Your search keyword '"WATER RETENTION"' showing total 5,530 results

1. Preparation and properties of magnetic superabsorbent composite based on poly (acrylic acid-acrylamide)-g-sodium alginate/Fe3O4.

Author

Zheng, Yunxiang, Zhang, Huan, Shi, Yaqing, Su, Zirui, Sun, Xinran, and Wang, Xiangpeng

Subjects

*ACRYLIC acid, *SCANNING electron microscopy, *LASER microscopy, *DISTILLED water, *THERMOGRAVIMETRY, *SUPERABSORBENT polymers, *SODIUM alginate

Abstract

Magnetic superabsorbents have been successfully synthesized through aqueous solution polymerization, employing sodium alginate as the backbone material, acrylic acid and acrylamide as the polymeric monomers, Fe3O4 nano-particles as the magnetic component, N,N'-methylenebisacrylamide as the crosslinking agent, and ammonium persulfate serving as the initiator. The micro-morphology and thermal stability of these superabsorbents were thoroughly characterized using scanning electron microscopy (SEM), confocal laser scanning microscopy (CLSM), X-ray diffraction (XRD), and thermogravimetric analysis (TGA), respectively. A comprehensive investigation was undertaken to examine the swelling capacity, water retention properties, magnetic responsiveness, and reusability of the magnetic superabsorbents. The findings reveal that these superabsorbents possess an impressive maximum water absorption capacity of 302.7 g/g in distilled water. Notably, their swelling ratios maintain high levels within a pH range of 5–10. Featuring a porous structure, the magnetic superabsorbents demonstrate rapid swelling kinetics, attaining swelling equilibrium within 30 min in a 1 wt% NaCl solution. Furthermore, the superabsorbents exhibit excellent magnetic responsiveness, characterized by a maximum saturation magnetization of 7.91 emu/g, allowing for swift separation under an external magnetic field. Lastly, the magnetic superabsorbents display outstanding reusability, with their water absorption capacity in distilled water still exceeding 90% of the initial swelling ratio after seven reuse cycles. [ABSTRACT FROM AUTHOR]

Published

2024

2. Preparation and properties of magnetic superabsorbent composite based on poly (acrylic acid-acrylamide)-g-sodium alginate/Fe3O4.

Author

Zheng, Yunxiang, Zhang, Huan, Shi, Yaqing, Su, Zirui, Sun, Xinran, and Wang, Xiangpeng

Subjects

ACRYLIC acid, SCANNING electron microscopy, LASER microscopy, DISTILLED water, THERMOGRAVIMETRY, SUPERABSORBENT polymers, SODIUM alginate

Abstract

Magnetic superabsorbents have been successfully synthesized through aqueous solution polymerization, employing sodium alginate as the backbone material, acrylic acid and acrylamide as the polymeric monomers, Fe3O4 nano-particles as the magnetic component, N,N'-methylenebisacrylamide as the crosslinking agent, and ammonium persulfate serving as the initiator. The micro-morphology and thermal stability of these superabsorbents were thoroughly characterized using scanning electron microscopy (SEM), confocal laser scanning microscopy (CLSM), X-ray diffraction (XRD), and thermogravimetric analysis (TGA), respectively. A comprehensive investigation was undertaken to examine the swelling capacity, water retention properties, magnetic responsiveness, and reusability of the magnetic superabsorbents. The findings reveal that these superabsorbents possess an impressive maximum water absorption capacity of 302.7 g/g in distilled water. Notably, their swelling ratios maintain high levels within a pH range of 5–10. Featuring a porous structure, the magnetic superabsorbents demonstrate rapid swelling kinetics, attaining swelling equilibrium within 30 min in a 1 wt% NaCl solution. Furthermore, the superabsorbents exhibit excellent magnetic responsiveness, characterized by a maximum saturation magnetization of 7.91 emu/g, allowing for swift separation under an external magnetic field. Lastly, the magnetic superabsorbents display outstanding reusability, with their water absorption capacity in distilled water still exceeding 90% of the initial swelling ratio after seven reuse cycles. [ABSTRACT FROM AUTHOR]

Published

2024

3. Experimental Study on Water Retention and Flame Retardancy of Environmental Protection Slurry of Film Coated Gasification Slag.

Author

Shao, Hao, Hu, Huan, Lu, Qingzi, Jing, Shuguang, Pei, Xiaodong, and Wu, Zhengyan

Subjects

FIREPROOFING, THIN films, ELASTIC solids, HEAT radiation & absorption, FIRE prevention

Abstract

Grouting Fire Prevention technology is the most commonly used technology in coal mines. In order to improve the water holding capacity of the slurry and prevent the cracking and re-leakage of air caused by the loss of water, this paper used sodium alginate, sodium polyacrylate and gasification slag to prepare thick paste mixture, and then used calcium chloride to induce the gelation of the mixed paste surface to form an elastic solid film. A kind of environmental protection slurry of coated gasification slag (hereinafter referred to as coated slurry) with good environmental protection, high strength and elastic solid film with flame retardant and water retention on the outer surface was developed. In the 30°C-300°C range, when the coated slurry was heated, it would have a significant heat absorption and cooling effect. The results show that the hydrophilic -COO-, -OH in sodium alginate forms a synergistic effect with -COO-, -COOH in sodium polyacrylate, and enhances the water absorption of sodium polyacrylate; The interaction of calcium ions with sodium alginate on the surface of the mixed slurry causes gelation and forms a calcium alginate film on the surface of the coated slurry, which prevents water evaporation. [ABSTRACT FROM AUTHOR]

Published

2024

4. Calcium alginate microspheres coated by bio-based UV-cured resin with high water retention performance.

Author

Yu, Tingting, Wang, Xu, Hu, Yuehang, Zhao, Yang, Zhu, Cenming, Cheng, Liang, Kong, Linghan, Zheng, Han, Yue, Baoshan, Zhan, Jianbo, Yu, Zhenhua, Wang, Hao, and Zhang, Ying

Subjects

*CORE materials, *PROTECTIVE coatings, *SOY oil, *DOUBLE bonds, *INTERNET content management systems

Abstract

In this work, a bio-based resin of acrylated epoxidized soybean oil (AESO) mixed with three types of active diluents (Isoborneol methacrylates [IBOMA], tripropylene glycol diacrylate [TPGDA], and Ethoxylated trimethylolpropane triacrylate [ETPTA]) is used to form a protective UV-curable coating film on calcium alginate water-carrying microspheres (CA-WCMs). Calcium alginate microspheres (CAMs) have previously been used to encapsulate only ester soluble or oil-in-water core materials, thus limiting their application. After UV-curing with an increased active diluent dose, the pencil hardness, pendulum hardness, and mechanical strength of the CAMs increased. A photopolymerization kinetics study reveals that the maximum double bond (C=C) conversion rates of AESO-IBOMA, AESO-TPGDA, and AESO-ETPTA are 95, 92, and 86%, respectively, and the maximum conversion rate of C=C bond is 87% in their mixed system. Additionally, the water retention rate of the water-carrying microspheres (WCMs) increased with an increasing number of coating layers, plateauing after the number of layers exceeded four. The water retention is favorable, with more than 75% of the water stored for a duration of 50 days. Overall, the cost-effective and environmentally friendly method has shown encouraging results in the acquisition of water-absorbing CAMs, with the potential to overcome existing implementation constraints. [ABSTRACT FROM AUTHOR]

Published

2024

5. Development of biodegradable gum guggul-based hydrogel as an efficient moisture-retaining agent for agricultural applications.

Author

Saleem, Shabnum, Sharma, Kashma, Sharma, Amit Kumar, Sharma, Vishal, Kumar, Vaneet, and Kumar, Vijay

Abstract

We prepared guggul gum-based hydrogel (GgG-cl-poly(AA)) through a free radical graft copolymerization mechanism in this work. The preparation was carried out using ammonium persulfate as an initiator, acrylic acid as the monomer, and N, N′-methylenebisacrylamide as the crosslinker. The synthesized hydrogel's swelling capacity and equilibrium swelling ratio were thoroughly investigated by optimizing various reaction parameters: reaction time, solvent volume, microwave power, crosslinker amount, initiator concentration, and monomer concentration. The swelling results demonstrated that the synthesized hydrogel can attain a maximum percentage swelling of 980% within 3 h in an aqueous solution. The prepared hydrogel sample was characterized using Fourier transform infrared, X-ray diffraction, scanning electron microscopy, nuclear magnetic resonance, and thermogravimetric analysis. The prepared hydrogel was studied for water retention behavior in the soil, water absorbance in the open air at room temperature, reswelling studies, and resistive swelling studies in various salt solutions at different temperatures and pH values. Notably, the crosslinked hydrogel exhibited a reduced swelling capacity across various salt solutions compared to the aqueous solutions. The biodegradation studies were examined in both soil burial and vermicomposting methods for two months, revealing a maximum biodegradation of 95.65% through the vermicomposting method and 87.7% through the soil burial method. The results indicate that the crosslinked hydrogel based on guggul gum is a potential candidate for various agricultural applications. [ABSTRACT FROM AUTHOR]

Published

2024

6. Development of a New Method for Evaluating Heat and Moisture Exchanger Performance.

Author

Kouhei Nagata, Tomio Andoh, Ken Kishimoto, Kunihisa Eguchi, Yutaka Usuda, Toshihiro Tsuji, Go Hirabayashi, and Koichi Maruyama

Subjects

WATER analysis, ARTIFICIAL respiration equipment, CONTINUING education units, EVALUATION research, RESEARCH funding, RESPIRATORY therapy, PRODUCT design, RESEARCH evaluation, DESCRIPTIVE statistics, HUMIDITY, HEAT, NEBULIZERS & vaporizers, TEMPERATURE, MECHANICAL ventilators

Abstract

BACKGROUND: A model system described in International Organization for Standardization 9360 is the standard method for estimating the humidifying performance of heat and moisture exchangers (HMEs). However, there are no reliable bedside methods for evaluating the ongoing humidification performance of HMEs. Therefore, this study aimed to develop 2 clinically applicable methods for estimating the ongoing humidifying performance of HMEs and to evaluate their reliability in a model system. METHODS: Physiologically expired gas was simulated using a heated humidifier, and ventilation was delivered using a ventilator with constant flow through 3 different types of HMEs. Relative humidity (RH) was measured using a capacitive-type moisture sensor. Water content lost during expiration was calculated by integrating absolute humidity (AH), instantaneous gas flow measured at the expiratory outlet of the ventilator, and time. We also calculated the water content released and captured by the HMEs during tidal ventilation by integrating the difference in AH across the HMEs, instantaneous gas flow, and time. RESULTS: We found that the RH, temperature, and AH were almost constant on the expiratory outlet of the ventilator but rapidly varied near the HMEs. The water content lost by the 3 HMEs was associated with the manufacturer-reported values and inversely correlated with the calculated values of the water content exchanged by the HMEs. The water content released and captured by HMEs was closely correlated with the difference in HME weight measured at the end of inspiration and expiration; however, the water content captured by HMEs seemed to be overestimated. CONCLUSIONS: Our results demonstrated that our system was able to detect the differences in the performance of 3 models of HMEs and suggest that our method for calculating water loss is reliable for estimating the water retention performance of HMEs during mechanical ventilation, even in the presence of a constant flow. [ABSTRACT FROM AUTHOR]

Published

2024

7. Conceptual and Applied Aspects of Water Retention Tests on Tailings Using Columns.

Author

Marinho, Fernando A. M., Corrêa, Yuri, Soares, Rosiane, Carvalho, Inácio Diniz, and de Sousa Silva, João Paulo

Abstract

The water retention capacity of porous materials is crucial in various geotechnical and environmental engineering applications such as slope stability analysis, landfill management, and mining operations. Filtered tailings stacks are considered an alternative to traditional tailings dams. Nevertheless, the mechanical behaviour and stability of the material under different water content conditions are of concern because these stacks can reach considerable heights. The water behaviour in these structures is poorly understood, particularly the effects of the water content on the stability and potential for liquefaction of the stacks. This study aims to investigate the water retention and flow characteristics of compacted iron ore tailings in high columns to better understand their hydromechanical behaviour. The research used 5 m high columns filled with iron ore tailings from the Quadrilátero Ferrífero region in Minas Gerais, Brazil. The columns were prepared in layers, compacted, and instrumented with moisture content sensors and suction sensors to monitor the water movement during various stages of saturation, drainage, infiltration, and evaporation. The sensors provided consistent data and revealed that the tailings exhibited high drainage capacity. The moisture content and suction profiles were effectively established over time and revealed the dynamic water retention behaviour. The comparison of the data with the theoretical soil water retention curve (SWRC) demonstrated a good correlation which indicates that there was no hysteresis in the material response. The study concludes that the column setup effectively captures the water retention and flow characteristics of compacted tailings and provides valuable insights for the hydromechanical analysis of filtered tailings stacks. These findings can significantly help improve numerical models, calibrate material parameters, and contribute to the safer and more efficient management of tailings storage facilities. [ABSTRACT FROM AUTHOR]

Published

2024

8. Carboxymethylation of viscose and cotton fibers: comparisons of water retention and moisture sorption.

Author

Bogner, Paul, Schlapp-Hackl, Inge, Hummel, Michael, Bechtold, Thomas, Pham, Tung, and Manian, Avinash P.

Subjects

COTTON fibers, METHYLENE blue, BASIC dyes, CONTRAST effect, CARBOXYMETHYLATION

Abstract

The aim of the work was to compare the water retention and moisture sorption of viscose (CV) and cotton (Co) fibers carboxymethylated from aqueous media, in presence of NaOH, with sodium monochloroacetate. It was shown previously that under the same treatment conditions, the degree of carboxymethylation was higher in CV and so was the depth within fiber structures to which the carboxymethylation reactions occurred. It was also shown previously, that in terms of their capacity for sorption of a cationic dye (methylene blue), the Co performed better than CV. In this work, the same fibers were tested for their water retention and moisture sorption propensities. The two were sensitive both to the degree of carboxymethylation and the inherent properties of fibers (accessibility, degree of swelling, hornification). But the moisture sorption levels were less sensitive to the degree of carboxymethylation and more to inherent fiber properties whereas the reverse was observed for water retention. In contrast to the prior observations with dye sorption, CV performed better than Co in both moisture sorption and water retention. The poor performance of CV in dye sorption was attributed to the greater depth of carboxymethylation within the fibers that hindered dye permeation, but the same feature was observed to result in better performance (water retention) or not to hinder performance (moisture sorption). These observations highlight the contrasting effects that may arise, of a given set of treatment parameters (fiber type, alkali level in treatment), on efficacy of the product performance. [ABSTRACT FROM AUTHOR]

Published

2024

9. Hydrogels as water and nutrient reservoirs in agricultural soil: a comprehensive review of classification, performance, and economic advantages.

Author

Wu, Yudi, Li, Simeng, and Chen, Gang

Subjects

SUSTAINABLE agriculture, ENVIRONMENTAL impact analysis, WATER use, IONIC strength, CROP yields

Abstract

In recent years, the development of various hydrogel types has aimed to address concerns regarding the inefficient utilization of water and nutrients in agricultural settings. However, conflicting outcomes have emerged regarding the effectiveness of hydrogel application in agriculture and its potential negative environmental consequences. Therefore, this comprehensive review seeks to evaluate the functionality of hydrogels as water and nutrient reservoirs, while identifying potential solutions to mitigate their environmental impacts based on previous research. By synthesizing data from prior studies, this review analyzes how the performance of hydrogels may be influenced by soil pH, ionic strength, and other solution chemistry factors in the environment. Notably, this review encompasses a comprehensive assessment of the impact of the environmental matrix on hydrogel performance, which fills an important knowledge gap and provides valuable insights for future research directions and practical applications in agricultural lands. Considering sustainability concerns associated with conventional hydrogel applications, it is recommended to explore biodegradable hydrogels derived from natural materials like cellulose. These biodegradable options offer minimal negative impacts on the environment. Although studies on the economic analysis of hydrogel usage are limited, they play a significant role in identifying current obstacles and promoting the adoption of biodegradable hydrogels. Conventional hydrogels have shown greater commercial benefits, but the increasing focus on environmental concerns has driven the development of nature-based hydrogels (e.g., starch) in recent years. However, the trade-off between the relatively high cost of biodegradable hydrogels and their low environmental impacts necessitates more pilot-scale experiments and political efforts in this field. In summary, this review demonstrates that incorporating sustainable hydrogels into soils can effectively improve water and nutrient retention, ultimately enhancing crop production. These findings suggest a promising and sustainable future for hydrogel applications in agriculture, while emphasizing the need for further research, pilot studies, and concerted efforts to strike a balance between economic viability and environmental considerations. [ABSTRACT FROM AUTHOR]

Published

2024

10. The Hydrologic Mitigation Effectiveness of Bioretention Basins in an Urban Area Prone to Flash Flooding.

Author

Laub, Brian G., Von Bon Jr., Eugene, May, Lani, and Garcia, Mel

Subjects

URBAN runoff management, GREEN infrastructure, MAINTENANCE costs, CONSTRUCTION costs, HYDROLOGY

Abstract

The hydrologic performance and cost-effectiveness of green stormwater infrastructure (GSI) in climates with highly variable precipitation is an important subject in urban stormwater management. We measured the hydrologic effects of two bioretention basins in San Antonio, Texas, a growing city in a region prone to flash flooding. Pre-construction, inflow, and outflow hydrographs of the basins were compared to test whether the basins reduced peak flow magnitude and altered the metrics of flashiness, including rate of flow rise and fall. We determined the construction and annual maintenance cost of one basin and whether precipitation magnitude and antecedent moisture conditions altered hydrologic mitigation effectiveness. The basins reduced flashiness when comparing inflow to outflow and pre-construction to outflow hydrographs, including reducing peak flow magnitudes by >80% on average. Basin performance was not strongly affected by precipitation magnitude or antecedent conditions, though the range of precipitation magnitudes sampled was limited. Construction costs were higher than previously reported projects, but annual maintenance costs were similar and no higher than costs to maintain an equivalent landscaped area. Results indicate that bioretention basins effectively mitigate peak flow and flashiness, even in flash-flood-prone environments, which should benefit downstream ecosystems. The results provide a unique assessment of bioretention basin performance in flash-flood-prone environments and can inform the optimization of cost-effectiveness when implementing GSI at watershed scales in regions with current or future similar precipitation regimes. [ABSTRACT FROM AUTHOR]

Published

2024

11. Effect of Biochar on Dwarf Green Coconut Orchard Yield and Irrigation Water Productivity.

Author

Gonçalves Oliveira, John Jackie, Gondim, Rubens Sonsol, Távora Costa, Raimundo Nonato, and da Silva, Janderson Pedro

Subjects

*IRRIGATION water, *BIOCHAR, *COCONUT palm, *COCONUT water, *ARID regions, *COCONUT

Abstract

The high irrigation water demand of coconut trees in semiarid regions makes rational use crucial for crop sustainability. Additionally, it produces residues that could improve the soil water holding capacity. This research aimed to evaluate the application of coconut shell biochar to an irrigated dwarf green coconut palm orchard. The study was carried out from January 2019 to December 2021 at Campo Experimental do Curu, Paraipaba, Brazil, belonging to Embrapa Agroindústria Tropical. The experiment consisted of a completely randomized design with five treatments and four replications and included the application of 0, 5, 10, 20, or 40 g of biochar per kg of soil, equivalent to 0.0 kg, 0.5 kg, 1.0 kg, 2.0 kg or 4.0 kg of biochar per plant, respectively. The following biometric variables were evaluated: number of leaves per plant (NL), plant height (PH), number of leaflets per leaf (LFT), canopy diameter (CD) and fruit production: number of bunches per plant (NB), number of fruits per plant (NF), volume of coconut water per fruit (CWF) and total soluble solids (TSS) (°Brix), as well as the daily soil moisture average. The results showed beneficial effects on the number of leaves per plant, fruits per plant, soil moisture and irrigation water productivity in terms of liters per fruit, liters per coconut water and fruits per cubic meter (m3) applied with ideal biochar doses estimated to be 1.40 kg, 1.72 kg, 1.79 kg, 1.56 kg, 1.48 and 1.68 kg of biochar per plant, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

12. Research progress in processing technology of rabbit meat.

Author

Deng, Yunjia, Nie, Qing, Zhou, Yanan, Wang, Wei, Wu, Zhoulin, Ji, Lili, Zhang, Jiamin, and Zhou, Decai

Subjects

RABBIT meat, MEAT texture, DEODORIZATION, MANUFACTURING processes, PROBLEM solving

Abstract

Rabbit meat is tender, high in protein, low in fat and cholesterol, and offers several nutritional benefits. However, it has a stronger taste and can be challenging to cook. The global rabbit industry has been developing steadily, and China's total rabbit meat production has exceeded half of the world's total production in 2021. Along with the progress of the production process, the meat of the nutrition and taste at the same time, to improve smell also can get better control, solved the problems met in rabbit meat production. This article discusses the attributes of rabbit meat and outlines the deodorization, texture adjustment, and water retention techniques currently used in rabbit meat processing, aiming to offer a theoretical foundation for the advancement of rabbit meat processing technology. [ABSTRACT FROM AUTHOR]

Published

2024

13. Organic Capillary Barriers for Soil Water Accumulation in Agriculture: Design, Efficiency and Stability.

Author

Smagin, Andrey, Sadovnikova, Nadezhda, Krivtsova, Victoria, Korchagina, Christina, and Krasilnikov, Pavel

Subjects

ARID regions agriculture, SOIL moisture measurement, WATER in agriculture, BUTTERNUT squash, SPRINKLER irrigation

Abstract

Acute shortage of water resources and high unproductive water losses are the key problems of irrigated agriculture in arid regions. One of the possible solutions is to optimize soil water retention using natural and synthetic polymer water absorbers. Our approach uses the HYDRUS-1D design to optimize the placement of organic water absorbents such as peat and composite hydrogels in the soil profile in the form of water-storing capillary barriers. Field testing of the approach used a water balance greenhouse experiment with the cultivation of butternut squash (butternut squash (Cucurbita moschata (Duchesne, 1786)) under sprinkler irrigation with measurement of the soil moisture profile and unproductive water losses in the form of lysimetric water outflow. In addition, the biodegradation rate of organic water absorbents was studied at the soil surface and at a depth of 20 cm. Organic capillary barriers reduced unproductive water losses by 40–70%, retaining water in the topsoil and increasing evapotranspiration by 70–130% with a corresponding increase in plant biomass and fruit yield. The deepening of organic soil modifiers to the calculated depth not only allowed capillary barriers to form, but also prevented their biodegradation. The best results in soil water retention, plant growth and yield according to the "dose-effect" criterion were obtained for a composite superabsorbent with peat filling of an acrylic polymer matrix. The study showed good compliance between the HYDRUS design and the actual efficiency of capillary barriers as an innovative technology for irrigated agriculture using natural and synthetic water absorbents. [ABSTRACT FROM AUTHOR]

Published

2024

14. Effects of Low Voltage Electrostatic Field Combined with Low Temperature and High Humidity Thawing on Beef Tenderness and Water Retention

Author

Qingqing LI, Xiaojia BAI, Hengxun LIN, Chunhui ZHANG, Shuangmei XIA, and Xia LI

Subjects

frozen beef, low-pressure electrostatic field, low temperature and high humidity thawing, synergistic effect, water retention, tenderness, Food processing and manufacture, TP368-456

Abstract

To investigate the effects of a low-pressure electrostatic field combined with low temperature and high humidity on beef tenderness, this study utilized bovine longissimus dorsi muscle as the experimental material. The analysis included low-pressure electrostatic field thawing (at a temperature of 4 ℃ and relative humidity of 50%), low temperature and high humidity thawing (at a temperature of 4 ℃ and relative humidity of 98%), low-pressure electrostatic field combined with low temperature and high humidity thawing (temperature 4 ℃ and relative humidity 98%), and low temperature thawing (temperature 4 ℃ and relative humidity 50%). The parameters examined encompassed shear force, texture, water distribution, water content, water holding capacity, and sensory evaluation of frozen beef. The findings revealed that low-voltage electrostatic field combined with low-temperature and high-humidity thawing exhibited the shortest thawing time (804 min) compared to the other three thawing methods. The thawing loss (2.06%), cooking loss (26.09%), and centrifugation loss (15.00%) were significantly lower than the other three thawing methods (P

Published

2024

15. Research progress in processing technology of rabbit meat

Author

Yunjia Deng, Qing Nie, Yanan Zhou, Wei Wang, Zhoulin Wu, Lili Ji, Jiamin Zhang, and Decai Zhou

Subjects

deodorization, process technology, rabbit meat, texture adjustment, water retention, Food processing and manufacture, TP368-456

Abstract

Abstract Rabbit meat is tender, high in protein, low in fat and cholesterol, and offers several nutritional benefits. However, it has a stronger taste and can be challenging to cook. The global rabbit industry has been developing steadily, and China's total rabbit meat production has exceeded half of the world's total production in 2021. Along with the progress of the production process, the meat of the nutrition and taste at the same time, to improve smell also can get better control, solved the problems met in rabbit meat production. This article discusses the attributes of rabbit meat and outlines the deodorization, texture adjustment, and water retention techniques currently used in rabbit meat processing, aiming to offer a theoretical foundation for the advancement of rabbit meat processing technology.

Published

2024

16. Feasibility of compacted attapulgite/diatomite amended clayey soils as gas barrier materials

Author

Heng Zhuang, Wei-Yi Xia, Jia-Ming Wen, Min Wang, Ying-Zhen Li, Ning-Jun Jiang, Konstantin S. Rodygin, and Yan-Jun Du

Subjects

Compacted clay liner, Attapulgite/diatomite mixture, Diffusion barrier, Water retention, Engineering geology. Rock mechanics. Soil mechanics. Underground construction, TA703-712

Abstract

Compacted clay liners are extensively used as barriers to control the upward diffusion of vapors of volatile or semi-volatile organic contaminants released from unsaturated contaminated soils at industry-contaminated sites. This study aimed to investigate the gas diffusion barrier performance of compacted clayey soils amended with three agents including attapulgite and diatomite individually, and attapulgite/diatomite mixture. The properties including water retention, volumetric shrinkage, gas diffusion, and unconfined compressive strength were evaluated through a series of laboratory tests of amended compacted clayey soils. The results demonstrate that the decrease in volume proportions of inter-aggregate pores leads to an increase in unconfined compressive strength (qu). Both hydrophilic groups and microstructures of attapulgite and diatomite result in an increase in water retention percent (Wt) of compacted clayey soil specimens after amendment regardless of the type of agent or initial water content (w0). Furthermore, the ratio of the gas diffusion coefficient (De) to the gas diffusion coefficient in the air (Da) was significantly reduced owing to a decrease in volume proportions of inter-aggregate pores, hydrophilic group, and microstructures of attapulgite and diatomite. Scanning electron microscope analyses revealed that rod-shaped attapulgite filled the inter-aggregate pores formed by clay particles, whereas the disc-shaped diatomite particles, characterized by micropores, failed to obstruct the inter-aggregate pores due to their larger particle size. Mercury intrusion porosimetry (MIP) analyses showed a reduction in pore volume in the inter-aggregate pores, leading to a reduction in the total pore volume for both the attapulgite and attapulgite/diatomite mixture amended clays, which is in accordance with the scanning electron microscope (SEM) results. The findings are pertinent to the practical application of compacted clay liners as gas barriers against the upward migration of volatile or semi-volatile organic contaminants at contaminated sites.

Published

2024

17. Urea intercalated encapsulated microalgae composite hydrogels for slow-release fertilizers

Author

Nada Sarhan, Esraa G. Arafa, Nada Elgiddawy, Khaled N. M. Elsayed, and Fatma Mohamed

Subjects

Microalgae, Hydrogels, Slow-release fertilizer, Water retention, Medicine, Science

Abstract

Abstract In agriculture, hydrogels can be addressed for effective operation of water and controlled-release fertilizers. Hydrogels have a significant ability for retaining water and improving nutrient availability in soil, enhancing plant growth while reducing water and fertilizer usage. This work aimed to prepare a hydrogel composite based on microalgae and biopolymers including chitosan and starch for use as a soil conditioner. The hydrogel composite was characterized by FTIR, XRD, and SEM. All hydrogel properties were studied including swelling degree, biodegradability, water-holding capacity, water retention, and re-swelling capacity in soil and water. The urea fertilizer loading and releasing behavior of the prepared hydrogels were investigated. The results revealed that the range of the maximal urea loading was between 99 and 440%, and the kinetics of loading was fitted with Freundlich model. The urea release % exhibited 78–95%, after 30 days, and the kinetics of release was fitted with zero-order, Higuchi, and Korsmeyer–Peppas models. Furthermore, the prepared hydrogels obtained a significant water-holding capacity, after blending soil (50 g) with small amount of hydrogels (1 g), the capacity increased in the range of 99.4–101.5%. In sum, the prepared hydrogels have the potential to be applied as a soil conditioner.

Published

2024

18. Numerical Assessment of Green Infrastructure Influence on Hydrologic Effectiveness in a Suburban Residential Development

Author

Marcin Konrad Widomski and Joanna Czerpak

Subjects

rainwater harvesting, swmm, hydraulic modelling, water retention, green infrastructure, rainfall outflow modelling, rainwater drainage, Environmental technology. Sanitary engineering, TD1-1066, Environmental sciences, GE1-350

Abstract

Applying green infrastructure measures helps to retain water in the land during wet periods, which in turn makes it more available during periods of drought. Water retention reduces the volume of rainwater that transforms into surface runoff, allowing for the increase in the intensity of evapotranspiration and infiltration, which helps to establish a catchment with a balanced hydrologic cycle that’s effectively more resistant to the consequences of climate change. With increasing popularity of introducing Low Impact Development (LID) solutions in highly urbanised catchments characterised by a high runoff coefficient, it is important also to reduce rainwater runoff in residential areas with lower density of housing. This work presents a numerical assessment of green infrastructure (green roofs, rain gardens, permeable paving and rainwater harvesting) performance in increasing retention in a catchment area consisting of single-family houses. The numerical model of potential residency in Ożarów, Poland was developed in SWMM 5.2. software, replicating local conditions with input infiltration data collected through on site and laboratory testing, as well as data gathered during a period of registering local evaporation and precipitation conditions. After running a series of simulations of three rain events, varying in their duration and intensity, the model was enhanced with green infrastructure solutions by the utilisation of LID Controls option in SWMM. With rainfall simulations resulting in varying rainwater outflow hydrographs and with differences in the volume of collected rainwater outflow, the results of LID application were consistent with the reduction of the peak rainwater outflow (reduction rate 61.90-67.99%), as well as the decrease in rainwater outflow volume (reduction rate 61.17-62.12%). This research promotes the hydrologic effectiveness of introducing green infrastructure in low density housing establishments.

Published

2024

19. Water exchange of the forest ecosystems epigeic bryophytes depending on changes of the structural and functional organization of their turfs and the influence of local growth environmental conditions

Author

Oksana Lobachevska and Lyudmyla Karpinets

Subjects

water retention, water recovery, drought resistance, moss plagiomnium cuspidatum, p. ellipticum, turf structure, osmoprotectors, Biology (General), QH301-705.5

Abstract

Background. Moss cover plays a decisive role in increasing soil moisture in forest ecosystems. Bryophytes with high water content can significantly reduce water evaporation from the soil surface and retain it for an extended time. Under the influence of environmental conditions, mosses change the shape and organization of moss turfs thus regulating the efficiency of moisture absorption and retaining. Therefore, it is essential to establish the differences in the water exchange strategy of epigeic dominant moss species depending on the environmental conditions in reserved and anthropogenically disturbed forest ecosystems. Materials and Methods. The research was carried out using the dominant epigeic, typical forest moss species Plagiomnium cuspidatum (Hedw.) T. J. Kop. and P. ellipticum (Brid.) T. J. Kop. from experimental plots of forest ecosystems, which differed in water and temperature regimes and light intensity. We determined the peculiarities of the influence of adaptations of moss turf morphological structure, individual plant’s physiological functional traits, and their metabolic osmoprotective changes based on the leading indicators of their water exchange (coefficients of water retention, water recovery, and drought resistance). Results. It was established that humidity and light intensity in forest ecosystems changed the shape and organization of moss turfs, i.e., the height of individual shoots in the turf and the density and size of leaves. The predominance of the generative or vegetative type of moss reproduction led to significant changes in the morphology of shoots, physiological functional traits of plants, and the density of the turf structure, which was regulated due to the increase in airstream turbulence and wind penetration, absorption and evaporation of water. The hydration of moss tissues was maintained due to the rise in the total carbohydrate content as well as the soluble fraction content primarily in the vegetative shoots. Conclusions. Mosses adapted to variable microclimatic conditions of forest ecosystems due to endohydricity and water retention mechanisms in external capillary spaces, i.e., changes in height, shape, and density of turfs, shoot morphology, various ratios of fertile to sterile plants, and their physiological functional traits. The internal regulation of water potential of cells was ensured by an increased concentration of osmoprotectors (carbohydrates, primarily their soluble fraction).

Published

2024

20. Spatial and Temporal Variability in Bioswale Infiltration Rate Observed during Full-Scale Infiltration Tests: Case Study in Riga Latvia.

Author

Kondratenko, Jurijs, Boogaard, Floris C., Rubulis, Jānis, and Maļinovskis, Krišs

Subjects

GREEN infrastructure, WATER supply, SPATIAL variation, DATABASES, UPLOADING of data, STORMWATER infiltration

Abstract

Urban nature-based solutions (NBSs) are widely implemented to collect, store, and infiltrate stormwater. This study addressed infiltration rate as a measure of the performance of bioretention solutions. Quick scan research was conducted, starting with mapping over 25 locations of implemented green infrastructure in Riga, Latvia. Basic information, such as location, characteristics, as well as photos and videos, has been uploaded to the open-source database ClimateScan. From this, eight bioswales installed in the period 2017–2022 were selected for hydraulic testing, measuring the infiltration capacity of bio-retention solutions. The results show a high temporal and spatial variation of infiltration rate for the bioswales, even those developed with similar designs: 0.1 to 7.7 m/d, mean 2.0 m/d, coefficient of variation 1.0. The infiltration capacity decreased after saturation: a 30% to 58% decrease in infiltration rate after refilling storage volume. The variation in infiltration rate as well as infiltration rate decrease on saturation is similar to other full-scale studies done internationally. The infiltration rate of most bioswales falls within the range specified by international guidelines, all swales empty within 48 h. Most bioswales empty several times within one day, questioning the effectiveness of water retention and water availability for dry periods. The results are of importance for stakeholders involved in the implementation of NBS and will be used to set up Latvian guidelines for design, construction, and maintenance. [ABSTRACT FROM AUTHOR]

Published

2024

21. Relationship between Plant-Available Water and Soil Compaction in Brazilian Soils.

Author

Gubiani, Paulo Ivonir, do Santos, Venesa Pinto, Mulazzani, Rodrigo Pivoto, Sanches Suzuki, Luis Eduardo Akiyoshi, Drescher, Marta Sandra, Zwirtes, Anderson Luiz, Koppe, Ezequiel, Pereira, Caroline Andrade, Mentges, Lenise Raquel, Galarza, Rodrigo de Moraes, Boeno, Daniel, Eurich, Keity, Bitencourt Junior, Darcy, Marcolin, Clovis Dalri, and Müller, Eduardo Augusto

Abstract

The capacity of soil to retain water and make it available to plants is an essential soil functions for the sustainability of terrestrial ecosystems. A lot of progress has been made in estimating water retention and availability as a function of soil texture. On the other hand, a lower effort has been dedicated to seeking correlations between plant-available water (AW) and soil compaction. In this study, we compiled a dataset with 2479 records from experiments conducted in Brazilian soils to evaluate the relationship between AW and bulk density (BD). The dataset was split into sub-datasets defined by soil textural classes to reduce the effect of texture on AW–BD relationships. In each sub-dataset, AW–BD relationships were described by linear regression. In general, there was a weak association between AW and BD. The strongest correlations were found in the Silty Loam (R2 = 0.26) and Loam (R2 = 0.13) classes. However, the partitioning of the overall dataset by textural classes was not effective to eliminate the effect of texture on AW–BD relationships. Still, the data showed that soil compaction may increase or reduce AW. Nevertheless, more experimental research is needed to bring a better understanding of how AW is affected by changes in BD. [ABSTRACT FROM AUTHOR]

Published

2024

22. PHYSIOLOGICAL AND BIOCHEMICAL PARAMETERS OF THE EXOTIC SPECIES OF GRASS PEA (LATHYRUS SATIVUS L.).

Author

KODIROVA, S., AMANOV, B., MUMINOV, KH., ABDIYEV, F., BURONOV, A., TURSUNOVA, N., and KURBANBAYEV, I.

Subjects

*PHOTOSYNTHETIC pigments, *CHEMICAL elements, *INTRODUCED species, *CHLOROPHYLL, *CAROTENOIDS, *ALKALINE earth metals, *TRACE elements

Abstract

The article outlines the physiological and biochemical parameters of 10 exotic accessions of two local cultivars of grass pea (Lathyrus sativus L.). By analyzing the plant leaf spectrophotometrically at the bud formation phase, exotic sample Bio-520 x 1330 showed chlorophyll а of 21.47 mg/ml, Bio (520 x Bio) x 273 with chlorophyll b of 12.79 mg/ml, and Ratan x IG 135481 had carotenoids at 5.57 mg/ml. Based on total pigments, Ratan x 1307 gave the highest value (30.24 mg/ml), while in the flowering phase, Ratan x IG 135481 showed chlorophyll а of 21.37 mg/ml, Ratan x 2125 with chlorophyll b of 16.51 mg/ml, and Prateek x IG 140034 with carotenoid of 6.02 mg/ml. For Ratan x 2125, the total pigments were 37.14 mg/ml, with the highest values for all traits. In the ripening phase, Bio 520 x 1330 with chlorophyll а (11.92 mg/ml), Ratan x 2125 with chlorophyll b (16.63 mg/ml), 1330 x 2125 with carotenoid (4.04 mg/ml), and Ratan x 2125 with total pigments (25.62 mg/ml). Higher protein content resulted in seeds of Prateek x IG 140035 (26.3%), Bio (520 x Bio) x 273 (26.1%), and Ratan x 1307 (26.0). Besides, 1330 x 2125 has biochemical elements (Li, B, Na, Cu, and As), Ratan x 2125 (Mg, K, Ca, Ti, Sr, and Ba), Ratan x IG 135481 (Rb, Mo, and Cd), and Prateek x IG 140034 with chemical elements (Al, Fe, and Ag). The control Lalmikor provided B, Mn, Rb, and Ag higher than other exotic samples. [ABSTRACT FROM AUTHOR]

Published

2024

23. Mechanical and hydraulic properties of unsaturated layered pyroclastic ashes in landslide-prone areas of Campania (Italy)

Author

Roman Quintero, Daniel Camilo, Damiano, Emilia, Olivares, Lucio, and Greco, Roberto

Abstract

Air-fall pyroclastic soil deposits usually display a loose fabric composed of alternating layers of ashes and pumices. Such deposits, when lying on steep slopes, represent a major geohazard due to the occurrence of landslides. This is the case of the carbonate massifs in Campania (southern Italy), a wide landslide-prone area of approximately 400 km2 covered with pyroclastic soils. In such cohesionless deposits, the additional shear strength provided by soil suction in unsaturated conditions is important for ensuring slope stability and can be jeopardized by soil wetting during rainwater infiltration. This paper provides a comprehensive view of the hydraulic and shear strength characteristics of different layers of pyroclastic deposits at different sites in Campania, revealing a broad view of their similarities and differences. To that end, some datasets from previous studies and novel data are gathered, linking the index properties, the hydraulic behavior of the soils and the contribution of suction to the shear strength of the studied materials. Two types of ashes at different positions within the stratigraphic sequence are identified: ashes interbedded between pumice layers, where landslide failure surfaces usually occur, and altered ashes in contact with the bedrock, which affects water leakage from the overlying soil profile. The former show quite uniform characteristics, and this allowed testing some predictive models for the assessment of the unsaturated shear strength of pyroclastic ashes in the absence of direct measurements. In contrast, the latter may exhibit significantly different behaviors, with great variability in hydraulic and mechanical properties. [ABSTRACT FROM AUTHOR]

Published

2024

24. Prediction of Soil–Water Characteristic Curves in Bimodal Tropical Soils Using Artificial Neural Networks.

Author

dos Santos Pereira, Sávio Aparecido, Silva Junior, Arlam Carneiro, Mendes, Thiago Augusto, Gitirana Junior, Gilson de Farias Neves, and Alves, Roberto Dutra

Subjects

ARTIFICIAL neural networks, ARTIFICIAL plant growing media, DATABASES

Abstract

Laborious and time-consuming tests are required for the determination of the soil–water characteristic curve (SWCC), often leading to the adoption of estimation methods. To answer the challenge of SWCC prediction, numerous pedotransfer functions (PTF) have been developed. Yet, previous studies have not considered the special behavior of bimodal tropical soils. These materials present dual porosity that is generally attributed to particle aggregation. This paper presents a novel PTF, specifically designed for bimodal tropical soils and based on artificial neural networks (ANNs). The model was trained and tested utilizing a database that was assembled containing soils from tropical regions of Brazil and featuring data for the grain-size distribution (GSD), consistency limits, and SWCC. Natural and remolded soils were included in the training database, but no distinction between soil conditions was made in the ANN. GSDs in the aggregated and disaggregated states were used to offer information to the ANN regarding the effect of particle aggregation on the water retention. The developed model was able to reproduce the typical SWCC shape of bimodal soils. Predictions for the degree of saturation were moderately correlated with directly measured data, with a coefficient of determination of 0.69. The air-entry value and residual suction of the macropores proved to be the most difficult SWCC attributes to be estimated. The ANN presented superior performance when compared to other PTFs not designed specifically for bimodal tropical soils, such as the Arya-Paris and ROSETTA models. It can be concluded from the obtained results that the developed ANN architecture and general approach showed a high capability to capture the main features of the SWCC. [ABSTRACT FROM AUTHOR]

Published

2024

25. Numerical Assessment of Green Infrastructure Influence on Hydrologic Effectiveness in a Suburban Residential Development.

Author

Czerpak, Joanna and Widomski, Marcin K.

Subjects

GREEN infrastructure, HOUSING development, WATER harvesting, HYDROLOGIC cycle, RF values (Chromatography), WATERSHEDS, RAINFALL

Abstract

Applying green infrastructure measures helps to retain water in the land during wet periods, which in turn makes it more available during periods of drought. Water retention reduces the volume of rainwater that transforms into surface runoff, allowing for the increase in the intensity of evapotranspiration and infiltration, which helps to establish a catchment with a balanced hydrologic cycle that's effectively more resistant to the consequences of climate change. With increasing popularity of introducing low impact development (LID) solutions in highly urbanised catchments characterised by a high runoff coefficient, it is important also to reduce rainwater runoff in residential areas with lower density of housing. This work presents a numerical assessment of green infrastructure (green roofs, raingardens, permeable paving and rainwater harvesting) performance in increasing retention in a catchment area consisting of single-family houses. The numerical model of potential residency in Ożarów, Poland was developed in SWMM 5.2. software, replicating local conditions with input infiltration data collected through on site and laboratory testing, as well as data gathered during a period of registering local evaporation and precipitation conditions. After running a series of simulations of three rain events, varying in their duration and intensity, the model was enhanced with green infrastructure solutions by the utilisation of LID Controls option in SWMM. With rainfall simulations resulting in varying rainwater outflow hydrographs and with differences in the volume of collected rainwater outflow, the results of LID application were consistent with the reduction of the peak rainwater outflow (reduction rate 61.90-67.99%), as well as the decrease in rainwater outflow volume (reduction rate 61.17-62.12%). This research promotes the hydrologic effectiveness of introducing green infrastructure in low density housing establishments. [ABSTRACT FROM AUTHOR]

Published

2024

26. Vegetation growth promotion and overall strength improvement using biopolymers in vegetated soils.

Author

Ni, Jing, Wang, Zi-Teng, and Geng, Xue-Yu

Abstract

Planting vegetation is a sustainable and eco-friendly method for shallow slope stabilization. However, in water-limited regions, this method is facing challenges such as retarded vegetation growth, which leads to unprotected soils. Biopolymers, with potentials in both vegetation growth promotion and soil strength enhancement, are therefore tested in this study with regard to their possibility in assisting soil reinforcement with vegetation through vegetation cultivation and direct shear tests. Both sugar-based and protein-based biopolymers improved water availability to growing plants and nutrient uptake. The most suitable polysaccharide xanthan gum was adopted to further explore the effects of treatment conditions (i.e., blending content) and external environment (i.e., precipitation) on the vegetated soil performance. Under a variety of water supplies, xanthan gum with a medium blending content of 0.5% (i.e., with respect to dry soil mass) led to the most substantial improvement in the ability to resist shear loading. This indicates that the appropriate dosage of biopolymers used at the initial stage of plant growth should provide moderate bond strength between soil particles, while not impeding root penetration. Supported by the obtained results, biopolymers are suggested to be used in combination with plants for soil reinforcement for the best efficiency. [ABSTRACT FROM AUTHOR]

Published

2024

27. Effect of air exposure time on erodibility of intertidal mud flats.

Author

van Rees, Floris F., Hanssen, Jill, Gamberoni, Stefano, Talmon, Arno M., and van Kessel, Thijs

Subjects

TIDAL flats, SEDIMENT transport, MUD, COHESION, MATERIAL erosion, INTERTIDAL zonation, YIELD stress, SHEAR strength

Abstract

This study investigates the influence of air exposure time on the erodibility of intertidal mud flats, emphasizing the role of evaporation in altering sediment strength and cohesion. Through a comprehensive approach combining laboratory experiments, fieldwork, and numerical modelling, it explores the dynamic interactions between sediment properties and environmental conditions. The research reveals that drying significantly reduces sediment erodibility, with pronounced effects observed during the initial hours of air exposure. Laboratory tests demonstrate a direct correlation between drying time and increased yield stress for both artificial and field-derived mud samples. Field observations further support these results, showing spatial and temporal variations in water content and shear strength across various locations on a tidal flat. The study emphasizes the critical impact of mud content on water retention and the subsequent effect on sediment stability. The incorporation of drying time into erosion formulations within a numerical model highlights the importance of considering evaporation processes in predicting the morphological evolution of tidal flats. This research contributes to a better understanding of sediment transport dynamics in intertidal zones, offering insights into the mechanisms driving the growth and stability of mud flats. It underscores the necessity of integrating evaporation effects into cohesive sediment transport models to enhance the accuracy of predictions concerning the erosion and accretion of intertidal environments. [ABSTRACT FROM AUTHOR]

Published

2024

28. Swelling Behaviors of Superabsorbent Composites Based on Acrylic Acid/Acrylamide Copolymer and Attapulgite.

Author

Ren, Hanru, Ren, Jun, Tao, Ling, and Ren, Xuechang

Subjects

*SUPERABSORBENT polymers, *ACRYLIC acid, *FULLER'S earth, *ACRYLAMIDE, *DISTILLED water

Abstract

The swelling behaviors and water retention of superabsorbent sand-fixing materials prepared from acrylic acid/acrylamide copolymer (AA/AM) and acid-modified attapulgite under ultrasonic treatments and different pH conditions were investigated. The results demonstrated that a suitable amount of attapulgite can effectively improve the absorption capacity and saltwater performance. The superabsorbent achieved the highest absorptions of 1257.54 g/g and 209.45 g/g in distilled water and a 0.9 wt% NaCl solution, and a higher water absorbency occurred over a wide pH range of 5~9 when the ultrasonic power was 200 W and the attapulgite content was 10%. The addition of attapulgite could significantly increase the water absorption and retention. [ABSTRACT FROM AUTHOR]

Published

2024

29. Ectomycorrhizal trees enhanced water-holding capacity in forest ecosystems in northeastern China.

Author

Jing, Lixin, Yang, Yanbo, Wang, Wenjie, and Wang, Huimei

Subjects

*FOREST conservation, *SOIL physics, *FOREST management, *TREE size, *SOIL density, *ECOSYSTEMS, *TREE planting

Abstract

Improving water-holding functions is an important purpose of sustainable forest management. However, few studies have examined whether there are differences in water-holding capacities between the forests dominated by trees associated with different mycorrhizal types and what are the main factors leading to the differences. Here, we investigated seven parameters of water-holding capacities of soils, litter, and canopy interception in 210 forest plots (10 m × 10 m). The plots were equally divided into three forest types associated with mycorrhizal types, including AM plots (arbuscular mycorrhizal trees > 75% in dominance), ECM plots (ectomycorrhizal trees > 75%), and AM + ECM plots (between 25 and 75%). We calculated tree diversity (richness, Shannon–wiener index, Simpson index, evenness), community structure (diameter at breast height, height, under branch height, density, neighborhood comparison-U, uniform angle index-W, and mingling index-M), and soil physics (soil bulk density and field water content). The results showed that: (1) ECM-dominated communities increased 1.6–2.0-fold in the litter water-holding capacities than those of AM and AM + ECM. The canopy interception of the ECM community was the highest (0.97 mm), significantly higher than that of the AM + ECM community (0.58 mm). (2) The ECM community had lower field soil water-holding capacity (p < 0.05) but 42–78% higher soil non-capillary water capacity than that of AM and AM + ECM (p < 0.05). (3) ECM forests were characterized by low tree species evenness, big-sized trees, and low bulk density, favoring increasing ecosystem water-holding capacities. Moreover, increasing ECM tree dominance enhanced the contribution of community structure to water-holding variations. (4) ECM trees increased ecosystem water-holding functions by direct effects (mainly on the litter) and indirect effects from soil physics (mainly on the soils) or tree size (mainly on the canopy) regulations. This study highlighted that ECM trees enhanced water-holding capacity, providing important information for planting and managing temperate water conservation forests. [ABSTRACT FROM AUTHOR]

Published

2024

30. Post-Recycling Sodium Polyacrylate with Nanostructural Halloysite Additive as the Basic Components of the New Hybrid Soil Modifier—The Circular Economy Rules for SAP in Agriculture.

Author

Sakiewicz, Piotr, Piotrowski, Krzysztof, Rajca, Mariola, and Cieślak, Szczepan

Subjects

CIRCULAR economy, HALLOYSITE, SODIUM, HYGIENE, SOILS, DEIONIZATION of water

Abstract

Post-recycling sodium polyacrylate (SPA) derived from the selective recycling of personal hygiene products was tested as a potential key component of soil modifiers. Recycled SPA in combination with layered aluminosilicate (halloysite) with the sorption capacity of fertilizers allows for the creation of a fully functional, original system responsible for both water retention in soil and controlled dosing of fertilizers. The use of post-recycling SPA (possibly partially supplemented with virgin SPA) is advantageous for the natural environment. The results of different water types retention in post-recycling SPA (deionized water, rainwater, tap water) are discussed. The most beneficial effects of R-SPA swelling and water accumulation are achieved when it comes into contact with rainwater. The clear impact of Mg2+ ions on the sorption capacity of R-SPA introduces the need for a technological compromise between the solution composition (N, P, K or N, P, K, Mg) affecting its fertilization value and the possibility of obtaining maximum R-SPA swelling. The sorption capacity of R-SPA can be slightly increased by using R-SPA/V-SPA mixtures, but R-SPA still plays a decisive role in this system. The possibility of technological adjustment of the leaching rate of fertilizer components under dynamic conditions using different combinations of (R-SPA/V-SPA)/HAL was demonstrated by column tests. [ABSTRACT FROM AUTHOR]

Published

2024

31. Enhancing Heat Removal and H 2 O Retention in Passive Air-Cooled Polymer Electrolyte Membrane Fuel Cells by Altering Flow Field Geometry.

Author

Mohsen, Ali M. and Basem, Ali

Abstract

This numerical study presents six three-dimensional (3D) cathode flow field designs for a passive air-cooled polymer electrolyte membrane (PEM) fuel cell to enhance heat removal and H2O retention. The data collected are evaluated in terms of water content, average temperature, and current flux density. The proposed cathode flow field designs are a straight baseline channel (Design 1), converging channel (Design 2), diverging channel (Design 3), straight channel with cylindrical pin fins (Design 4), trapezium cross-section channel (Design 5), and semi-circle cross-section channel (Design 6). The lowest cell temperature value of 56.67 °C was obtained for Design 2, while a noticeable water retention improvement of 6.5% was achieved in a semi-circle cathode flow field (Design 5) compared to the baseline channel. However, the current flux density shows a reduction of 0.1% to 1.2%. Nevertheless, those values are relatively small compared to the improvement in the durability of the fuel cell due to heat reduction. Although the modifications to the cathode flow field resulted in only minor improvements, ongoing advancements in fuel cell technology have the potential to make our energy landscape more sustainable. These advancements can help reduce emissions, increase efficiency, integrate renewable energy sources, enhance energy security, and support the transition to a hydrogen-based economy. [ABSTRACT FROM AUTHOR]

Published

2024

32. Measured and Predicted Unsaturated Permeability of Cracked Compacted Fine Soil.

Author

Mabrouk, Abdelkader, Jamei, Mehrez, and Ahmed, Anwar

Subjects

PERMEABILITY, ROCK permeability, WATER pressure, SOIL porosity, STRUCTURAL stability, GEOTECHNICAL engineering

Abstract

The unsaturated permeability of cracked compacted fine soil is a key parameter in geotechnical engineering, particularly when analyzing water flow through the soil in various conditions. The compaction affects the saturated and unsaturated permeability by reducing porosity. However, cracks can appear by shrinkage and growth during desiccation, which obviously leads to macro-porosity (a process during which the soil acquires a high level of double porosity). The development of a crack network influences the suction (as negative water pressure) and then the unsaturated permeability. The current paper aims to analyze the role of the crack network (considered as macropores) on the unsaturated permeability, by quantifying the network based on the Crack Intensity Factor (CIF). The unsaturated permeability is given as a function, separately of CIF and suction. The experimental results may be considered constructive for soil modeling. Regarding the birth of the first crack, it occurred when the suction reached a value near to that of the air entry suction. Since the first crack appeared, primary cracks were developed and then followed by secondary cracks. The obtained experimental results of WRC and Kunsat for cracked compacted clay are beneficial in managing the design of the geotechnical structure stability and the environmental issues of water diffusion. CIF increases with suction, which is augmented during the drying process demonstrating a decrease in the moisture content. After 21 hours of desiccation, CIF ended up reaching a value of 4%. It is generally recognized that cracks create preferential pathways for water flow, whereas their geometry and distribution influence how water moves through the soil. Modeling the impact of cracks on permeability may involve considering factors like crack width, orientation, and connectivity. In this paper, a simple model was proposed to predict the unsaturated permeability as a function of suction with different CIF values with the material being assumed as a double porosity soil. [ABSTRACT FROM AUTHOR]

Published

2024

33. Application of biochar in soil remediation: A decade of scientometrics and systematic review from 2014 to 2024

Author

Daniel Hogan Itam, Ibiba Taiwo Horsfall, and Tari Hudson Ekiyor

Subjects

Biochar-supported nZVI, Clay-rich soil, Water retention, Increased microbial activity, Technology

Abstract

This study provides a comprehensive scientometric analysis and systematic review of biochar applications in soil remediation. It was observed that China is the most productive country in this field. In 2023, a significant increase in publications indicating a growing interest in the field was noted. However, this trend is reversing in 2024 from January to May. Furthermore, literatures reveal that biochar-supported nZVI significantly reduces PAH by 99.9 % in ambient condition. Previous research indicates that animal-based biochar exhibited the highest level of biostimulation.In addition, the combination of biochar with clay-rich soil improves soil characteristics. Similarly, biochar improves nitrogen retention, raises pH in acidic soils, microbial biomass and diversity can be enhanced during remediation. Lastly, future research may incorporate quantitative analyses of academic literature in the field by exploring other databases.

Published

2024

34. Assessing water storage capacity and wettability of plants and woody fragments in post-fire environments: A case study in Los Guájares, SE Spain

Author

Anna Klamerus-Iwan, Laura Cambronero Ruiz, Casandra Muñoz Gómez, Agata Warczyk, Pranav Dev Singh, Muhammad Owais Khan, and Andrés Caballero-Calvo

Subjects

Wetting contact angle, Forest fire, Water retention, Drought resilience, Post-fire recovery, Forestry, SD1-669.5, Plant ecology, QK900-989

Abstract

Wildfires pose significant threats to ecosystems, impacting soil properties and hydrological dynamics. This study investigates the water storage capacity and wettability of ecosystem elements, especially plants and woody fragments in post-fire areas of Los Guájares (Granada, SE Spain). Wildfires alter soil acidity, water storage, and nutrient concentration, affecting the hydrological properties of the forest floor. Understanding the water cycle is crucial for preserving and harnessing ecosystem capabilities. Plant wettability, a key parameter reflecting the ability to retain water on surfaces, is integral to the hydrological and ecological functioning of ecosystems. This research employs contact angle measurements and water storage capacity assessments to explore the relationship between leaves and wood wettability in areas affected by last year's fire (B) compared to adjacent unburned areas (U). The research was conducted in Los Guájares, characterized by steep slopes and Mediterranean climate, and utilized photography and angle measurements in graphic software for the wetting contact angle measurements and a weighing method for the plant surface water storage determination. Results reveal that average water capacity (S) decreases with increasing contact angle (CA) on both burned and unburned surfaces. Woody fragments, such as dry but unburned mango branches, exhibit the highest water capacity after 24 h of water immersion (S24), 1.10 [g-1] of water, emphasizing the role of dead wood as a water reservoir. Burnt pine wood and fresh mango branches show lower water retention, indicating the impact of fire on water storage. Findings suggest that while the water capacity of leaves in new plants is similar between burned and unburned areas, wettability differs. This research provides insights into species selection for landscape conservation, informs hillslope restoration planning, and identifies areas resilient to droughts.

Published

2024

35. Long-Term Impact of Soil Management on the Physical and Hydraulic Properties of a Fine-Textured Soil: Insights on the Effects of Minimum Tillage and No-Tillage for Precision Farming Applications

Author

Castellini, Mirko, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Cui, Zhen-Dong, Series Editor, Berruto, Remigio, editor, Biocca, Marcello, editor, Cavallo, Eugenio, editor, Cecchini, Massimo, editor, Failla, Sabina, editor, and Romano, Elio, editor

Published

2024

36. Roles of Coarser-Grained Soil Layers in Capillary Barrier System

Author

Sawada, Mai, Mimura, Mamoru, Murai, Shigemasa, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Cui, Zhen-Dong, Series Editor, Hazarika, Hemanta, editor, Haigh, Stuart Kenneth, editor, Chaudhary, Babloo, editor, Murai, Masanori, editor, and Manandhar, Suman, editor

Published

2024

37. The Use of Field Water Retention and Ambient Temperature for Developing the Soil Water Characteristic Curve

Author

Liyanage, Randhilini, Mousa, Ahmad, Garg, Ankit, Ahmad, Fauziah, Anggraini, Vivi, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Cui, Zhen-Dong, Series Editor, Hazarika, Hemanta, editor, Haigh, Stuart Kenneth, editor, Chaudhary, Babloo, editor, Murai, Masanori, editor, and Manandhar, Suman, editor

Published

2024

38. Preparation and properties of magnetic superabsorbent composite based on poly (acrylic acid-acrylamide)-g-sodium alginate/Fe3O4

Author

Zheng, Yunxiang, Zhang, Huan, Shi, Yaqing, Su, Zirui, Sun, Xinran, and Wang, Xiangpeng

Published

2024

39. Influence of bio-cementation on gas permeability of unsaturated soils in landfill cover system

Author

Huang, Longjian, Cai, Weiling, Chandra, Bogireddy, Garg, Ankit, and Wang, Yanning

Published

2024

40. Anti-erosion ability and water retention of spreading PAM powder granules and spraying PAM gum liquid on inner dump

Author

Wang, Haipeng, Wang, Xuedong, Li, Shiyu, Zhu, Yongdong, Wang, Cui, and Zhang, Heyong

Published

2024

41. Flow through and Volume Change Behavior of a Compacted Expansive Soil Amended with Natural Biopolymers

Author

Ahmed Bukhary and Shahid Azam

Subjects

natural biopolymers, expansive soil, water retention, swell–shrink, consolidation, Dynamic and structural geology, QE500-639.5

Abstract

Natural biopolymers offer a sustainable alternative for improving soil behavior due to their inert nature, small dosage requirement, and applicability under ambient temperatures. This research evaluates the efficacy of natural biopolymers for ameliorating an expansive soil by using a 0.5% dosage of cationic chitosan, charge-neutral guar gum, and anionic xanthan gum during compaction. The results of laboratory investigations indicate that the flow through and volume change properties of the expansive soil were affected variably. The dual porosity, characterized by low air entry due to inter-aggregate pores (AEV1 of 4 kPa) and high air entry due to the clay matrix (AEV2 of 200 kPa) of the soil, was healed using chitosan and guar gum (AEV of 200 kPa) but was enhanced by the xanthan gum (AEV1 of 100 kPa and AEV2 of 200 kPa). The s-shaped swell–shrink path of the soil comprised structural (e from 1.23 to 1.11), normal (e from 1.11 to 0.6), and residual stages (e ranged from 0.6–0.43). This shape was converted into a j-shaped path through amendment using chitosan and guar gum, showing no structural volume change, with e from about 1.25 to 0.5, but was reverted to a more pronounced form by xanthan gum, with e from 1.5 to 1.32, 1.32 to 0.49, and 0.49 to 0.34 in the three stages, respectively. The consolidation behavior of the soil was largely unaffected by the addition of biopolymers such that the saturated hydraulic conductivity decreased from 10−9 m/s to 10−12 m/s over a void ratio decrease from 1.1 to 0.6. At a seating stress of 5 kPa, the swelling potential (7.8%) of the soil slightly decreased to 6.9% due to the addition of chitosan but increased to 9.4% and 12.2% with guar gum and xanthan gum, respectively. The use of chitosan and guar gum will allow the compaction of the investigated expansive soil on the dry side of optimum.

Published

2024

42. Novel nano-fertilizers derived from drinking water industry waste for sustained release of macronutrients: performance, kinetics and sorption mechanisms

Author

Samira S. Elsabagh, Elsayed A. Elkhatib, and Mohamed Rashad

Subjects

Water treatment residuals, Water retention, Adsorption mechanisms, Efficient release, Sustainable agriculture, Medicine, Science

Abstract

Abstract Nanotechnology has emerged as a promising approach for the controlled release of nutrients, particularly phosphorus and potassium. These essential plant nutrients are often applied in excess, leading to environmental pollution and loss of efficiency in crop production. Innovative economic and highly efficient fertilizers are urgently needed to achieve the targeted crop production worldwide in the presence of limited land and water resources. Therefore, in this study, novel, eco-friendly, cost-effective and enhanced efficiency nano-enabled fertilizers, NEF (nWTF1and nWTF2) were synthesized by impregnation of nanostructured water treatment residuals (nWTR) with (KH2PO4 + MgO) at 1:1 and 3:1 (w/w) ratios respectively using a planetary ball mill. The nWTR, nWTF1 and nWTF2 were extensively characterized. The water retention behavior and the sustained release of nutrients from the fabricated nano-enabled fertilizers (nWTF1 and nWTF2) in distilled water and sandy soil were investigated and monitored over time. The water retention capacity of the soil treated with nWTF2 after 26 days was 9.3 times higher than that of soil treated with conventional fertilizer. In addition, the nWTF2 exhibited lower release rates of P, K and Mg nutrients for longer release periods in comparison with the conventional fertilizers. This is a significant advantage over traditional fertilizers, which release nutrients quickly and can lead to leaching and nutrient loss. The main interaction mechanisms of PO4–K–Mg ions with nWTR surface were suggested. The results of the kinetics study revealed that power function was the best suitable model to describe the kinetics of P, K and Mg release data from NEF in water and soil. The produced NEF were applied to Zea maize plants and compared to commercial chemical fertilizer control plants. The obtained results revealed that the nano-enabled fertilizers (nWTF1 and nWTF2) significantly promoted growth, and P content compared with the commercial chemical fertilizer treated plants. The present work demonstrated the power of nano enabled fertilizers as efficient and sustained release nano-fertilizers for sustainable agriculture and pollution free environment.

Published

2024

43. Incorporation of polyzwitterions in superabsorbent network membranes for enhanced saltwater absorption and retention

Author

Kang-Ting Huang, Cao Tuong Vi Nguyen, Pin-Ju Yu, Cheng-Lin Lee, Chun-Jen Huang, and Yung Chang

Subjects

Superabsorbent polymer, Zwitterionic, Water retention, Swelling behavior, Hydrophilic polymers, Chemistry, QD1-999

Abstract

Background: Superabsorbent polymers (SAPs) have a remarkable ability to absorb significant quantities of water. However, their absorption capacity is significantly reduced when exposed to saline solutions, such as urine, due to the polyelectrolyte effect and charge screening. Methods: In this study, we demonstrate a zwitterionic superabsorbent polymer (ZSAP) with excellent salt-water absorption and retention capacities. ZSAP was synthesized by grafting a copolymer of p(sulfobetaine methacrylate-co-2-hydroxyethyl methacrylate) (p(SBMA-co-HEMA)) onto an acrylic acid (AA)-based hydrogel via free-radical polymerization. The introduction of zwitterionic SBMA significantly enhances the hydrophilicity of the polymer, particularly in a saline solution due to the anti-polyelectrolyte effect, thereby accelerating the rate of salt absorption. Additionally, the hydroxyl groups from HEMA facilitate the formation of covalent bonds with the AA network membrane through esterification, effectively mitigating polymer leaching. The hydration/dehydration behaviors of linear polymers were measured using the dynamic vapor sorption (DVS) method. Moreover, the salt-water absorption capacity, centrifuge retention capacity (CRC), and absorbency under load (AUL) of ZSAP with various SBMA moieties and copolymer dosages were comprehensively evaluated in a 0.9 wt% sodium chloride solution. Additionally, the water retention under different temperatures and polymer leaching of ZSAP were investigated. Significant Findings: The copolymer p(SBMA-co-HEMA) not only demonstrates a high salt-water absorption rate at 90% RH in a 0.9 wt% NaCl solution but also exhibits superior water retention at 0% RH compared to the AA polymer. Moreover, the ZSAP exhibits superior salt-water absorption capacity and AUL in a 0.9 wt% NaCl solution compared to conventional AA-based SAP. Additionally, the introduction of the hydroxyl moiety from the p(SBMA-co-HEMA) copolymer reduces free polymer leaching from ZSAP. This work presents an approach for the development of new SAP with high salt-water absorption and retention.

Published

2024

44. Using Beerkan Procedure to Estimate Hydraulic Soil Properties under Long Term Agroecosystems Experiments.

Author

Vergni, Lorenzo, Tosi, Grazia, Bertuzzi, Jennifer, Rossi, Giulia, Farneselli, Michela, Tosti, Giacomo, Tei, Francesco, Agnelli, Alberto, and Todisco, Francesca

Subjects

ORGANIC farming, CROP management, CROPPING systems, TILLAGE, COVER crops, CROP rotation, WINTER wheat

Abstract

The BEST (Beerkan Estimation of Soil Transfer parameters) method was used to compare the hydraulic properties of the soils in two Long-term Agroecosystem Experiments (LTAEs) located at the FIELDLAB experimental site of the University of Perugia (central Italy). The LTAE "NewSmoca" consists of a biennial maize-durum wheat crop rotation under integrated low-input cropping systems with (i) inversion soil tillage (INT) or (ii) no-tillage (INT+) and (iii) under an organic cropping system with inversion soil tillage (ORG). ORG and INT+ involve the use of autumn-sown cover crops (before the maize cycle). Pure stand durum wheat was grown in INT and INT+, while a faba bean–wheat temporary intercropping was implemented in ORG. The LTAE "Crop Rotation" consists of different crop rotations and residue management, a continuous soft winter wheat and biennial rotations of soft winter wheat with maize or faba bean. Each rotation is combined with two modes of crop residue management: removal or burial. For INT+, despite the high-bulk density (>1.50 g/cm3), we found that conductivity, sorptivity and available water are comparable to those of INT, probably due to a more structured and efficient micropore system. ORG soils show the highest conductivity, sorptivity and available water content values, probably due to the recent spring tillage occurring in the wheat inter-row with the faba bean incorporation into the soil. For LTAE Rotation, the residue burial seems to influence the capacity-based indicators positively. However, the differences in the removal treatment are minor, and this could be due to the inversion soil tillage, which limits the progressive accumulation of organic matter. [ABSTRACT FROM AUTHOR]

Published

2024

45. Microbial community shifts indicate recovery of soil physical properties in a post‐tin‐mining area on Belitung Island, Indonesia.

Author

Putra, Hirmas Fuady, Bui, Long Thanh, and Mori, Yasushi

Subjects

MICROBIAL communities, SOIL moisture, CHEMICAL terrorism, SOILS, HYDRAULIC conductivity, SOIL composition

Abstract

Mineral mining often results in changes to the soil environment, reducing the sustainability of the surrounding environment. Restoring the physical and chemical properties of soil in post‐tin‐mining areas on the tropical island of Belitung, Indonesia, has been a laborious process after more than 10 decades of land reclamation. We aimed to determine which parameter of the soil properties was responsible for the slow recovery process and if there were other properties that indicated more rapid changes. We measured the physical, chemical, and biological properties of soils of different periods in the post‐tin‐mining areas. We sampled soil from three areas: 0, 1, and 6 years after mining and an adjacent natural forest as a reference site. The soil water content, hydraulic conductivity, bulk density, particle distribution, mineral content, and soil microbial composition were measured in the field and analyzed in the laboratory. The soil showed a fine particle loss and despite the absence of clay, water‐holding capacity was significantly increased in the 6‐year‐old soil. Organic carbon increased by 0.2% after 6 years of reclamation. Copper, iron, manganese, and zinc in the soils fluctuated less. Minimal amounts of Pb and Cd were found. Soil bacterial communities shift with land age. Actinobacteria were dominant a few years after mining, while Proteobacteria colonized the mined area after 6 years. This study examined the more profound changes in the soil properties of tropical post‐tin‐mined land. Soil and bacterial characteristics can be used as markers to monitor the progress of land rehabilitation. [ABSTRACT FROM AUTHOR]

Published

2024

46. The Effects of Four Different Thawing Methods on Quality Indicators of Amphioctopus neglectus.

Author

Zhang, Huixin, Liu, Shuji, Li, Shuigen, Chen, Xiaoe, Xu, Min, Su, Yongchang, Qiao, Kun, Chen, Xiaoting, Chen, Bei, Zhong, Hong, Lin, Hetong, and Liu, Zhiyu

Subjects

THAWING, DENATURATION of proteins, NUCLEAR magnetic resonance, MEAT preservation, MEAT quality, PROTEIN structure, PROTEOLYSIS

Abstract

Amphioctopus neglectus is a species of octopus that is favored by consumers due to its rich nutrient profile. To investigate the influence of different thawing methods on the quality of octopus meat, we employed four distinct thawing methods: air thawing (AT), hydrostatic thawing (HT), flowing water thawing (FWT), and microwave thawing (MT). We then explored the differences in texture, color, water retention, pH, total volatile basic nitrogen (TVB–N), total sulfhydryl content, Ca2+–ATPase activity, and myofibrillar protein, among other quality indicators in response to these methods, and used a low-field nuclear magnetic resonance analyzer to assess the water migration that occurred during the thawing process. The results revealed that AT had the longest thawing time, leading to oxidation-induced protein denaturation, myofibrillar protein damage, and a significant decrease in water retention. Additionally, when this method was utilized, the content of TVB–N was significantly higher than in the other three groups. HT, to a certain extent, isolated the oxygen in the meat and thus alleviated protein oxidation, allowing higher levels of Ca2+–ATPase activity, sulfhydryl content, and springiness to be maintained. However, HT had a longer duration: 2.95 times that of FWT, resulting in a 9.84% higher cooking loss and a 28.21% higher TVB–N content compared to FWT. MT had the shortest thawing time, yielding the lowest content of TVB–N. However, uneven heating and in some cases overcooking occurred, severely damaging the protein structure, with a concurrent increase in thawing loss, W value, hardness, and shear force. Meanwhile, FWT improved the L*, W* and b* values of octopus meat, enhancing its color and water retention. The myofibrillar protein (MP) concentration was also the highest after FWT, with clearer subunit bands in SDS-PAGE electrophoresis, indicating that less degradation occurred and allowing greater springiness, increased Ca2+–ATPase activity, and a higher sulfhydryl content to be maintained. This suggests that FWT has an inhibitory effect on oxidation, alleviating protein oxidation degradation and preserving the quality of the meat. In conclusion, FWT outperformed the other three thawing methods, effectively minimizing adverse changes during thawing and successfully maintaining the quality of octopus meat. [ABSTRACT FROM AUTHOR]

Published

2024

47. Soil–Water Retention Curve Determination for Sands Using the Filter Paper Method.

Author

Shwan, B. J.

Subjects

*FILTER paper, *SAND filtration (Water purification), *SAND dunes, *SOIL moisture, *SAND, *CALIBRATION, *SAND waves

Abstract

The filter paper (FP) method, a cost-effective, versatile, and convenient approach, has found extensive application in analyzing fine-grained soils, enabling the successful measurement of a broad spectrum of total and matric suctions. However, using the FP method in sand with a limited range of suction profiles has been notably underrepresented in the existing literature. Therefore, this study investigated the applicability of the contact FP method in establishing soil water retention curves (SWRCs) using five distinct FP calibration curves for 10 poorly graded sands. Among these calibration curves, the one presented by Chandler yielded the highest suction values, which were followed by those of ASTM. Furthermore, the FP results were subjected to fitting with a mathmatical model, which led to the observation that the overall trends in the obtained SWRCs displayed smooth sigmoidal shapes, resulting in a complete and coherent SWRCs. The SWRC results of five sand samples were assessed through validation against the hanging column technique (HCT) results, indicating a high degree of concordance and affirming the suitability of the FP method for sands characterized by a limited suction profile. Notably, the entire range of suction values fell within the 0.01–20 kPa range based on the calibration curves presented by Chandler and ASTM for all the examined sand samples, except sands 9 and 10. Furthermore, the suction values were unobtainable using the two aforementioned calibration curves within the ranges of 0.01–1.47 kPa and 0.01–0.172 kPa. [ABSTRACT FROM AUTHOR]

Published

2024

48. Perbaikan Retensi Air dengan Aplikasi Bahan Organik pada Pertanaman Sorgum.

Author

Nurmi, Musa, Nikmah, and Ilahude, Zulzain

Subjects

*CARBON content of water, *BLOCK designs, *ORGANIC compounds, *FACTORIALS, *WATER hyacinth, *RESEARCH methodology, *SORGHUM

Abstract

This study aimed to determine the role of water hyacinth (Eichhornia crassipes Mart.) organic matter on water retention at pF 2.54 and pF 4.2, available water content, and bulk density (BD). The research method used was a factorial randomized block design. The first factor was the sorghum variety, which consisted of 2 levels, namely, V1 (variety) and V2 (Kawali). The second factor was the dose of water hyacinth organic matter, which consisted of 5 levels, namely P0 (without the application of water hyacinth organic matter), P1 (10 tons.ha-1), P2 (20 tons.ha-1), P3 (30 tons.ha-1), and P4 (40 tons.ha-1). Water retention was measured at pF 2.54 and pF 4.2 using a pressure plate apparatus and pressure membrane apparatus, respectively, and BD was measured using the ring method. The results showed that the treatment of organic matter application and varieties had a significant effect on water retention at pF 2.54, available water content, and BD with the best treatment of 40 tons of organic matter application and Kawali variety, but not affecting water retention at pF 4.2. There was no interaction between water hyacinth organic matter and sorghum varieties to improve water retention and BD. The highest water retention at pF 2.54 was 32.24% (P4), and the highest available water content was 11.67% (P4) but not significantly different from P3 (11.55%); the lowest BD was 1.11 g.cm-3 (P4) but not significantly different from P3 (1.13 g.cm-3). A very strong positive linear and negative linear correlation exists between available water content and BD with plant height, panicle length, and sorghum yield. [ABSTRACT FROM AUTHOR]

Published

2024

49. Preparation of pH/temperature-responsive semi-IPN hydrogels based on sodium alginate and humic acid as slow-release and water-retention fertilizers.

Author

Hua, Bingyan, Wei, Hongliang, Hu, Chunwang, Zhang, Yaqi, Yang, Shuai, Wang, Gang, Guo, Tao, and Li, Jingjing

Subjects

*SODIUM alginate, *HUMIC acid, *ALGINATES, *FOURIER transform infrared spectroscopy, *FERTILIZERS, *HYDROGELS, *ETHYLENE glycol

Abstract

Herein, a semi-interpenetrating network (semi-IPN) hydrogel (SH/PNA) was prepared by simple free radical polymerization using N-isopropylacrylamide and 2-acrylamide-2-methylpropanesulfonic acid as monomers, poly(ethylene glycol) dimethacrylate as a crosslinking agent, and sodium alginate and humic acid as filled biomolecules. Fourier transform infrared spectroscopy, scanning electron microscopy, X-ray diffraction, and rheometer were used to characterize the structure and properties of the samples. The effect of feeding ratios on the gel mass fraction and swelling properties of the SH/PNA hydrogel was explored to optimize its preparation conditions. The swelling behavior under different pH and temperatures was investigated. The experimental result showed that the SH/PNA hydrogel had excellent water absorption capacity and pH/temperature dual responsiveness. Moreover, SH/PNA hydrogel was used as a carrier of urea to prepare slow-release and water-retention fertilizer by in situ loading method, and slow-release properties of urea in water and soil were measured. Taking into account its good ability for controlled release and water retention, the WSRF was expected to be a promising low-cost, environmentally friendly fertilizer that can be used in agriculture and horticulture. [ABSTRACT FROM AUTHOR]

Published

2024

50. Modelling the evolution of water retention hysteresis loops during soil deformation based on the ink‐bottle effect.

Author

Chen, Ke, Zhou, Annan, and Liang, Fayun

Subjects

*HYSTERESIS loop, *SOIL mechanics, *SOIL compaction, *POROSITY, *HYSTERESIS

Abstract

The ink‐bottle effect, resulting from the heterogeneous pore structure, plays a significant role in the hydraulic hysteresis of water retention behavior. Experimental evidence indicates that volumetric deformation extensively influences the hysteresis characteristics of the soil‐water retention curve (SWRC). This paper presents a physical–based model that aims to simulate the contraction of the hysteresis loop in the SWRC during soil compression by considering the evolution of the ink‐bottle effect. Within the proposed model, it is assumed that the suction increment is consumed in two distinct manners: to overcome the ink‐bottle effect and to alter soil saturation. As soil undergoes compression, the ink‐bottle effect weakens, resulting in a reduced proportion of suction consumed in counteracting this effect. To quantitatively describe the impact of ink‐bottle effect evolution on SWRC hysteresis, a novel concept known as hysteresis potential is introduced, which is defined as the difference in natural logarithmic values of suction between the drying and wetting curves at a given saturation. Finally, the proposed model was validated using five sets of experimental data, affirming its capability to capture the hysteresis loop evolution in SWRC attributed to the weakening of the ink‐bottle effect during soil compression. [ABSTRACT FROM AUTHOR]

Published

2024