties and suitability for eco-friendly formulations. Precision climate farming aims to address environmental concerns by reducing water consumption, eliminating pesticide use, and minimizing energy consumption.

Published

2024

202. Water and power scarcity.

Subjects

WATER power, WATER shortages, POOR communities

Abstract

Karachi, a major economic hub in Pakistan, is facing severe water and power scarcity, causing hardships for its citizens during the heatwave season. The city's water supply is inadequate due to mismanagement and corruption, with outdated pipelines and wastage. Water distribution is also unequal, favoring affluent areas over poorer neighborhoods. Additionally, prolonged power outages are causing misery for residents, with electricity being prioritized for industries instead of citizens. The government needs to address these issues by improving infrastructure, governance, and investments, including the use of local coal and clean energy sources like solar power. [Extracted from the article]

Published

2024

203. Construction of an interface interaction in a g-C3N4/CdS/NiS for photoreforming of plastic and clean hydrogen regeneration.

Author

Yin, Zhe, Chen, Huanyu, Wang, Qiuyu, Wang, Ziwen, Yu, Guoping, Tang, Binglin, Zhang, Man, Li, Kangzheng, Zhang, Zhichao, Luo, Qingcheng, Hu, Tianding, and Lv, Bo

Subjects

*INTERSTITIAL hydrogen generation, *COUPLING reactions (Chemistry), *HYDROGEN evolution reactions, *HYDROGEN as fuel, *PLASTIC scrap, *WATER shortages

Abstract

[Display omitted] • Through accurate material design and construction, seawater can completely replace scarce fresh water to obtain hydrogen energy: Seawater accounts for 96 %∼97 % of the world's water resources, and the use of seawater as a source of hydrogen will alleviate the problem of water shortage; The hydrogen production rates of g-C 3 N 4 /CdS/NiS in seawater and pure water for 5 h are 30.44 and 25.79 mmol/g/h, respectively. After 25 h, the hydrogen production rates are 16.17 mmol/g/h and 15.54 mmol/g/h, respectively; • This is a completely new design concept without sacrificing agents: The use of plastic hydrolysate as a sacrificial agent effectively reduces the pollution caused by other sacrifices, such as Na 2 S/Na 2 SO 3 , methanol, etc; • The mechanism of the whole coupling reaction is discussed and proposed: The photocharge transfer occurs between CdS and g-C 3 N 4 , the CB electrons of the g-C 3 N 4 are transferred to the CB of CdS. The electrons participate in the hydrogen evolution reaction at the reduction site of the NiS to produce hydrogen. The VB hole of CdS is injected into the VB of g-C 3 N 4. The hole will react with lactate in seawater solution to oxidize lactate to pyruvate, acetate and formate. Converting plastics into organic matter by photoreforming is an emerging way to deal with plastic pollution and produce valuable organic matter. Water shortage can be alleviated by using seawater resources. To solve these problems, we synthesize a ternary heterostructure composite g-C 3 N 4 /CdS/NiS. Heterojunctions are formed between graphitized carbon nitride (g-C 3 N 4), cadmium sulfide (CdS) and nickel sulfide (NiS), which effectively improve the problem of fast charge recombination of pure g-C 3 N 4 and CdS. The results of the g-C 3 N 4 /CdS/NiS photocatalytic tests show that the hydrogen production rates in seawater and pure water for 5 h are 30.44 and 25.79 mmol/g/h, respectively. In stability test, the hydrogen production rate of the g-C 3 N 4 /CdS/NiS in seawater and pure water is similar. This suggests that seawater can replace pure water as a source of hydrogen. While H 2 is generated, the lactate obtained by polylactic acid (PLA) hydrolysis is oxidized to form small organic compounds such as formate, acetate and pyruvate. Our study shows that g-C 3 N 4 /CdS/NiS can not only use seawater as a hydrogen source to produce H 2 , but also photoreformate plastics dissolved in seawater into valuable small organic molecules. This has a positive impact on the production and use of clean energy, as well as on plastic pollution and water scarcity. [ABSTRACT FROM AUTHOR]

Published

2024

204. Evolution and health risk of indicator microorganisms in landscape water replenished by reclaimed water.

Author

Chen, Yitong, Qi, Chang, Yu, Yanan, Cao, Xiaoxin, Zheng, Xiang, and Cheng, Rong

Subjects

*WATER shortages, *HEALTH status indicators, *BODIES of water, *SARS disease, *PATHOGENIC microorganisms, *COLIFORMS

Abstract

• The indicator microorganisms increased along the water flow direction. • Indicator microorganisms had a positive correlation with COD. • Increased indicator microorganisms led to over 30% health risk increase. • Indicator microorganisms' concentration was higher in summer/autumn than in spring. • Staff related to water surface operation had the highest health risk. As an important means to solve water shortage, reclaimed water has been widely used for landscape water supply. However, with the emergence of large-scale epidemic diseases such as SARS, avian influenza and COVID-19 in recent years, people are increasingly concerned about the public health safety of reclaimed water discharged into landscape water, especially the pathogenic microorganisms in it. In this study, the water quality and microorganisms of the Old Summer Palace, a landscape water body with reclaimed water as the only replenishment water source, were tracked through long-term dynamic monitoring. And the health risks of indicator microorganisms were analyzed using Quantitative Microbial Risk Assessment (QMRA). It was found that the concentration of indicator microorganisms Enterococcus (ENT), Escherichia coli (EC) and Fecal coliform (FC) generally showed an upward trend along the direction of water flow and increased by more than 0.6 log at the end of the flow. The concentrations of indicator microorganisms were higher in summer and autumn than those in spring. And there was a positive correlation between the concentration of indicator microorganisms and COD. Further research suggested that increased concentration of indicator microorganisms also led to increased health risks, which were more than 30% higher in other areas of the park than the water inlet area and required special attention. In addition, (water) surface operation exposure pathway had much higher health risks than other pathways and people in related occupations were advised to take precautions to reduce the risks. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

205. Assessing the Effects of Water Scarcity and Biofertilizer Application (Pseudomonas putida) on the Growth and Productivity of Different Eggplant (Solanum melongena) Genotypes in Northeastern Morocco.

Author

Maachi, Dina, Ouzouline, Malika, Skiker, Mounia, Oussellam, Mariam, Riouchi, Ouassila, Zerrouk, Mohamed Hassani, Assouguem, Amine, Lahlali, Rachid, El Moukhtari, Ikram, and Aberkani, Kamal

Subjects

PLANT breeding, WATER shortages, PLANT genomes, BIOFERTILIZERS, DROUGHTS, AGRICULTURAL productivity

Abstract

Drought had affected the crops production in Morocco, during the last decade. Plants breeding is still a solution to increase crops tolerance for water scarcity. Using natural biofertilizer based on microorganisms still a good practice to enhance the resilience of agriculture to drought. The objective of this study is to investigate the effect of water shortage and use of a biofertilizer based on the strain of Pseudomonas putida on five genotypes of eggplants selected for drought tolerance under the semi-arid of the northeast of Morocco. Two irrigations regimes: 100% (amount of water irrigation made by growers) and 50% of this amount with and without the biofertilizer (1 × 108 UFC/g). The biofertilizer was applied three times during the plant growth stages. The experiment was conducted at commercial farm production and using a randomized complete block design. Plants were organized in blocks containing 3 plants for each genotype and repeated in 5 repetitions. Crops were planted on August 3rd, 2022, and experiments ended on January 2nd, 2023. The results showed different responses among the genotypes in terms of growth. The effect of Pseudomonas on plant height showed that there was a significant increase, at 100% irrigation for C14, B3, C8, B5 and C11 with 20%, 19%, 17%, 14.29% and 12,5%, respectively compared with the control. For C8 and B3, when subjected to 100% water with biofertilizer, there was an increase in the average number of fruits compared to 100% water without the biofertilizer. The highest yield was recorded with B5 under 100% irrigation + fertilizer (1.35 kg/plant). Water shortage impacted the productivity of all genotypes and the fruit number and yield increased with the use of the biofertilizer. Our study is still valuable under the conditions of this trial and more experiments will be needed at several seasons and at different growing conditions. [ABSTRACT FROM AUTHOR]

Published

2024

206. ЗРОШЕННЯ ТА ПРОДОВОЛЬЧА БЕЗПЕКА В КОНТЕКСТІ ДЕФІЦИТУ ВОДИ: ПРАВОВІ ПРОБЛЕМИ ТА ПЕРСПЕКТИВИ.

Author

Х. А., Григор’єва

Subjects

NATURAL resources, WATER shortages, ALTERNATIVE crops, MICROIRRIGATION, GROUNDWATER

Abstract

The article examines the legal problems and prospects of ensuring the irrigation of agricultural land in conditions of a lack of traditional water resources. Modern hydromelioration reform in the form in which it is currently implemented is not a panacea. It mostly solves property and administrativefunctional issues, but leaves a call for attention to environmental and natural resource problems. In view of the tendency to decrease the quantity and quality of water in the country, the question arises about the prospects of irrigation under such conditions. In recent decades, there has been a constant search for innovative solutions of not only technological, but also legal nature in the world for solving the complex problems of distributing limited resources and providing agriculture with vital moisture for maintaining food security. The objective problem of the lack of water suitable for irrigation against the background of the rapid growth of such needs is getting worse every year and in the long run can endanger the food security of the country. World experience demonstrates the approbation of various approaches to solving the problem of sufficient irrigation. According to the main way of achieving the goal, these approaches are presented by us in the form of three groups: 1) use of alternative sources of water resources (use of underground water, treated wastewater, desalinated salt water); 2) application of alternative irrigation technologies (modernization of irrigation systems; use of micro-irrigation); 3) use of alternative crops (voluntary and mandatory transition). Having analyzed the foreign and domestic experience of the legal regulation of selected methods of solving the problem of water shortage for irrigation, it is possible to trace some general trends: a) self-removal of the state from the implementation of large-scale irrigation projects, the need for which is generated by global environmental challenges; b) slow ecological transformation of legislation regulating agricultural irrigation; c) the predominance of separate legal norms and separate legal mechanisms aimed at regulating alternative irrigation, and the lack of comprehensive regulatory and legal support for the reconstruction of the irrigation system taking into account objective environmental problems. [ABSTRACT FROM AUTHOR]

Published

2024

207. Tailoring the covalent organic frameworks based polymer materials for solar-driven atmospheric water harvesting.

Author

Liu, Xiaomei, Ding, Wenbin, Feng, Tao, Yang, Cailing, Li, Jing, Liu, Pengbo, and Lei, Ziqiang

Subjects

*WATER harvesting, *ORGANIC bases, *POROUS polymers, *POLYMER solutions, *PHOTOTHERMAL conversion, *WATER shortages, *MESOPOROUS materials, *WATER salinization

Abstract

[Display omitted] Atmospheric water harvesting through reticular materials is an innovation that has the potential to change the world. Here, this study offers a technique for creating a solar-powered hygroscopic polymer material for atmospheric water harvesting with the reticular materials. The results show that the porous hygroscopic polymer materials can achieve high performance with high vapor capture (up to ac. 28.8–49.7 mg/g at 28–38 %RH and 25 ℃), rapid photothermal conversion efficiency (up to 32.2 ℃ within 15 min under 1000 W/m−2 light at 25 ℃), a low desorption temperature (lower than 40 ℃), and an effective water release rate. Besides, the material also has excellent water-retention properties, which can effectively store desorbed liquid water in polymer networks for use by vegetation during water demand periods. The strategy opens new avenues for atmospheric water-harvesting materials, which will hopefully solve the global crisis of freshwater shortages. [ABSTRACT FROM AUTHOR]

Published

2024

208. Feasibility Assessment and Environmental Benefits of Developing Rainwater Retention Ponds Across Najran Valley.

Author

Alyami, Saleh H., Jamil, Rehan, and Ghanim, Abdulnoor A.

Subjects

*WATER supply, *FLOOD risk, *WATER storage, *WATER shortages, *GROUNDWATER quality

Abstract

Water resources in arid and semi-arid regions are constrained by several critical problems, including scarcity of water resources and extensive use of groundwater. Climate change and population growth will certainly result in a decline in water tables and degradation of groundwater quality. The purpose of this study is to create rainwater retention ponds in the Najran Valley located at the southern border of Saudi Arabia. Over the past decade, various researchers have reported a sharp decrease in the availability of water in the area. In addition to urban sprawl, excessive groundwater extraction is the primary cause of the decrease. Even though the valley receives a sufficient amount of rainfall throughout the year, there is no adequate rainwater management system in place. As a result of this combined water management issue, the authorities are seeking additional water storage options in addition to the Najran dam reservoir. To evaluate the flood characteristics of the region, an extensive GIS-based hydrological study is conducted. To estimate flood volumes, the critical flood-prone areas are identified and their catchments are calculated. To store rainwater generated by these catchments during rainfall events, a variety of suitable locations have been proposed for retention ponds. The construction of retention ponds would have numerous environmental benefits in addition to solving the problem of water scarcity. As a result of the study, the authorities will be able to implement a management strategy that maximizes the use of the region's water resources. [ABSTRACT FROM AUTHOR]

Published

2024

209. Leaf gas exchange, water use, and yield of Marula (Sclerocarya birrea) and Kei Apple (Dovyalis caffra): South African indigenous fruit trees with domestication potential.

Author

Wilken, L.E., Kleinert, A., Schmeisser, M., and Dzikiti, S.

Subjects

*SOIL moisture, *WATER shortages, *WATER storage, *WATER use, *GROWING season

Abstract

• Marula transpiration is strongly driven by both climatic and soil water content variations. • Marula can buffer daily transpiration demands via large water storage capacity. • Kei Apple transpiration is predominantly driven by climatic factors. • Whole-tree transpiration can be accurately predicted using a simple Penman-Monteith model, albeit with different parameters for each species. Conventional crop production is expected to decline in the future in sub-Saharan Africa due to the rising costs of inputs, soil degradation, and increasing water scarcity related to climate variability and change. South Africa has more than 30 species of indigenous fruit trees that are adapted to grow under harsh conditions, yet these species are currently underutilized. Their cultivation is constrained by the lack of detailed ecophysiological information required to develop effective management strategies that optimize tree performance. In this study we investigated how two species with domestication potential namely Marula (Sclerocarya birrea) and Kei apple (Dovyalis caffra) responded to climate and soil factors over a period of two years (2019–2021). Photosynthesis, transpiration, and yield were quantified for mature trees growing in experimental orchards in the Mpumalanga Province of South Africa. Leaf gas exchange data were collected at selected intervals during the growing season using an infrared gas analyser while whole tree transpiration rates were quantified using the heat ratio method of monitoring sap flow. These data were used to parameterize a big leaf Penman-Monteith (PM) model to estimate the transpiration dynamics of individual trees at the daily time step. S. birrea's transpiration responded strongly to both climatic and soil water content variations while the water use of D. caffra was driven mostly by climatic factors. Transpiration rates averaged 0.30 L/m2 of leaf area for S. birrea while that of D. caffra was around 0.45 L/m2. Both species exhibited significant alternate bearing with yield of individual trees fluctuating by more than 50 % between successive years. For the 2019/20 season, water productivity (grams of fruit per litre of water transpired) varied between 6.2 and 17.4 g/L for S. birrea and between 24.3 and 41.7 g/L for D. caffra. Whole tree transpiration by both species were accurately predicted using the PM model albeit with different parameters for each species. This study demonstrates that a simple PM model can accurately estimate the water requirements of these species in other growing regions. [ABSTRACT FROM AUTHOR]

Published

2024

210. Vegetative Growth, Enzymatic Activities, Fruit Yield, and Quality of 'Balady' Mandarins (Citrus reticulata Blanco) in Response to Deficit Irrigation Levels.

Author

Salama, Abdel-Moety, Okba, Sameh, Ibrahim, Eman, and Aiad, Hamdya

Subjects

DEFICIT irrigation, MANDARIN orange, WATER shortages, VITAMIN C, FRUIT quality

Abstract

CITRUS is one of the most important fruit crops grown in the worldwide, especially in Mediterranean countries. Deficit irrigation (DI) is a proposed strategy many years ago to overcome the scarcity of water, especially in arid and semiarid regions. The vegetative growth, enzymatic activities, proline and phenolic content, fruit yield and quality in response to deficit irrigation levels (T1 (irrigation every 15 days as a control), T2 (irrigation every 20 days), T3 (irrigation every 25 days), and T4 (irrigation every 30 days), were evaluated. The results showed that the P, K, proline, phenols, vitamin C, SSC contents, and catalase and peroxidase activities were increased by T2 and T3. While the N content, fruit yield, weight, peel thickness, juice volume, and transpiration rate were increased by T1 and T2 compared to T3 and T4. The fruit yield, weight, and physical properties were not negatively affected by light and medium deficit irrigation (T2 and T3), which positively affected enzymatic activities, proline and phenol contents, and chemical fruit properties (SSC and Vitamin C). [ABSTRACT FROM AUTHOR]

Published

2024

211. The effect of irrigation practice and water consumption using aqua-crop.

Author

Teweldebrihan, M. D. and Dinka, M. O.

Subjects

IRRIGATION management, WATER efficiency, IRRIGATION water, WATER management, WATER shortages, DEFICIT irrigation

Abstract

BACKGROUND AND OBJECTIVES: The study explored the relationship between irrigation practices, water availability, and soil fertility in relation to crop yield. The investigation analyzed three distinct irrigation scenarios, namely full irrigation, deficit irrigation, and rain fed agriculture. The primary objective of the study was to evaluate the correlation between irrigation practices and soil fertility. To achieve this, the study incorporated different soil fertility levels, with high levels representing unlimited fertility for both full and deficit irrigation, and low levels corresponding to rain fed conditions. This design is primarily used to isolate the effects of irrigation practices on crop yields under a variety of fertility scenarios. The study also looks into how to achieve sustainable water management in the agricultural sector. METHODS: Aqua-crop, a computerized model, was utilized mimic real-life crop harvests. The aqua crop model was used to simulate crop yield in response to water availability. The calibration of the model involved utilizing data on various crop growth parameters, including soil fertility, crop canopy cover, evapotranspiration, soil water movement, crop yield and harvest index percentage. This innovative study utilizes aqua-crop to analyze the impact of irrigation methods on crop yields under controlled settings, effectively isolating irrigation influences from soil discrepancies. This approach is well-suited for studying sustainable water management strategies in agriculture, a pressing concern in light of worldwide water water scarcity. FINDINGS: Aqua-crop simulations revealed that consistent irrigation with a full irrigation system and high efficiency (70 percent) resulted in high yields. The simulated yields (8.48 to 10.04 tons per hectare) were significantly higher than farmers' actual yields (3.86 to 4.74 tons per hectare). Discrepancies between farmer irrigation methods and the model's assumption of uniform water application are the probable cause of the variation, underscoring the significance of considering real-world intricacies in the interpretation of model outcomes. The observed yield differences despite similar irrigation systems indicate the potential impact of unaccounted for factors such as soil type variations and real-world farmer practices (e.g., fertilization). Nevertheless, a substantial R-squared value of 0.85 suggests a robust association between simulated and observed yields, suggesting that aqua-crop can be valuable in comprehending overall irrigation-yield connections. Emphasis is placed on considering real-world complexities to achieve optimal crop yield. Aqua-crop simulations analyzed the correlation between irrigation and water use efficiency. Although full irrigation resulted in the highest simulated yields, deficit irrigation enhanced evapotranspiration water productivity. This seemingly contradictory finding can be explained by diminishing returns: deficit irrigation may result in slightly lower yields but higher water efficiency, highlighting the importance of considering both yield and water use efficiency when making long-term irrigation decisions. has highlighted the disparity between projected and actual crop yields, underscoring the significance of incorporating practical factors into the simulation of irrigation techniques. This finding holds particular relevance in areas where water resources are limited. CONCLUSION: The Food Agriculture Organization's aqua-crop is a useful tool for farmers who have limited access to water. Aqua-crop is a computer-based model that replicates the growth of crops in different irrigation scenarios. It provides farmers with the opportunity to explore the correlation between water usage and crop yield. By doing so, they can determine the most effective irrigation strategies that optimize harvest while minimizing water consumption. This aspect holds particular significance in regions facing water scarcity. [ABSTRACT FROM AUTHOR]

Published

2024

212. Modeling High Pan Evaporation Losses Using Support Vector Machine, Gaussian Processes, and Regression Tree Models.

Author

Alsumaiei, Abdullah A.

Subjects

SUPPORT vector machines, REGRESSION trees, GAUSSIAN processes, WATER shortages, HYDROLOGIC cycle

Abstract

Evaporation is considered to be one of the most influential hydrological processes, contributing significantly to water loss within the hydrological cycle. This study aimed to address the challenge of modeling daily pan evaporation in arid climates, where harsh hydroclimatic conditions hinder modeling efficacy. In such climates, annual pan evaporation rates exceed 3,500 mm, exacerbating water scarcity in agricultural basins. Three machine-learning techniques: regression trees, Gaussian processes, and support vector machine regression were employed to model daily pan evaporation rates at two meteorological stations in Kuwait. Various meteorological variables, including average diurnal temperature, average wind speed, and average relative humidity, were utilized to formulate different modeling scenarios. The three modeling methods demonstrated robust efficiency in simulating historical pan evaporation under varied input formulations. In addition, the data-driven models were shown to outperform physically and statistically based conventional evaporation modeling methods. The mean absolute error (MAE) and coefficient of determination (R2) ranged from 2.04 to 2.84 mm/day and 0.73–0.85, respectively. Notably, a bias in model predictions was observed for daily pan evaporation rates exceeding 25 mm/day. A probabilistic assessment of model skill for operational forecasts on a weekly time scale affirmed the suitability of the selected data-driven models for operational and water management decision-making. This study sought to equip water managers in arid regions with powerful tools to formulate resilient water strategies mitigating the detrimental effects of water scarcity. [ABSTRACT FROM AUTHOR]

Published

2024

213. Is "green" ammonia a misnomer? Unpacking the green label from a food-water-energy nexus perspective in water-scarce regions.

Author

Simha, Prithvi and van der Merwe, Gert

Subjects

CIRCULAR economy, WATER shortages, AMMONIA, ALKALIES, FERTILIZERS

Abstract

The term 'green ammonia' can be misleading. For fertilisers to merit a green label, the industry must adopt a planetary boundaries framework that includes reducing carbon emissions and circular management of nutrients. It should seek to achieve net reductions in reactive nitrogen and phosphorus fluxes to terrestrial and marine ecosystems. [ABSTRACT FROM AUTHOR]

Published

2024

214. Dynamic Variations of Agricultural Drought and Its Response to Meteorological Drought: A Drought Event‐Based Perspective.

Author

Wang, Fei, Lai, Hexin, Men, Ruyi, Wang, Zipeng, Li, Yanbin, Qu, Yanping, Feng, Kai, Guo, Wenxian, and Jiang, Yunzhong

Subjects

DROUGHT management, AGRICULTURE, WATER shortages, DROUGHTS, DROUGHT forecasting, VEGETATION dynamics, ENVIRONMENTAL quality, SPATIAL variation

Abstract

The dynamic variations of agricultural drought can reflect the water shortage situation of the agricultural system, and there is a progressive relationship in the response of agricultural drought to meteorological drought on a spatiotemporal scale. In this study, the vegetation health index and the standardized precipitation evapotranspiration index were adopted as agricultural and meteorological drought indicators, respectively. Additionally, using the three‐dimensional spatiotemporal clustering technology, the dynamic evolutions of typical drought events were clarified, and the spatiotemporal response characteristics of agricultural drought to meteorological drought were revealed. The results indicated that: (a) there were 81 agricultural drought events in the North China Plain (NCP) during 1982–2020, with a largest drought severity (12.82 × 104 month km2), a 6‐month duration, and a 23.24 × 104 km2 affected area occurring in the No. 4 event; (b) from the 1980s to the 2010s, the agricultural drought gradually decreased and large‐scale droughts mainly concentrated in the border areas of Hebei, Shandong, and Henan; and (c) a total of 13 drought event pairs were successfully matched in the NCP, including 7 pairs of "one‐to‐one," 4 pairs of "one‐to‐many," 1 pair of "many‐to‐one," and 1 pair of "many‐to‐many." The spatiotemporal responses of agricultural drought were elucidated in a three‐dimensional perspective, which can propose a new approach for establishing drought propagation model, predicting future agricultural drought conditions, improving ecological environment quality, and can also be applied for the investigation of other drought types. Plain Language Summary: There is a certain delay effect and time lag between agricultural drought and meteorological drought, thus, it is crucial to investigate the dynamic variation of agricultural drought and its response to meteorological drought to understand the impact of climate change on vegetation, which has important scientific significance and application value for improving ecological environment quality and restoring ecosystem functions. However, the dynamic variation of agricultural drought and its response to meteorological drought are still unclear from a three‐dimensional perspective. Based on the Center for Satellite Applications and Research and Famine Early Warning Systems Network Land Data Assimilation System data set, the vegetation health index and the standardized precipitation evapotranspiration index were adopted as agricultural and meteorological drought indicators, respectively. Additionally, using the three‐dimensional spatiotemporal clustering technology, the temporal variations and spatial patterns of drought were explored, the dynamic evolutions of typical drought events were clarified, and the spatiotemporal response characteristics of agricultural drought to meteorological drought were revealed from a three‐dimensional perspective. This study sheds new viewpoints into the identification of agricultural drought variation and its relationships with meteorological drought, which can also be applied in other areas. Key Points: There were 81 agricultural drought events in the North China Plain during 1982–2020The drought gradually decreased from the 1980s to the 2010sA total of 13 drought event pairs were successfully matched [ABSTRACT FROM AUTHOR]

Published

2024

215. Community assembly influences plant trait economic spectra and functional trade-offs at ecosystem scales.

Author

Anderegg, William R. L., Martinez-Vilalta, Jordi, Mencuccini, Maurizio, and Poyatos, Rafael

Subjects

*SOCIAL influence, *CLIMATE feedbacks, *ECOSYSTEM dynamics, *CARBON cycle, *ECOSYSTEMS, *PLANTATIONS, *WATER shortages

Abstract

Plant functional traits hold the potential to greatly improve the understanding and prediction of climate impacts on ecosystems and carbon cycle feedback to climate change. Traits are commonly used to place species along a global conservative-acquisitive trade-off, yet how and if functional traits and conservative-acquisitive trade-offs scale up to mediate community and ecosystem fluxes is largely unknown. Here, we combine functional trait datasets and multibiome datasets of forest water and carbon fluxes at the species, community, and ecosystem-levels to quantify the scaling of the tradeoff between maximum flux and sensitivity to vapor pressure deficit. We find a strong conservative-acquisitive trade-off at the species scale, which weakens modestly at the community scale and largely disappears at the ecosystem scale. Functional traits, particularly plant water transport (hydraulic) traits, are strongly associated with the key dimensions of the conservative-acquisitive trade-off at community and ecosystem scales, highlighting that trait composition appears to influence community and ecosystem flux dynamics. Our findings provide a foundation for improving carbon cycle models by revealing i) that plant hydraulic traits are most strongly associated with community-and ecosystem scale flux dynamics and ii) community assembly dynamics likely need to be considered explicitly, as they give rise to ecosystem-level flux dynamics that differ substantially from trade-offs identified at the species-level. [ABSTRACT FROM AUTHOR]

Published

2024

216. Mitigation of drought-induced stress in sunflower (Helianthus annuus L.) via foliar application of Jasmonic acid through the augmentation of growth, physiological, and biochemical attributes.

Author

Ashraf, Farkhanda and Siddiqi, Ejaz Hussain

Subjects

*JASMONIC acid, *COMMON sunflower, *DROUGHT management, *SUNFLOWERS, *HYDROGEN peroxide, *WATER shortages, *BETAINE, *PLANT regulators

Abstract

Drought stress poses a significant threat to agricultural productivity, especially in areas susceptible to water scarcity. Sunflower (Helianthus annuus L.) is a widely cultivated oilseed crop with considerable potential globally. Jasmonic acid, a plant growth regulator, plays a crucial role in alleviating the adverse impacts of drought stress on the morphological, biochemical, and physiological characteristics of crops. Experimental detail includes sunflower varieties (Armani Gold, KQS-HSF-1, Parsun, and ESFH-3391), four drought stress levels (0, 25%, 50%, and 75% drought stress), and three levels (0, 40ppm, 80ppm) of jasmonic acid. The 0% drought stress and 0ppm jasmonic acid were considered as control treatments. The experimental design was a completely randomized design with three replicates. Drought stress significantly reduced the growth in all varieties. However, the exogenous application of jasmonic acid at concentrations of 40ppm and 80ppm enhanced growth parameters, shoot and root length (1.93%, 19%), shoot and root fresh weight (18.5%, 25%), chlorophyll content (36%), photosynthetic rate (22%), transpiration rate (40%), WUE (20%), MDA (6.5%), Phenolics (19%), hydrogen peroxide (7%) proline (28%) and glycine betaine (15–30%) under water-stressed conditions, which was closely linked to the increase in stomatal activity stimulated by jasmonic acid. Furthermore, JA 80 ppm was found to be the most appropriate dose to reduce the effect of water stress in all sunflower varieties. It was concluded that the foliar application of JA has the potential to enhance drought tolerance by improving the morphological, biochemical, and physiological of sunflower. [ABSTRACT FROM AUTHOR]

Published

2024

217. Applying recession models for low-flow prediction: a comparison of regression and matching strip approaches.

Author

Margreth, Michael, Lustenberger, Florian, Peter, Dorothea Hug, Schlunegger, Fritz, and Zappa, Massimiliano

Subjects

RECESSIONS, PREDICTION models, HAZARD mitigation, WATER shortages, RAMS

Abstract

Low flows in the Swiss Plateau are expected to occur more often, to last longer and, hence, to be more severe under climate change. To predict and manage such periods of water scarcity effectively, more precise information on the drainage behavior of catchments is required. The drainage behavior of a catchment can be characterized by recession analysis methods (RAMs; e.g., recession curves) of which several have been developed in the last decades. Their recession parameters have been related to different aquifer characteristics or more general catchment characteristics like lithology, topography, or climatology. Such parameters vary widely, and the effects of uncertainties on the model's outcomes are diverse and complex. Despite the obvious potential of recession curves for prediction, they have so far not been used for operational low flow prediction and guidance for hazard mitigation. In addition, recession curves of slowly draining catchment states are hardly represented by current RAMs. To fill the gap of RAMs representing slow draining catchment states we developed two novel RAMs, one fully automated and based on the matching strip method (MRC_slow), the other one (SDSC) relying on a careful expert-based selection of few recession segments with the slowest recession behavior. Alongside we used three established RAMs from the literature (one further matching strip model, linear regression and lower envelope in the discharge decay – discharge recession diagram). We applied the five RAMs on previously extracted low flow segments of 33 catchments in the Swiss Plateau and compared them on their recession curvatures, durations, and volumes. We designed a procedure that evaluates which of any selected RAMs best matches the recession behavior of individual low flow segments of a hydrograph. Applying this in a simulated prediction situation, we evaluated in retrospect, which of the five specifically selected RAMs predicted the low flow hydrographs between 2021 and 2022 most accurately. We found the variability of recession durations and volumes between catchments to be higher than between the five RAMs. Within 30 of the 33 catchments, the order of recession durations and recession volumes was the same. Hence the different recession behaviors of the RAMs could be related to different catchment states. Upon evaluating the low flow predictions, we found that the MRC_slow approach overall performed best followed by linear regression and SDSC. However, for operational low flow prediction we recommend using four of the five RAMs. This allows for changing the recession model(s) at every timestep if the recession behavior changes. It is also possible to present predictions with a model ensemble, indicating a range of uncertainties if several models perform similarly well. The described data-driven approach and the newly developed models are, therefore, very promising for improving low flow predictions in gauged catchments. [ABSTRACT FROM AUTHOR]

Published

2024

218. The institutionalization of the Kura-Aras River Basin for effective management of water resources.

Author

Suleymanov, Firuz

Subjects

*WATER management, *WATERSHEDS, *WATER shortages

Abstract

Water scarcity in the region underscores the urgent need for effective management of the Kura-Aras River Basin, emphasizing the critical role it plays in ensuring sustainable water access and security for all riparian states. The research on the institutionalization of the Kura-Aras River Basin holds significant importance in advancing academic understanding and informing policy decisions regarding effective water resource management in transboundary river basins. During a semi-structured interview with field experts from riparian states, the consensus highlighted the significance of institutionalizing the Kura-Aras River Basin for effective water resource management. Field experts from basin countries highlighted the importance of establishing robust governance mechanisms as a strength, fostering cooperation, enhancing transparency, and mitigating conflicts among riparian states in the region. In contrast, the lack of trust between riparian states emerged as a significant weakness, exacerbating the deprivation of the Kura-Aras River Basin and contributing to underdevelopment. [ABSTRACT FROM AUTHOR]

Published

2024

219. Optimal water tariffs for domestic, agricultural and industrial use.

Author

Caravaggio, Andrea, De Cesare, Luigi, and Di Liddo, Andrea

Subjects

*AGRICULTURE, *CONSUMER protection, *DIFFERENTIAL games, *PRICES, *WATER use, *WATER shortages, *TARIFF

Abstract

Consider a water supplier who determines sales rates with the goals of maximizing profits, protecting consumer welfare, and ensuring adequate future water supplies. Buyers are differentiated and can use the water for domestic, agricultural, and industrial purposes. We propose a leader-follower finite-horizon differential game. The leader (the water supplier) determines the selling price and the followers (consumers) react by requesting their optimal amount of water. We calculate a feedback Stackelberg equilibrium assuming that all user demand is satisfied (interior equilibrium). We compare two different tariff schemes: linear tariffs (the price paid is a multiple of the volume of water purchased), and increasing block tariffs (the unit price is lower for quantities of water that do not exceed a fixed threshold). We show that block pricing is never optimal and linear pricing is always preferred. [ABSTRACT FROM AUTHOR]

Published

2024

220. Tree-Inspired Structurally Graded Aerogel with Synergistic Water, Salt, and Thermal Transport for High-Salinity Solar-Powered Evaporation.

Author

Zhao, Xiaomeng, Zhang, Heng, Chan, Kit-Ying, Huang, Xinyue, Yang, Yunfei, and Shen, Xi

Subjects

*AEROGELS, *SALT crystals, *HEAT radiation & absorption, *SALT, *WATER shortages

Abstract

Highlights: Inspired by transport system in trees, a two-way water and salt transport mechanism is realized in a structurally graded aerogel, enabling simultaneous fast water uptake and salt rejection. The horizontally aligned pore channels near the surface achieve excellent heat localization by maximizing solar absorption and minimizing heat loss. The integrated water, salt, and thermal transports impart an impressive evaporation rate of 1.94 kg m−2 h−1 in a 20 wt% NaCl solution for 8 h without salt accumulation. Solar-powered interfacial evaporation is an energy-efficient solution for water scarcity. It requires solar absorbers to facilitate upward water transport and limit the heat to the surface for efficient evaporation. Furthermore, downward salt ion transport is also desired to prevent salt accumulation. However, achieving simultaneously fast water uptake, downward salt transport, and heat localization is challenging due to highly coupled water, mass, and thermal transport. Here, we develop a structurally graded aerogel inspired by tree transport systems to collectively optimize water, salt, and thermal transport. The arched aerogel features root-like, fan-shaped microchannels for rapid water uptake and downward salt diffusion, and horizontally aligned pores near the surface for heat localization through maximizing solar absorption and minimizing conductive heat loss. These structural characteristics gave rise to consistent evaporation rates of 2.09 kg m−2 h−1 under one-sun illumination in a 3.5 wt% NaCl solution for 7 days without degradation. Even in a high-salinity solution of 20 wt% NaCl, the evaporation rates maintained stable at 1.94 kg m−2 h−1 for 8 h without salt crystal formation. This work offers a novel microstructural design to address the complex interplay of water, salt, and thermal transport. [ABSTRACT FROM AUTHOR]

Published

2024

221. Multi-criteria analysis for sustainable and cost-effective development of desalination plants in Chile.

Author

Sola, Iván, Zarzo, Domingo, Sánchez-Lizaso, José Luis, and Sáez, Claudio A.

Subjects

SALINE water conversion, PLANT development, GEOGRAPHIC information systems, SUSTAINABLE development, REVERSE osmosis, WATER shortages, GREENHOUSES

Abstract

In Chile, there is an increasing demand for freshwater supply for human consumption, agriculture, and industrial activities. In this sense, the country is highly threatened by climate change, which is drastically affecting the availability of water resources in the north-central region due to desertification processes. Therefore, seawater reverse osmosis (SWRO) desalination is becoming one of the most feasible alternatives to address current and future challenges regarding water scarcity in the country. This investigation aims to evaluate potential locations for a sustainable and cost-effective installation of desalination projects; the latter, under a multi-criteria and geographic information system (GIS)-model. The model was tested in the highly water scarcity-threatened Valparaiso Region, Chile, as a case study. The model was developed integrating economic and socio-environmental criteria involved in the development and/or construction of desalination projects. The results of the multi-criteria analysis show that the Valparaıso Region presents optimal areas for developing SWRO projects. Both the northern and central areas of the Region show appropriate locations for installing SWRO plants and their freshwater distribution lines, ensuring short- and long-term water supply, especially for agriculture and population consumption. The results obtained in this study could be extrapolated as a tool to assess the desalination projects development in other world regions to make future desalination projects more viable and sustainable for addressing global water demands. [ABSTRACT FROM AUTHOR]

Published

2024

222. Design and fabrication of porous three‐dimensional Ag-doped reduced graphene oxide (3D Ag@rGO) composite for interfacial solar desalination.

Author

Bezza, Fisseha A., Iwarere, Samuel A., Brink, Hendrik G., and Chirwa, Evans M. N.

Subjects

*DOPING agents (Chemistry), *PHOTOTHERMAL conversion, *SALINE waters, *THERMAL conductivity, *WATER shortages, *HEAT pipes, *GRAPHENE oxide

Abstract

Solar-driven interfacial desalination technology has shown great promise in tackling the urgent global water scarcity crisis due to its ability to localize heat and its high solar-to-thermal energy conversion efficiency. For the realization of sustainable saline water desalination, the exploration of novel photothermal materials with higher water vapor generation and photothermal conversion efficiency is indispensable. In the current study, a novel 3D interconnected monolithic Ag-doped rGO network was synthesized for efficient photothermal application. The Ultraviolet–Visible-Near Infrared (UV–Vis-NIR) and FTIR analyses demonstrated that the controlled hydrothermal reduction of GO enabled the restoration of the conjugated sp2 bonded carbon network and the subsequent electrical and thermal conductivity through a significant reduction of oxygen-containing functional groups while maintaining the hydrophilicity of the composite photothermal material. In the solar simulated interfacial desalination study conducted using 3.5 wt.% saline water, the average surface temperatures of the 3D material increased from 27.1 to 54.7 °C in an hour, achieving an average net dark-excluded evaporation rate of 1.40 kg m−2 h−1 and a photothermal conversion efficiency of ~ 97.54% under 1 sun solar irradiance. In the outdoor real-world application test carried out, the surface temperature of the 3D solar evaporator reached up to 60 °C and achieved a net water evaporation rate of 1.50 kg m−2 h−1 under actual solar irradiation. The 3D interwoven porous hierarchical evaporator displayed no salt precipitation over the 54-h period monitored, demonstrating the promising salt rejection and real-world application potential for efficient desalination of saline water. [ABSTRACT FROM AUTHOR]

Published

2024

223. Validation of Gross Primary Production Estimated by Remote Sensing for the Ecosystems of Doñana National Park through Improvements in Light Use Efficiency Estimation.

Author

Gómez-Giráldez, Pedro J., Cristóbal, Jordi, Nieto, Héctor, García-Díaz, Diego, and Díaz-Delgado, Ricardo

Subjects

*PHOTOSYNTHETICALLY active radiation (PAR), *REMOTE sensing, *NATIONAL parks & reserves, *WATER shortages, *SOLAR radiation, *SALT marshes, *ECOSYSTEMS

Abstract

Doñana National Park is located in the southwest of the Iberian Peninsula, where water scarcity is recurrent, together with a high heterogeneity in species and ecosystems. Monitoring carbon assimilation is essential to improve knowledge of global change in natural vegetation cover. In this work, a light use efficiency (LUE) model was applied to estimate gross primary production (GPP) in two ecosystems of Doñana, xeric shrub (drought resistant) and seasonal marsh (with grasslands dependent on water hydroperiod) and validated with in situ data from eddy covariance (EC) towers installed in both ecosystems. The model was applied in two ways: (1) using the fraction of absorbed photosynthetically active radiation (FAPAR) from Sentinel-2 and meteorological data from reanalysis (ERA5), and (2) using Sentinel-2 FAPAR, reanalysis solar radiation (ERA5) and the Sentinel-2 land surface water index (LSWI). In both cases and for both ecosystems, the error values are acceptable (below 1 gC/m2) and in both ecosystems the model using the LSWI gave better results (R2 of 0.8 in marshes and 0.51 in xeric shrubs). The results also show a greater influence of the water status of the system than of the meteorological variables in this area. [ABSTRACT FROM AUTHOR]

Published

2024

224. Unveiling novel APLIS model for identifying groundwater recharge zones in semi-arid regions: A case from Lebanon.

Author

Tadmouri, Rida, Shaban, Amin, Baghdady, Khaled, and Soliman, Mohamed R.

Subjects

ARID regions, GROUNDWATER recharge, AQUIFERS, WATER shortages, AGRICULTURAL productivity, AGRICULTURE, GROUNDWATER flow, SOIL infiltration

Abstract

The Bekaa Plain in Lebanon, is a major agricultural region known for its fertile soil and extensive crops cultivation using groundwater resources which is recently became under stress due to population growth, urbanization, and climate change. The main aim of this study is to investigate the rate of groundwater recharge (GwR) into this region using APLIS Model which principally depends on altitude, slope, lithology, infiltration, and soil type. Using GIS-based for a multicriteria mapping approach, in this study additional factors were added to the model, by incorporating rainfall rates, stream density, and fracture density. Results revealed various recharge potential area in the Bekaa Plain, with 52 % classified as high to very high GwR zones, equivalent to approximately 42.5 % of precipitated water, which is a testament to the exceptional capacity of the region to replenish groundwater aquifers. The geographic distribution of GwR categories primarily depends on altitude and lithological characteristics. The exceptional GwR potential of the Bekaa Plain holds immense promise for mitigating water scarcity, fostering agricultural productivity, and ensuring the socioeconomic well-being of communities reliant on groundwater resources. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

225. MONITORING STRATEGIES FOR WATER PROTECTION IN INDUSTRIAL CONTEXTS.

Author

Kuliqi, Florim

Subjects

WATER supply, WATER shortages, WATER pollution, CLIMATE change, HAZARDOUS substances

Abstract

Despite the Earth's abundant water resources, potable water scarcity persists due to pollution from multiple sources. The escalating demand for water across households, agriculture, industry, and other sectors, compounded by economic growth and population expansion, forecasts a worsening situation. Climate change further exacerbates these challenges, heightening concerns over water pollution and scarcity. Water, fundamental to the sustenance of diverse life forms on Earth, underpins all biological processes. Water pollution, characterized by changes in physical, chemical, and microbiological properties resulting from hazardous substances, poses significant threats to the quality and hygiene of drinking water and its suitability for various applications. Efforts to safeguard water resources necessitate ongoing vigilance and strategic management informed by legal frameworks and contemporary understanding. Mitigating water pollution requires a multifaceted approach encompassing monitoring, addressing root causes, pollutant reduction, purification, conservation, and robust regulatory mechanisms. [ABSTRACT FROM AUTHOR]

Published

2024

226. CaRDS - the statewide California Residential water Demand and Supply open dataset.

Author

Gross, Marie-Philine, Escriva-Bou, Alvar, Porse, Erik, and Cominola, Andrea

Subjects

WATER supply, WATER demand management, ENERGY demand management, WATER conservation, WATER shortages, WATER security, SUPPLY & demand

Abstract

As water scarcity becomes the new norm in the Western United States, states such as California have increased their efforts to improve water resilience. Achieving water security under climate change, population growth, and urbanization requires an integrated multi-sectoral approach, where adaptation strategies combine supply and demand management interventions. Yet, most studies consider supply-side and demand-side management strategies separately. Water conservation efforts are mainly driven by policy requirements and publicly available data to assess the effectiveness of demand- and supply-side management policies is often hard to find and unstructured. Here we present CaRDS - the statewide California Residential water Demand and Supply open dataset. CaRDS encompasses nine years (2013-2021) of monthly water supply and demand time series for 404 water suppliers in California, USA, compiled from different open-access data sources. Access to detailed temporal and spatial water supply operations and demands at the state-level can be useful to researchers and practitioners to realize applications such as evaluating the effectiveness of water conservation policies and discovering regional differences in water resilience measures. [ABSTRACT FROM AUTHOR]

Published

2024

227. Drought Resilience in Oil Palm Cultivars: A Multidimensional Analysis of Diagnostic Variables.

Author

Bayona-Rodríguez, Cristihian and Romero, Hernán Mauricio

Subjects

CULTIVARS, OIL palm, GLUTATHIONE reductase, WATER efficiency, CATALASE, PALMS, WATER shortages, PRINCIPAL components analysis, CHLOROPHYLL spectra

Abstract

Water scarcity is a significant constraint on agricultural practices, particularly in Colombia, where numerous palm cultivators rely on rainfed systems for their plantations. Identifying drought-tolerant cultivars becomes pivotal to mitigating the detrimental impacts of water stress on growth and productivity. This study scrutinizes the variability in drought responses of growth, physiological, and biochemical variables integral to selecting drought-tolerant oil palm cultivars in the nursery. A comprehensive dataset was compiled by subjecting seedlings of eleven cultivars to four soil water potentials (−0.05 MPa, −0.5 MPa, −1 MPa, and −2 MPa) over 60 days. This dataset encompasses growth attributes, photosynthetic parameters like maximum quantum yield and electron transfer rate, gas exchange (photosynthesis, transpiration, and water use efficiency), levels of osmolytes (proline and sugars), abscisic acid (ABA) content, as well as antioxidant-related enzymes, including peroxidase, catalase, ascorbate peroxidase, glutathione reductase, and superoxide dismutase. Principal Component Analysis (PCA) elucidated two principal components that account for approximately 65% of the cumulative variance. Noteworthy enzyme activity was detected for glutathione reductase and ascorbate peroxidase. When juxtaposed with the other evaluated cultivars, one of the cultivars (IRHO 7001) exhibited the most robust response to water deficit. The six characteristics evaluated (photosynthesis, predawn water potential, proline, transpiration, catalase activity, sugars) were determined to be the most discriminant when selecting palm oil cultivars with tolerance to water deficit. [ABSTRACT FROM AUTHOR]

Published

2024

228. Impact Assessment of Climate Change on Water Supply to Hsinchu Science Park in Taiwan.

Author

Lee, Tsung-Yu, Lai, Yun-Pan, Teng, Tse-Yang, and Chiu, Chi-Cheng

Subjects

WATER supply, RESEARCH parks, WATER shortages, CLIMATE change, SEMICONDUCTOR manufacturing, WATER storage, RAINFALL, TYPHOONS

Abstract

The Hsinchu Science Park (HSP) in Taiwan plays a vital role in the chain of semiconductor production, but water scarcity has been challenging semiconductor manufacturing. The Baoshan Reservoir (BS) and the Baoshan Second Reservoir (BSR) are two major sources of water supply to the HSP. However, the impacts of climate change on the water supply have not been analyzed. In this study, a hydrological model (i.e., SWAT) and an operation model of the BR and the BSR were coupled to assess the climate change impacts on the inflow, outflow, and water storage volume (WSV) of the reservoirs. The simulations were based on the weather data for the RCP2.6, RCP4.5, RCP6.0, and RCP8.5 scenarios of AR5 for the Periods of 2021–2040, 2041–2060, 2061–2060, and 2081–2100 derived from up to 33 GCMs/EMSs. It is found that more intensified global warming would generally result in more apparent rainfall seasonality that is wetter in the wet season and dryer in the dry season and more magnified seasonality in river flow. During the hotspot period of water shortage in the HSP from February to May, future water scarcity is expected to worsen. Among the 16 combinations of scenarios and Periods, 13 indicate lower WSV in the future compared to the Baseline. The annual mean number of ten-day periods with WSV lower than the operation rule curve ranges from 4.84 to 6.95 ten-day periods, higher than the Baseline of 4.81 ten-day periods. Overall, RCP6.0 has the most significant impact on the study area, with the highest annual economic loss occurring during the 2041-2060 period, reaching USD 1 billion (~2.37% of the 2023 annual production value) for the HSP. This study also provides a three-month cumulative rainfall threshold as an operational warning indicator for the HSP. Our assessment results indicate that future water supply to the HSP should be a serious concern for stabilizing the manufacturing processes and hence the global semiconductor component supply. [ABSTRACT FROM AUTHOR]

Published

2024

229. Carbon Emission Reduction of Reclaimed Water Use Substitution for Inter-Basin Water Transfer and Sustainability of Urban Water Supply in Valley Area.

Author

Ma, Nian and Xu, Yongxin

Subjects

MUNICIPAL water supply, CARBON emissions, SUSTAINABLE urban development, WATER use, WATER transfer, WATER shortages, ENVIRONMENTAL risk

Abstract

Urbanization confronts the dual challenges of water scarcity and environmental degradation, prompting the exploration of diverse water sources for mitigating these impacts. Inter-basin water transfer (IBWT) has emerged as a solution to balance urban water demand and supply in areas with local water shortages. While IBWT can deliver high-quality water over long distances, it is costly, often contributing significantly to carbon emissions. Reclaimed water use (RWU) presents a promising alternative to address this dilemma. In this paper, a valley region of Chongqing municipality in Southwest China, which is confronted with water and environmental risks resulting from rapid urbanization, was explored and discussed as a case study to assess the potential impact of RWU on reducing carbon emissions as compared to IBWT. A method of accumulative accounting was adapted to calculate and sum up carbon emission intensities at various stages, revealing that the operational carbon emission intensities of IBWT and RWU are 0.7447 KgCO2/m3 and 0.1880 KgCO2/m3, respectively. This indicates that RWU substitution can reduce carbon emissions by 0.5567 KgCO2/m3 or 75%. This paper further elucidates the mechanism behind carbon emission reduction, highlighting the energy-saving benefits of using reclaimed water locally without recourse to extensive transportation or elevation changes. Additionally, this result presents three scenarios of reclaimed water use, including urban miscellaneous water, river flow replenishment, and agricultural irrigation in relation to their substitution effects and environmental impacts. Estimates of carbon emission reductions from reclaimed water use were projected at the planned scale, with the maximum potential of reclaimed water utilization predicted. Finally, this paper proposes an enhanced strategy to identify and prioritize factors affecting reclaimed water utilization and the effect of carbon emission reduction. This paper aims to facilitate the establishment of a robust legal, institutional, and managerial framework while fostering interdisciplinary and cross-sectoral cooperation mechanisms in valley urban areas. The methodology employed can be universally applied to other regions grappling with severe water stress, thereby facilitating endeavors toward carbon reduction and contributing significantly to the attainment of water sustainability. [ABSTRACT FROM AUTHOR]

Published

2024

230. The Improved Water Resource Stress Index (WRSI) Model in Humid Regions.

Author

Yang, Yuxin, Yan, Feng, and Wu, Hongliang

Subjects

WATER management, WATER shortages, WATER supply, WATER use, PLANT anatomy, RAINFALL

Abstract

Water scarcity is commonly evaluated using the water resource stress index (WRSI). However, the conventional WRSI model cannot effectively reflect the water shortage in humid areas, which may lead to distorted evaluation results. To solve this problem, an improved WRSI has been designed. In the improved WRSI, the assessment year is first divided into multiple periods. Then, the temporal WRSI (T-WRSI) is built to evaluate water scarcity in each period. Finally, the comprehensive WRSI (C-WRSI) is constructed based on the entropy weight model (EWM) to synthetically assess the water shortage condition. The water scarcity of Yongzhou City is taken as a sample for evaluation. The results are as follows. (i) The Lingling-Lengshuitan District and Dong'an County suffer from the most serious water shortage. Their C-WRSI values are 0.464 and 0.458, respectively, both of which are "high" grades. (ii) The values of T-WRSI are more than 0.4 from August to October in most areas, indicating that the major key water shortage period is from August to October. (iii) The reasons for water shortage are that the annual runoff distribution in Yongzhou City is uneven with a uniformity coefficient (Cv) of 0.83, and the main irrigation periods are coincidentally accompanied by the retreat of rainfall. (iv) The main measures to solve water scarcity are to strengthen water resource management, to optimize plant structure, and to construct more reservoirs. (v) The C-WRSI values calculated by the improved model in each region are 95–168% larger than those of conventional WRSI. The improved WRSI has better capacities in evaluating the water shortage induced by uneven runoff within the year and identifying the key water scarcity period of humid regions. [ABSTRACT FROM AUTHOR]

Published

2024

231. Water Use in Livestock Agri-Food Systems and Its Contribution to Local Water Scarcity: A Spatially Distributed Global Analysis †.

Author

Wisser, Dominik, Grogan, Danielle S., Lanzoni, Lydia, Tempio, Giuseppe, Cinardi, Giuseppina, Prusevich, Alex, and Glidden, Stanley

Subjects

WATER shortages, WATER use, WATER requirements for crops, SERVICE animals, WATER withdrawals, LIVESTOCK

Abstract

There is a growing concern about limited water supply and water scarcity in many river basins across the world. The agricultural sector is the largest user of freshwater on the planet, with a growing amount of water extracted for livestock systems. Here, we use data from the GLEAM model to advance previous studies that estimated livestock water footprints by quantifying water use for feed production, animal drinking water, and animal service water. We additionally account for the role of trade in accounting for feed water allocations to different animals in different countries and make use of a hydrologic model to estimate feed irrigation water requirements for individual crops at a high spatial resolution. Lastly, we estimate the contribution of livestock water abstractions to water stress at a small river basin scale for the entire globe. We find that feed production water accounts for the majority (>90%) of global livestock water withdrawals, though there is regional variation. Similarly, we find large regional variation in the water consumption per head by livestock species. Despite consuming >200 km3 of water per year, we find that reducing water use in the livestock system alone will rarely reduce water stress in high-stress basins. This study highlights the need for quantifying locally relevant water use and water stress metrics for individual livestock systems. [ABSTRACT FROM AUTHOR]

Published

2024

232. Can the Interfacial Solar Vapor Generation Performance Be Really "Beyond" Theoretical Limit?

Author

Nawaz, Fahad, Yang, Yawei, Zhao, Qi, Mo, Yalu, Jiang, Zhuohang, Wu, Jinghe, Liu, Yihong, Liu, Bowen, Gao, Bowen, and Que, Wenxiu

Subjects

*HEATS of vaporization, *VAPORS, *WATER purification, *ENERGY dissipation, *ENERGY consumption, *WATER shortages, *RESEARCH personnel

Abstract

The interfacial solar vapor generation (ISVG) process is an environmentally friendly approach that utilizes solar to produce steam, which can solve the water shortage. Despite many previous research studies, claims beyond the theoretical limit have risen due to limitations in the efficiency of converting solar to vapor and the rate of solar evaporation, which are still being debated. Energy losses remain even under ideal conditions, which means that the efficiency of the system will never be ≥100%. This review primarily analyzes the theoretical values of evaporation rate and energy efficiency in the ISVG process. Utilizing a theoretical formula for energy distribution, the factors contributing to the current exceedance of conversion efficiency and evaporation rate are scrutinized. By examining various strategies, such as the reduction of vaporization enthalpy for photothermal materials and the utilization of environmental energy for evaporation, these studies seek to enhance evaporation efficiencies, but they ignore the problem of the theoretical limit of evaporation. Therefore, this review emphasizes misconceptions about efficiencies beyond theoretical limits and aims to guide researchers to provide plausible explanations for such breakthroughs under specific conditions, alongside established reference conditions. Ultimately, this study lays a solid theoretical foundation for practical solar water purification. [ABSTRACT FROM AUTHOR]

Published

2024

233. The impact of information provision on public willingness to use recycled water for flushing from the perspective of risk perception.

Author

Yizhe Ding and Xiaojun Liu

Subjects

RISK perception, WATER use, PUBLIC spending, PUBLIC opinion, TRUST, WATER currents, WATER shortages

Abstract

To solve the current urban water shortage, increasing the willingness of urban residents to use recycled water for flushing is one proposed approach. This study developed a risk perception measurement model of recycled water for toilet flushing to explore which risk triggered people's risk perception of recycled water, and then analyzed the interaction among information provision, trust, risk perception, and willingness to use recycled water. The main results were as follows. First, the risk perception of recycled water for flushing mainly come from four types of risks, which were performance risk, health risk, service risk and financial risk in order of importance. Second, reducing the perceived risk can improve public willingness to use recycled water for flushing, and greater trust in the water authorities and recycled water enterprises reduces the public's perception of the risk of recycled water. A higher level of initial trust is related to higher willingness to use recycled water. Third, information provision can enhance the risk perception of recycled water and enhance trust in the water authorities and recycled water enterprises, but information provision does not directly affect the willingness to use recycled water. This indicates that reducing performance risk and health risk of recycled water, will be the key to controlling the overall risk perception of recycled water and promoting willingness to use. Effective risk communication strategies combine information provision and trust in information providers, which together affect risk perception and thus the willingness to use recycled water. [ABSTRACT FROM AUTHOR]

Published

2024

234. Rhizobacterial inoculation to improve the responses of olive cultivars to drought stress.

Author

Boussadia, Olfa, Omri, Amal, Sayari, Marwa, and Ben Khedher, Saoussen

Subjects

CULTIVARS, DROUGHTS, WATER shortages, VACCINATION, DROUGHT management, OLIVE, WATER supply

Abstract

Tunisia is known as an underprivileged country in water resources, and water scarcity is evident in certain regions. In the long term, this situation could become more exacerbated, considering the increased risk of aridity. In this context, this work was carried out to study and compare the ecophysiological behavior of five olive cultivars facing drought stress and to evaluate the contribution of rhizobacteria to mitigate the effects of drought stress on these cultivars. The results showed a significant decrease in the relative water content (RWC) with the lowest percentage recorded for the 'Jarboui' cultivar (RWC = 37%), and the highest percentage was registered for the 'Chemcheli' cultivar (RWC = 71%). In addition, the performance index (PI) decreased for all the five cultivars and it reached the lowest values for 'Jarboui' and 'Chetoui' with 1.51 and 1.57, respectively. For the SPAD index, a decrease was registered for all the cultivars, except 'Chemcheli' (SPAD index = 89). Furthermore, the bacterial inoculation treatment improved the responses of cultivars to water stress. In fact, for all of the studied parameters, it was found that rhizobacterial inoculation significantly attenuated the effects of drought stress with variability dependent on the level of tolerance of the tested cultivars. This response improvement was noted especially in susceptible cultivars like 'Chetoui' and 'Jarboui'. [ABSTRACT FROM AUTHOR]

Published

2024

235. Structure‐Property Relationships of Hydrogel‐based Atmospheric Water Harvesting Systems.

Author

Feng, An, Shi, Yihan, Onggowarsito, Casey, Zhang, Xin Stella, Mao, Shudi, Johir, Muhammed A.H., Fu, Qiang, and Nghiem, Long D.

Subjects

WATER harvesting, WATER supply, ELECTRIC potential, WATER shortages, ARID regions, HYDROGELS

Abstract

Atmospheric water harvesting (AWH) is considered one of the promising technologies to alleviate the uneven‐distribution of water resources and water scarcity in arid regions of the world. Hydrogel‐based AWH materials are currently attracting increasing attention due to their low cost, high energy efficiency and simple preparation. However, there is a knowledge gap in the screening of hydrogel‐based AWH materials in terms of structure‐property relationships, which may increase the cost of trial and error in research and fabrication. In this study, we synthesised a variety of hydrogel‐based AWH materials, characterized their physochemcial properties visualized the electrostatic potential of polymer chains, and ultimately established the structure‐property‐application relationships of polymeric AWH materials. Poly(2‐acrylamido‐2‐methyl‐1‐propanesulfonic acid) (PAMPS) hydrogel is able to achieve an excellent water adsorption capacity of 0.62 g g−1 and a high water desorption efficiency of more than 90 % in relatively low‐moderate humidity environments, which is regarded as one of the polymer materials with potential for future AWH applications. [ABSTRACT FROM AUTHOR]

Published

2024

236. Can "sponge city" pilots enhance ecological livability: Evidence from China.

Author

Wang, Qi, Wang, Qinmei, and Wang, Xi

Subjects

*CITIES & towns, *HUMAN settlements, *WATER shortages, *ECOSYSTEMS, *PANEL analysis, *WATER supply

Abstract

The challenges posed by environmental pollution, water scarcity, and energy limitations resulting from industrialization and modernization pose significant threats to human habitats. Consequently, assessing ecological livability and delineating pathways for improvement carry considerable practical importance. Leveraging panel data encompassing 288 cities in China from 2010 to 2021, this study establishes an evaluation system for ecological livability, encompassing three dimensions: natural greenery level, residential comfort level, and environmental governance level. Subsequently, the study measures the ecological livability level and investigates the impact of "sponge city" pilots on ecological livability and their underlying mechanisms using a multi-period difference-in-differences model. Our findings underscore the substantial role of "sponge city" pilot projects in bolstering ecological livability, with robustness observed across various models and specifications. Specifically, human capital concentration and green technology innovation emerge as pivotal pathways through which "sponge city" pilots augment ecological livability. Moreover, the effectiveness of "sponge city" pilots varies across regions due to disparities in drought severity and water supply, with more pronounced effects observed in arid areas and cities facing water supply shortages. This research furnishes comprehensive theoretical and empirical underpinnings for comprehending the influence of "sponge city" pilots on ecological livability, offering valuable insights and recommendations to inform future efforts aimed at enhancing ecological livability and fostering sustainable development. [ABSTRACT FROM AUTHOR]

Published

2024

237. Strategic water resource management: pump stations in Fayoum City, Egypt.

Author

Kotb, Sultan, Li Cheng, Amin, Mohamed, Elzoghby, Mohamed Monir, and Nasr, Ahmed

Subjects

WATER supply management, WATER shortages, WATER pumps, ANALYTIC hierarchy process, WATER reuse

Abstract

Water scarcity presents significant challenges to sustainable development, particularly in arid regions like Fayoum City, Egypt, which faces particular water challenges due to its unique topography. This study explores the pivotal role of pump stations and wastewater reuse in mitigating water scarcity and promoting sustainable water management practices. Utilizing a comprehensive mixed-method approach, including desk research, field surveys, stakeholder interviews, and integrating the Analytic Hierarchy Process (AHP) into a decisionmaking framework. The study categorizes pump stations into priority ranking groups based on the evaluation of the following criteria: efficiency, operating hours, working unit ratio, and discharge capacity. The investigation reveals that the 72 pump stations in Fayoum City play a vital role in regulating water levels, optimizing distribution, and facilitating the reuse of irrigation wastewater. Despite operational challenges, such as manpower shortages and maintenance issues, these stations are crucial for sustaining agricultural productivity and addressing water scarcity concerns, including the prevention of recurring inundation events like the one in 2012. Moreover, the study underscores the potential of wastewater reuse as a sustainable solution to water scarcity, particularly in meeting agricultural water demands and mitigating water balance issues, such as inundation. Based on the findings, the study proposes actionable recommendations, including upgrading high-priority pump stations, evaluating lower-priority ones, enhancing canal infrastructure, and promoting waterefficient irrigation methods. In conclusion, this study provides valuable insights into the pivotal role of pump stations and wastewater reuse in addressing water scarcity challenges in arid regions. By implementing the proposed recommendations, Fayoum City can optimize its water management practices, ensure water security, and support the long-term development of the region. [ABSTRACT FROM AUTHOR]

Published

2024

238. Sustainability of global small-scale constructed wetlands for multiple pollutant control.

Author

Chen, Guogui, Mo, Yuanyuan, Gu, Xuan, Jeppesen, Erik, Xie, Tian, Ning, Zhonghua, Li, Yina, Li, Dongxue, Chen, Cong, Cui, Baoshan, and Wu, Haiming

Subjects

CONSTRUCTED wetlands, POLLUTANTS, SUSTAINABILITY, WATER shortages, BIVARIATE analysis, WETLAND conservation

Abstract

The global wastewater surge demands constructed wetlands (CWs) to achieve the UN's Sustainable Development Goals (SDG); yet the pollutant removal interactions and global sustainability of small CWs are unclear. This study synthesizes small CW data from 364 sites worldwide. The removal efficiency of organic matter and nutrient pollutants of small CWs had a 75th percentile of 68.8–84.0%. Bivariate analysis found consistent synergies between pollutant removals, lasting 3–12 years. The optimal thresholds for maintaining the synergistic effects were as follows: area size—17587 m2, hydraulic loading rate—0.45 m/d, hydraulic retention time—8.2 days, and temperature—20.2 °C. When considering the co-benefits and sustainability of small CWs for multi-pollutants control, promoting small-scale CWs could be an effective and sustainable solution for managing diverse wastewater pollutants while simultaneously minimizing land requirements. This solution holds the potential to address the challenges posed by global water scarcity resulting from wastewater discharge and water pollution. [ABSTRACT FROM AUTHOR]

Published

2024

239. Using 5TE Sensors for Monitoring Moisture Conditions in Green Parks.

Author

Dafalla, Muawia

Subjects

*TIME-domain reflectometry, *DESERTS, *IRRIGATION water, *HYDRAULIC conductivity, *WATER shortages, *BENTONITE

Abstract

The ground surface and subsurface of green parks in arid and desert areas may be subjected to desiccation as a result of weather and hot temperatures. It is not wise to wait until plants are turning pale and yellow before watering is resumed. Given the scarcity of water in typical desert zones, we recommend full control of irrigation water. This study presents a method of recycling irrigation water using 5TE sensors, employing time-domain reflectometry (TDR) technology. A trial test section was constructed along the coast of the eastern province of Saudi Arabia. Water recycling involves using clay–sand liners placed below the top agricultural soils to intercept excess water and direct it towards a collection tank, and then it is pumped out to a major water supply tank. The main properties of soils and clay–sand liners normally taken into account include moisture content, density, and hydraulic conductivity. An assessment of geotechnical properties of clay–sand mixtures containing 20% clay content was conducted. The profiles of moisture and temperature changes were monitored using 5TE sensors and data loggers. The 5TE sensors provided continuous measurements at varying temperatures and watering cycles. Twenty-nine watering cycles were conducted over a six-month period. An additional section was considered with a liner consisting of the same clay but enhanced with bentonite as one-third of the clay content. The volumetric water content was found to vary from 0.150 to 0.565 following changing weather and direct watering cycles. The results indicated that the use of a TDR instrumentation is a cost-effective and time-saving technique to construct a system for saving irrigation water. [ABSTRACT FROM AUTHOR]

Published

2024

240. The Antioxidant Defense System of Tomato (Solanum lycopersicum L.) Varieties under Drought Stress and upon Post-Drought Rewatering.

Author

Niyazova, Naima N. and Huseynova, Irada M.

Subjects

*TOMATOES, *WATER shortages, *VITAMIN C, *PHENOLS, *DROUGHTS, *PLANT productivity, *GUAIACOL

Abstract

Water shortage induces physiological, biochemical, and molecular alterations in plant leaves that play an essential role in plant adaptive response. The effects of drought and post-drought rewatering on the activity of antioxidant enzymes and levels of H2O2, phenolic compounds, ascorbic acid, and proline were studied in six local tomato (Solanum lycopersicum L.) varieties. The contents of H2O2 and ascorbic acid increased in all drought-exposed tomato plants and then decreased upon rewatering. The level of phenolic compounds also decreased in response to water shortage and then recovered upon rehydration, although the extent of this response was different in different varieties. The activities of ascorbate peroxidase (APX) and guaiacol peroxidase (POX) and the content of proline significantly increased in the drought-stressed plants and then decreased when the plants were rewatered. The activities of 8 constitutive APX isoforms and 2 constitutive POX isoforms varied upon exposure to drought and were observed after rewatering in all studied varieties. The information on the response of tomato plants to drought and subsequent rewatering is of great importance for screening and selection of drought-tolerant varieties, as well as for development of strategies for increasing plant productivity under adverse environmental conditions. [ABSTRACT FROM AUTHOR]

Published

2024

241. Differential response of bacteria and fungi to drought on the decomposition of Sarcocornia fruticosa woody stems in a saline stream.

Author

Doménech‐Pascual, Anna, Carrasco‐Barea, Lorena, Gich, Frederic, Boadella, Judit, Freixinos Campillo, Zeus, Gómez Cerezo, Rosa, Butturini, Andrea, and Romaní, Anna M.

Subjects

*COLONIZATION (Ecology), *WATER shortages, *RIVER channels, *FUNGI, *BACTERIA

Abstract

Inland saline ecosystems suffer multiple stresses (e.g., high radiation, salinity, water scarcity) that may compromise essential ecosystem functions such as organic matter decomposition. Here, we investigated the effects of drought on microbial colonization and decomposition of Sarcocornia fruticosa woody stems across different habitats in a saline watershed: on the dry floodplain, submerged in the stream channel and at the shoreline (first submerged, then emerged). Unexpectedly, weight loss was not enhanced in the submerged stems, while decomposition process differed between habitats. On the floodplain, it was dominated by fungi and high cellulolytic activity; in submerged conditions, a diverse community of bacteria and high ligninolytic activity dominated; and, on the shoreline, enzyme activities were like submerged conditions, but with a fungal community similar to the dry conditions. Results indicate distinct degradation paths being driven by different stress factors: strong water scarcity and photodegradation in dry conditions, and high salinity and reduced oxygen in wet conditions. This suggests that fungi are more resistant to drought, and bacteria to salinity. Overall, in saline watersheds, variations in multiple stress factors exert distinct environmental filters on bacteria and fungi and their role in the decomposition of plant material, affecting carbon cycling and microbial interactions. [ABSTRACT FROM AUTHOR]

Published

2024

242. Analysis of the Rainfall Pattern and Rainfall Utilization Efficiency during the Growth Period of Paddy Rice.

Author

Chen, Mengting, Shen, Yingying, Wang, Haili, Cheng, Xiangju, and Luo, Yufeng

Subjects

*PADDY fields, *RAINFALL probabilities, *RAINFALL, *WATER shortages

Abstract

Rainfall is one of the most important water sources for rice production in China. However, its temporal and spatial variability is leading to water shortages. The present study collected a long series of historical rainfall data from research sites during the rice growth period to analyze the characteristics of rainfall distribution and the correlation with rainfall utilization efficiency, aiming to investigate its impact on rice irrigation practices. It is found that the rainfall distribution varied greatly between the different locations and growth periods. The average rainfall of the whole growth period ranges from 135.5 mm to 694.5 mm. The rainfall curve exhibits a typical unimodal pattern with variations in the intensity, duration, and timing of peak precipitation across different growth periods. During the rice growth period, the cases in southern China are more prone to waterlogging for a high probability of continuous rainfall, and the cases in northern China are more prone to drought. The rainfall utilization efficiency of all cases exhibits a significant inter-year fluctuation range, negatively influenced by the rainfall amount and rainfall inhomogeneity. The efficiency in utilizing precipitation is diminished with greater and more uneven rainfall experienced during the growth period. These findings can provide a decision-making basis for optimizing rice irrigation strategies and enhancing rainfall utilization efficiency in diverse regions across China. [ABSTRACT FROM AUTHOR]

Published

2024

243. Influence of Super-Absorbent Polymer on Growth and Productivity of Green Bean under Drought Conditions.

Author

Alotaibi, Mashael M., Alharbi, Maha Mohammed, Alsudays, Ibtisam Mohammed, Alsubeie, Moodi Saham, Almuziny, Makhdora, M. Alabdallah, Nadiyah, Alghanem, Suliman Mohammed Suliman, Albalawi, Bedur Faleh, Ismail, Khadiga Ahmed, Alzuaibr, Fahad Mohammed, Moustafa, Mahmoud M. I., Abd-Elwahed, Ahmed H. M., Hassan, Assad H. A., Khalifa, Sobhy M., and Awad-Allah, Mamdouh M. A.

Subjects

*SUPERABSORBENT polymers, *PEARSON correlation (Statistics), *SOIL remediation, *WATER shortages, *COMMON bean, *DROUGHTS, *GREEN bean

Abstract

The water-retaining and yield-increasing capacity of super-absorbent polymer (SAP) are essential for soil remediation in arid and semi-arid areas. Water availability is an increasing challenge to plant development and crop yield. During the growing seasons in 2021 and 2022, the present study was conducted to evaluate the effect of the addition of different amounts of SAP on the development and yield of green beans (Phaseolus vulgaris L. cv Bronco) under varying water deficit stresses, compared with the control treatment without SAP and water deficit stress. The results demonstrated that a 50% reduction in water requirement (WR) resulted in significant decreases in leaf fresh weight, specific leaf area, leaf total chlorophyll content, pod number, leaf free water content, pod fresh weight per plant, and yield. Decreases were also found in pod total chlorophyll content, carotenoids, dry matter and total protein, leaf proline content, and crude fiber content. Additionally, leaf water saturation deficit was significantly increased under the stress compared with the full irrigation at 100% WR. However, irrigation at 75% WR increased pod contents of ascorbic acid, total sugars, and leaf bound water. The current study also indicated that addition of SAP significantly enhanced the above-mentioned growth characteristics under irrigation at 50% and 75% WR. Treatment with SAP at 3 g/plant was the most effective in mitigating the adverse effects of water deficiency, especially at the irrigation rate of 75% WR. Pearson's correlation analysis showed significantly positive correlations between the growth parameters, as well as pod yield, under water stress and SAP. This study provides a promising strategy for green bean cultivation by adding SAP to soil to alleviate water shortage stress. [ABSTRACT FROM AUTHOR]

Published

2024

244. Different paradigms for dealing with urban water issues, using new technological and governance solutions, learning from Chinese, Indian and European experiences.

Author

Pieter van Dijk, Meine

Subjects

*MUNICIPAL water supply, *CITIES & towns, *CHOICE (Psychology), *WATER management, *APPROPRIATE technology, *WATER shortages

Abstract

Three paradigms to deal with urban water issues are compared. The analysis focuses on their definition and objectives, the role of different stakeholders, the issues they deal with, and the possible solutions suggested. The paradigms differ in scope (from the narrow focus of the sponge city paradigm to the broad goals of eco-city paradigm) and in terms of the governance structures used to coordinate different stakeholders. The smart and sponge paradigms mainly use existing government structures. In the eco-cities approach, the citizens want to be involved through newly created governance structures. Smart and eco-city initiatives emphasize the involvement of stakeholders, while in the sponge cities approach, the initiative is often taken by the local government. Finally, in terms of expected solutions, the paradigms want to create eco- or healthy cities or improve water management to create a more healthy urban environment. After identifying the issue, alternative water-related technologies are available, like generating energy from wastewater or separating grey and brown water. Cities require different governance structures, and managing information flows in an integrated way to solve water and other issues. The experience in Europe, China, and India may help other cities choose the right paradigm. [ABSTRACT FROM AUTHOR]

Published

2024

245. Exploring Farmers' Willingness to Engage in Participatory Irrigation Infrastructure Programs: Evidence from a Water-Stressed Region.

Author

Han, Yilong, Soomro, Mohsin Ali, Li, Yongkui, Garvin, Michael J., and Xue, Rui

Subjects

*IRRIGATION, *WATER distribution, *IRRIGATION water, *SOCIAL sustainability, *FARMERS, *SOCIAL goals, *WATER shortages

Abstract

Climate change is increasingly exacerbating water shortages worldwide. Among the various repercussions of water scarcity, notably in developing countries, the most critical are the decline in social sustainability and the widening inequality within farming communities. In response, irrigation reforms aimed at establishing farmer-managed networks have been introduced to foster equitable water distribution and enhance the livelihood and food security of underprivileged farmers. However, these reforms have largely fallen short of achieving their social sustainability goals. A significant factor in this shortfall is the farmers' limited capacity and reluctance to assume roles typically filled by bureaucracy under institutional reforms. This study explores farmers' willingness to engage in a World Bank-assisted participatory irrigation infrastructure program. We utilized questionnaire surveys and hierarchical analysis to evaluate how various factors influence farmers' willingness to participate. The findings indicate a multifaceted challenge that intensifies in communities fragmented by socioeconomic and political divides. Particularly, the predominance of large landowners in agricultural communities and the absence of sufficient bureaucratic support for participation are key impediments. Our research offers comprehensive insights into the regional sociopolitical obstacles obstructing farmer involvement in government-led participatory projects. It also guides policymakers in grasping the intricate interplay between program design, execution, and contextual elements, which is crucial for the sustainable development of resource-stressed areas. [ABSTRACT FROM AUTHOR]

Published

2024

246. Late-Season Irrigation Influences French Fry Color.

Author

T., Francisco Gonzalez, Pavek, Mark J., Knowles, N. Richard, and Holden, Zachary

Subjects

*POTATO growers, *WATER shortages, *POTATO quality, *POTATO growing, *FRENCH fries

Abstract

Given the increasing challenges of water scarcity and the stringent quality requirements of the frozen potato-processing industry, this multi-year research trial aimed to determine whether reduced late-season irrigation on potatoes could improve French fry color. The study was conducted near Othello, WA, and was comprised of five irrigation levels: 40%, 60%, 80%, 100%, and 120% of modeled evapotranspiration (ET), and five potato cultivars: Alturas, Clearwater Russet, Ranger Russet, Russet Burbank, and Umatilla Russet. Irrigation treatments started 100 to 105 days after planting (DAP), approximately 1500 day degrees (at or near peak canopy growth), and ended at vine kill, 150 to 155 DAP. Fry color was assessed following storage durations of 45 and 90 days after harvest from three storage temperatures of 4.4 °C, 6.7 °C, and 8.9 °C, using a photovolt reflectometer, measuring percent light reflectance, in which higher values represented lighter fries. The study found that reducing late-season irrigation generally improved overall fry color. Fry color improvements were observed in four potato cultivars grown with 20% to 40% less irrigation than the control (100% ET); Ranger Russet exhibited no improvement. Reducing late-season irrigation by more than 40% resulted in darker fries for Clearwater Russet, Russet Burbank, and Umatilla Russet when tubers were stored at 4.4 °C and 6.7 °C. Excess irrigation, greater than 100% ET, generally darkened fries in Alturas, Clearwater Russet, Russet Burbank, and Umatilla Russet. These findings provide valuable guidelines for potato growers, indicating that while reducing late-season irrigation can enhance fry color, the effects may depend on a combination of cultivar, irrigation level, and storage temperature. [ABSTRACT FROM AUTHOR]

Published

2024

247. Reduced Late-Season Irrigation Improves Potato Quality, Often at the Expense of Yield and Economic Return.

Author

Gonzalez T., Francisco, Pavek, Mark J., Knowles, N. Richard, and Holden, Zachary

Subjects

*POTATO quality, *POTATO waste, *WATER shortages, *SEWAGE, *AGRICULTURE, *POTATOES

Abstract

With a rising global population and looming water shortages in the U.S., there is a pressing need for water-efficient farming methods. The water needs of potato plants decrease in the late season due to foliage aging and tuber maturation. Therefore, proper late-season irrigation is vital in preventing water waste and maximizing potato profits. This study assessed the feasibility of reducing late-season irrigation to improve crop water productivity (WPc), tuber quality, and economic return. Field trials were planted near Othello, WA, across three years (2018–20). Treatments included five irrigation levels (ILs), 40%, 60%, 80%, 100%, and 120% of modeled evapotranspiration (ET), and five potato cultivars: Alturas, Clearwater Russet, Ranger Russet, Russet Burbank, and Umatilla Russet. Treatments started 100 to 105 days after planting (DAP), approximately 1500 day degrees (at or near peak canopy growth), and ended at vine kill, 150 to 155 DAP. Water from reduced ILs of 40% to 80% ET was more efficiently converted into yield (WPc) for Alturas than higher ILs; however, economic return for all cultivars typically peaked when irrigation was supplied at or above 80% ET. Tuber quality generally improved with a reduction in irrigation level, occasionally at the expense of yield and economic value. [ABSTRACT FROM AUTHOR]

Published

2024

248. Can we rely on drought‐ending "miracles" in the Colorado River Basin?

Author

Pokharel, Binod, Jagannathan, Kripa Akila, Wang, S.‐Y. Simon, Jones, Andrew, LaPlante, Matthew D., Buddhavarapu, Smitha, Borhara, Krishna, Ulrich, Paul, Leung, Lai‐Yung Ruby, Eklund, James, Hasenyager, Candice, Serago, Jake, Prairie, James R., Kaatz, Laurna, Winchell, Taylor, and Kugel, Frank

Subjects

*WATERSHEDS, *GLOBAL warming, *MIRACLES, *ATMOSPHERIC models, *WATER shortages

Abstract

Unexpected and large spring precipitation events in the Colorado River Basin (CRB) that significantly alleviated an otherwise severe water shortage have been observed for over a century, such as the "Miracle May" of 2015. Although these events are often termed as "drought‐busting" or "miracle events" by water managers and the media, they have not been extensively researched or characterized. In this collaborative study with water managers across the CRB, we propose a definition for these hard‐to‐predict, ultra‐high precipitation events occurring during the late‐snow or snowmelt season. This characterization provides a framework for quantifying the frequency and intensity of extreme dry‐to‐wet springtime transitions. Despite limitations of climate model simulations due to uncertainties and the inhomogeneous qualities, our findings suggest that such transitions may become less frequent and less intense in a warming climate. In view of the potentially wetter but less‐snowy climate in the basin, the need for future research to more quantitatively assess these "miracle events" is emphasized. [ABSTRACT FROM AUTHOR]

Published

2024

249. An Amphiphilic Surface with Improved Thermal Radiation for Water Harvesting.

Author

Wang, Han, Li, Shengtao, Zhang, Ye, Wu, Weihui, Ali, Khaled Abdeen Mousa, and Li, Changyou

Subjects

*WATER harvesting, *HEAT radiation & absorption, *GEOTHERMAL resources, *WATER shortages, *NANOPARTICLES, *ENERGY harvesting, *BORON nitride

Abstract

Water scarcity poses a significant challenge for people living in arid areas. Despite the effectiveness of many bioinspired surfaces in promoting vapor condensation, their water-harvesting efficiency is insufficient. This is often exacerbated by overheating, which decreases the performance in terms of the micro-droplet concentration and movement on surfaces. In this study, we used a spotted amphiphilic surface to enhance the surfaces' water-harvesting efficiency while maintaining their heat emissivity. Through hydrophilic particle screening and hydrophobic groove modifying, the coalescence and sliding characteristics of droplets on the amphiphilic surfaces were improved. The incorporation of boron nitride (BN) nanoparticles further enhanced the surfaces' ability to harvest energy from condensation. To evaluate the water-harvesting performance of these amphiphilic surfaces, we utilized a real-time recording water-harvesting platform to identify microscopic weight changes on the surfaces. Our findings indicated that the inclusion of glass particles in hydrophobic grooves, combined with 1.0 wt.% BN nanoparticles, enhanced the water-harvesting efficiency of the amphiphilic surfaces by more than 20%. [ABSTRACT FROM AUTHOR]

Published

2024

250. Ferrocene Bis(Sulfonate) Salt as Redoxmer for Fast and Steady Redox Flow Desalination.

Author

Xie, Rongxuan, Schrage, Briana R., Jiang, Junhua, Ziegler, Christopher J., and Peng, Zhenmeng

Subjects

*HYDROPHILIC compounds, *ENERGY consumption, *WATER shortages, *SALINE waters, *OXIDATION-reduction reaction, *FERROCENE

Abstract

Desalination is considered a promising solution to alleviate water shortages, yet current methods are often restricted, due to challenges like high energy consumption, significant cost, or limited desalination capacity. In this study, we present a novel approach of redox flow desalination (RFD) utilizing the highly aqueous-soluble and reversible redox-active compound, potassium 1,1′-bis(sulfonate) ferrocene (1,1′-FcDS). This water-soluble organic compound yielded stable and rapid desalination, sustaining extended operation without notable decay and achieving an impressive desalination rate of up to 457.5 mmol·h−1·m−2 and energy consumption as low as 40.2 kJ·molNaCl−1. Specifically, the RFD device effectively desalinated a 50 mM NaCl solution to potable standards within 6000 s using 1,1′-FcDS. It maintained an average energy consumption of 178.16 kJ·molNaCl−1 and exhibited negligible deterioration in desalination rate, energy efficiency, and charge efficiency throughout a rigorous 12,000 s cycling test. Furthermore, the versatility of this method was demonstrated by effectively treating saline water with varying initial concentrations from 10 mM to 50 mM, showcasing its potential across a broad spectrum of applications. [ABSTRACT FROM AUTHOR]

Published

2024