Your search keyword '"SANDY soils"' showing total 10,062 results

151. On the stability of slopes of the subgrade under seismic impacts.

Author

Abduraimov, U. K., Mirzaeva, Z. M., Ismailova, G. B., and Urazov, Kh. U.

Subjects

*EARTHQUAKE zones, *SANDY soils, *SLOPE stability

Abstract

The calculation of the stability of the slopes of the subgrade under difficult engineering and geological conditions, in areas with high seismic activity is considered. The purpose of this study is to analyze the seismic resistance of subgrade structures of different heights. According to regulatory documents, to reduce the negative aftermath of seismic impact on the transport structures, the slopes of the subgrade should consist of sandy soils. [ABSTRACT FROM AUTHOR]

Published

2024

152. Closure to "Infiltration Model Parameters from Rainfall Simulation for Sandy Soils".

Author

Schoener, Gerhard, Rassa, Sara, Fleming, Matthew, and Gatterman, David

Subjects

RAINFALL simulators, PARTICLE size distribution, SOIL crusting, SOIL texture, HYDRAULIC conductivity, SOIL infiltration, SANDY soils

Abstract

This document serves as a closure to a previous article on infiltration model parameters for sandy soils. It addresses points raised by discussers and compares the data to previous work. The writers agree with the discussers' assessment that soil placed in test plots may not directly apply to natural soils, and they acknowledge the importance of ground cover in infiltration and runoff. Additional tests on stone-covered soils are included to illustrate the impact of ground cover. The document also compares findings to previous studies, showing close agreement. The document provides data on the effective hydraulic conductivity of different soil types, categorized as "Bare (scraped)" or "Low," along with corresponding values. The authors acknowledge the study's limitations and the importance of soil data in hydrologic modeling, emphasizing the need for improved methods of model parameterization. [Extracted from the article]

Published

2024

153. The effects of contour-based rainwater harvesting and integrated nutrient management on maize yields in semi-arid regions of Zimbabwe

Author

Pasipanodya Chiturike, Jephta Gotosa, Innocent Wadzanai Nyakudya, Sandra M. Madamombe, Ronald Mandumbu, Ngonidzashe Chirinda, Andrew Tapiwa Kugedera, and George Nyamadzawo

Subjects

Integrated nutrient management, Rainwater harvesting, Semi-arid, Maize, Sandy soils, Climate change, Agriculture (General), S1-972

Abstract

Abstract In the smallholder farming areas located in semi-arid regions of Zimbabwe, low and unreliable rainfall distribution and poor soil fertility are the major factors limiting crop production. The negative effects of these biophysical factors have been worsened by climate change. However, the major challenges have been the lack of sustainable, low-cost water and nutrient management technologies for these semi-arid regions. The objectives of this study were to evaluate the effects of contour-based rainwater harvesting (RWH) namely tied contours (TC), infiltration pits (IP) which were compared with the standard contour (STDC), and intergrated nutrient management (INM) where cattle manure was used as basal fertiliser and Ammonium Nitrate (AN) as top dressing, on maize yields. Results showed that fields with RWH had higher yields compared to STDC. Average maize yields were 2210 and 1792 kg ha−1 for TC and IP which were 88% and 52% above STDC (1176 kg ha−1) respectively. Increasing nitrogen (N) levels resulted in a further increase in maize yields. Return on investment was negative during drier years and was significantly higher in RWH systems compared with STDC during wet seasons. Farmers need to reduce mineral fertiliser application during dry seasons since little rainwater is captured. We conclude that contour based RWH and INM can be used as sustainable low cost methods of crop production. Higher fertiliser application rates when rainfall is limiting, do not result in increased return on investiment.

Published

2024

154. Taste the MEDITERRANEAN

Subjects

Sandy soils

Abstract

TROPICAL SUBTROPICAL ARID/SEMI-ARID WARM TEMPERATE COLD TEMPERATE (PHOTO: GAP PHOTOS_VICTORIA FIRMSTON) Many parts of Australia have a similar climate to the Mediterranean – hot, dry summers and mild, wet winters. [...]

Published

2024

155. Enhancing salt stress tolerance in wheat (Triticum aestivum) seedlings: insights from trehalose and mannitol.

Author

Alhudhaibi, Abdulrahman M., Ibrahim, Mervat A. R., Abd-Elaziz, Seham M. S., Farag, Hanaa R. M., Elsayed, Salwa M., Ibrahim, Hemmat A., Hossain, ABM Sharif, Alharbi, Basmah M., Haouala, Faouzi, Elkelish, Amr, and Srour, Hany A. M.

Subjects

*TREHALOSE, *MANNITOL, *POLYPHENOL oxidase, *SEEDLINGS, *WHEAT, *SALT, *SANDY soils

Abstract

Salinity stress, an ever-present challenge in agriculture and environmental sciences, poses a formidable hurdle for plant growth and productivity in saline-prone regions worldwide. Therefore, this study aimed to explore the effectiveness of trehalose and mannitol induce salt resistance in wheat seedlings. Wheat grains of the commercial variety Sakha 94 were divided into three groups : a group that was pre-soaked in 10 mM trehalose, another group was soaked in 10 mM mannitol, and the last was soaked in distilled water for 1 hour, then the pre soaked grains cultivated in sandy soil, each treatment was divided into two groups, one of which was irrigated with 150 mM NaCl and the other was irrigated with tap water. The results showed that phenols content in wheat seedlings increased and flavonoids reduced due to salt stress. Trehalose and mannitol cause slight increase in total phenols content while total flavonoids were elevated highy in salt-stressed seedlings. Furthermore, Trehalose or mannitol reduced salt-induced lipid peroxidation. Salt stress increases antioxidant enzyme activities of guaiacol peroxidase (G-POX), ascorbate peroxidase (APX), and catalase (CAT) in wheat seedlings, while polyphenol oxidase (PPO) unchanged. Trehalose and mannitol treatments caused an increase in APX, and CAT activities, whereas G-POX not altered but PPO activity were decreased under salt stress conditions. Molecular docking confirmed the interaction of Trehalose or mannitol with peroxidase and ascorbic peroxidase enzymes. Phenyl alanine ammonia layase (PAL) activity was increased in salt-stressed seedlings. We can conclude that pre-soaking of wheat grains in 10 mM trehalose or mannitol improves salinity stress tolerance by enhancing antioxidant defense enzyme and/or phenol biosynthesis, with docking identifying interactions with G-POX, CAT, APX, and PPO. [ABSTRACT FROM AUTHOR]

Published

2024

156. Genome assembly of M. spongiola and comparative genomics of the genus Morchella provide initial insights into taxonomy and adaptive evolution.

Author

Meng, Qing, Xie, Zhanling, Xu, Hongyan, Guo, Jing, Peng, Qingqing, Li, Yanyan, Yang, Jiabao, Dong, Deyu, Gao, Taizhen, and Zhang, Fan

Subjects

*BIOLOGICAL evolution, *MIOCENE Epoch, *GERMPLASM, *BIOGEOGRAPHY, *SANDY soils, *COMPARATIVE genomics, *GENOMES

Abstract

Morchella spongiola is a highly prized mushroom for its delicious flavor and medical value and is one of the most flourishing, representative, and dominant macrofungi in the Qilian Mountains of the Qinghai-Tibet Plateau subkingdoms (QTPs). However, the understanding of M. spongiola remains largely unknown, and its taxonomy is ambiguous. In this study, we redescribed a unique species of M. spongiola, i.e., micromorphology, molecular data, genomics, and comparative genomics, and the historical biogeography of M. spongiola were estimated for 182 single-copy homologous genes. A high-quality chromosome-level reference genome of M. spongiola M12-10 was obtained by combining PacBio HiFi data and Illumina sequencing technologies; it was approximately 57.1 Mb (contig N50 of 18.14 Mb) and contained 9775 protein-coding genes. Comparative genome analysis revealed considerable conservation and unique characteristics between M. spongiola M12-10 and 32 other Morchella species. Molecular phylogenetic analysis indicated that M. spongiola M12-10 is similar to the M. prava/Mes-7 present in sandy soil near rivers, differentiating from black morels ~ 43.06 Mya (million years ago), and diverged from M. parva/Mes-7 at approximately 12.85 Mya (in the Miocene epoch), which is closely related to the geological activities in the QTPs (in the Neogene). Therefore, M. spongiola is a unique species rather than a synonym of M. vulgaris/Mes-5, which has a distinctive grey-brown sponge-like ascomata. This genome of M. spongiola M12-10 is the first published genome sequence of the species in the genus Morchella from the QTPs, which could aid future studies on functional gene identification, germplasm resource management, and molecular breeding efforts, as well as evolutionary studies on the Morchella taxon in the QTPs. [ABSTRACT FROM AUTHOR]

Published

2024

157. Phosphorus uptake and rhizosphere properties of alfalfa in response to phosphorus fertilizer types in sandy soil and saline-alkali soil.

Author

Tianchan Zhang, Weifan Wan, Zhi Sun, and Haigang Li

Subjects

PHOSPHATE fertilizers, SANDY soils, SOIL classification, RHIZOSPHERE, ALFALFA, POTASSIUM, PLATEAUS

Abstract

Introduction: Phosphorus (P) fertilizer is critical to maintain a high yield and quality of alfalfa (Medicago sativa L.). There are several fertilizer types and soil types in China, and the application of a single type of P fertilizer may not be suitable for present-day alfalfa production. Methods: In order to select the optimal combination of alfalfa and soil type and fertilizer type for improving P utilization efficiency. We conducted a greenhouse pot experiment, calcium superphosphate (SSP), diammonium phosphate (DAP), ammonium polyphosphate (APP), potassium dihydrogen phosphate (KP), and no-fertilizer control treatments were applied to alfalfa in sandy and saline-alkali soils. The response of alfalfa root morphology and rhizosphere processes to different P fertilizers was investigated. Results and discussion: The results showed that shoot biomass of alfalfa was slightly higher in sandy soil than in saline-alkali soil. Shoot biomass of alfalfa increased by 223%-354% in sandy soil under P treatments compared with the control, and total root length increased significantly by 74% and 53% in DAP and SSP treatments, respectively. In saline-alkali soil, alfalfa shoot biomass was significantly increased by 229% and 275% in KP and DAP treatments, and total root length was increased by 109% only in DAP treatment. Net P uptake of alfalfa in DAP treatment was the highest in both soils, which were 0.73 and 0.54 mg plant-1, respectively. Alfalfa shoot P concentration was significantly positively correlated with shoot and root biomass (P < 0.05, 0.01 or 0.001) whereas negatively correlated with acid phosphatase concentration (P < 0.05). Improvement of plant growth and P uptake induced by P fertilizer application was greater in sandy soil than in saline-alkali soil. DAP and KP was the most efficient P fertilizers in both sandy soil and saline-alkali soil. [ABSTRACT FROM AUTHOR]

Published

2024

158. Experimental study on the effect of different cement content on the improvement of dynamic characteristics of seismic-prone poor soil.

Author

Zhao, Yunhui, Qiao, Feng, Meng, Fanchao, Zheng, Zhihua, Gu, Jiapei, and Li, Haoyu

Subjects

*MODULUS of rigidity, *CEMENT, *SANDY soils, *EARTHQUAKE resistant design, *ENGINEERING design

Abstract

The improvement of sandy soils with poor seismic properties to modify their dynamic characteristics is of great importance in seismic design for engineering sites. In this study, a series of dynamic tests on sandy soils sandy soils with poor seismic conditions were conducted using the GCTS resonant column system to investigate the improvements effects of different cement contents on dynamic characteristic parameters. The research findings are as follows: The cement content has certain influences on the dynamic shear modulus, dynamic shear modulus ratio, the maximum dynamic shear modulus, and the damping ratio of sandy soils with poor seismic properties. Among them, the influence on dynamic shear modulus is limited, while the damping ratio is significantly affected. The addition of cement to seismic-poor sandy soils significantly enhances their dynamic characteristics. The most noticeable improvement is observed when the cement content is 8%. Through curve fitting analysis, a relationship equation is established between the maximum dynamic shear modulus and the cement content, and the relevant parameters are provided. A comparative test between the improved soils and the remolded soils reveals that the addition of cement significantly improves the seismic performance of the poor soils. The recommended values for the range of variation of the dynamic shear modulus ratio and damping ratio are provided, considering the effect of improvement. These research findings provide reference guidelines for seismic design and engineering sites. [ABSTRACT FROM AUTHOR]

Published

2024

159. Experimental Study on Enhancing the Mechanical Properties of Sandy Soil by Combining Microbial Mineralization Technology with Silty Soil.

Author

Hu, Jun, Fan, Fei, Huang, Luyan, and Yu, Junchao

Subjects

*SANDY soils, *MINERALIZATION, *SHEAR strength, *CALCIUM carbonate, *SOILS, *COASTS

Abstract

Currently, coastal sandy soils face issues such as insufficient foundation strength, which has become one of the crucial factors constraining urban development. Geotechnical engineering, as a traditional discipline, breaks down disciplinary barriers, promotes interdisciplinary integration, and realizes the green ecological and low-carbon development of geotechnical engineering, which is highly important. Based on the "dual carbon" concept advocating a green and environmentally friendly lifestyle, Bacillus spores were utilized to induce calcium carbonate precipitation technology (MICP) to solidify coastal sandy soils, leveraging the rough-surface and low-permeability characteristics of silty soil. The mechanical-strength variations in the samples were explored through experiments, such as calcium carbonate generation rate tests, non-consolidated undrained triaxial shear tests, and scanning electron microscopy (SEM) experiments, to investigate the MICP solidification mechanism. The results indicate that by incorporating silty soil into sandy soil for MICP solidification, the calcium carbonate generation rates of the samples were significantly increased. With the increase in the silty-soil content, the enhancement range was 0.58–3.62%, with the maximum calcium carbonate generation rate occurring at a 5% content level. As the silty-soil content gradually increased from 1% to 5%, the peak deviator stress increased by 4.2–43.2%, enhancing the sample shear strength. Furthermore, the relationship between the internal-friction angle, cohesion, and shear strength further validates the enhancement of the shear strength. Silty soil plays roles in adsorption and physical filling during the MICP solidification process, reducing the inter-particle pores in sandy soil, increasing the compactness, providing adsorption sites, and enhancing the calcium carbonate generation rate, thereby improving the shear strength. The research findings can provide guidance for reinforcing poor coastal sandy-soil foundations in various regions. [ABSTRACT FROM AUTHOR]

Published

2024

160. Physiological and Agronomical Response of Coffee to Different Nitrogen Forms with and without Water Stress.

Author

Ramirez-Builes, Victor Hugo, Küsters, Jürgen, Thiele, Ellen, and Lopez-Ruiz, Juan Carlos

Subjects

SUSTAINABILITY, SOIL acidification, COFFEE, NUTRIENT uptake, AMMONIUM nitrate, SANDY soils, SAND, WATER levels

Abstract

Nitrogen (N) is the most important nutrient in coffee, with a direct impact on productivity, quality, and sustainability. N uptake by the roots is dominated by ammonium (NH4+) and nitrates (NO3−), along with some organic forms at a lower proportion. From the perspective of mineral fertilizer, the most common N sources are urea, ammonium (AM), ammonium nitrates (AN), and nitrates; an appropriate understanding of the right balance between N forms in coffee nutrition would contribute to more sustainable coffee production through the better N management of this important crop. The aim of this research was to evaluate the influences of different NH4-N/NO3-N ratios in coffee from a physiological and agronomical perspective, and their interaction with soil water levels. Over a period of 5 years, three trials were conducted under controlled conditions in a greenhouse with different growing media (quartz sand) and organic soil, with and without water stress, while one trial was conducted under field conditions. N forms and water levels directly influence physiological responses in coffee, including photosynthesis (Ps), chlorophyll content, dry biomass accumulation (DW), nutrient uptake, and productivity. In all of the trials, the plants group in soils with N ratios of 50% NH4-N/50% NO3-N, and 25% NH4-N/75% NO3-N showed better responses to water stress, as well as a higher Ps, a higher chlorophyll content, a higher N and cation uptake, higher DW accumulation, and higher productivity. The soil pH was significantly influenced by the N forms: the higher the NO3−-N share, the lower the acidification level. The results allow us to conclude that the combination of 50% NH4-N/50% NO3-N and 25% NH4-N/75% NO3-N N forms in coffee improves the resistance capacity of the coffee to water stress, improves productivity, reduces the soil acidification level, and improves ion balance and nutrient uptake. [ABSTRACT FROM AUTHOR]

Published

2024

161. Effect of Humic Amendment on Selected Hydrophysical Properties of Sandy and Clayey Soils.

Author

Kandra, Branislav, Tall, Andrej, Vitková, Justína, Procházka, Michal, and Šurda, Peter

Subjects

CLAY soils, SANDY soils, HYDRAULIC conductivity, CONTACT angle, SOIL sampling

Abstract

In recent years, products containing humic acids have been increasingly used in agriculture to improve soil parameters. Quantifying their impact on soil quality is, therefore, of key importance. This study seeks to evaluate the impact of the commercial humic acid product (HA) on the hydrophysical parameters of sandy and clayey soils sampled from different sites in Slovakia. Specifically, the study hypothesizes that humic amendment will enhance particle density (ρs), dry bulk density (ρd), porosity (Φ), saturated hydraulic conductivity (Ks), soil water repellency (SWR), and water retention capacity in sandy and clayey soils. The results of the laboratory measurements were analyzed using NCSS statistical software at a statistical significance of p < 0.05. In sandy soil, there was a statistically significant decrease in ρd and Ks and an increase in Φ and a contact angle (CA) after the application of 1 g/100 cm3 HA. At a dose of 6 g/100 cm3 HA, the values of ρs, ρd, and Ks decreased, and the Φ and CA values increased. In clayey soil, the Ks value significantly decreased by −35.5% only after the application of 6 g/100 cm3 HA. The addition of HA increased the full water capacity (FWC) and available water capacity (AWC) of clayey and sandy soils. The positive influence of HA on the studied soil parameters was experimentally confirmed, which can be beneficial, especially for their use in agricultural production. [ABSTRACT FROM AUTHOR]

Published

2024

162. 脱碳气化渣基土壤调理制剂对土壤养分和 羊草生长的影响.

Author

朱占荣, 马泳波, 边江东, 张 正, 艾 锋, 杨 航, 曹虎生, and 李强

Subjects

*SOIL conditioners, *COAL gasification, *WASTE recycling, *PHOSPHORUS in soils, *SANDY soils

Abstract

Decarbonization gasification slag is a porous solid waste obtained by flotation extraction of residual carbon from coal gasification slag. At present, it is generally used to produce decarbonization gasification slag-based soil conditioner for soil improvement to achieve waste reuse. In order to study effects of decarbonized gasification slag-based soil conditioner on soil properties and growth of forage grass, in this study, using field plot test, and soil nutrients, taking Leymus chinensis as the indicate crop, five appication levels of decarbonized gasification slag-based soil conditioner such as 0(CK), 15(SF1), 30(SF2), 60(SF3), and 120 t/ha(SF4) were set, and physical and chemical properties of sandy soil, physiological and biochemical indexes and quality of Leymus chinensis were analyzed. The results showed that decarbonized gasification slag-based soil conditioner could effectively improve soil nutrient supply capacity, the contents of soil organic matter, alkaline hydrolyzed nitrogen, and available phosphorus in soil of the treatments with addition of decarbonized gasification slag-based soil conditioner increased by 8.95%- 76.96%, 4.95%-46.59%, and 5.80%-105.80% compared to those in CK, respectively. The contents of soil organic matter, alkaline hydrolyzed nitrogen, and available phosphorus in the treatment SF4 were significantly higher than those in other treatments. Compared to CK, the aboveground biomass and the plant height at maturity stage of Leymus chinensis in the treatments with addition of decarbonized gasification slag-based soil conditioner increased by 31.52%-113.16% and 7.10%-28.90%, respectively. The contents of crude protein and crude fat of Leymus chinensis in the additon treatments increased by 29.26% -64.36% and 8.74%-24.84%, respectively. The increase rate of the indexes in the treatment SF4 was the highest, and the contents of crude protein and crude fat reached to 73.70 and 117.10 g/kg. In conclusion, the treatment SF4 could not only significantly regulate the effectiveness of soil nutrients, but also promote the effective accumulation of biomass of Leymus chinensis in sand land, therefore, it was the best application levle of decarbonized gasification slag-based soil conditioner. [ABSTRACT FROM AUTHOR]

Published

2024

163. BLEI: Research on a Novel Remote Sensing Bare Land Extraction Index.

Author

He, Chaokang, Wang, Qinjun, Yang, Jingyi, Xu, Wentao, and Yuan, Boqi

Subjects

*LAND cover, *REMOTE sensing, *SURFACE of the earth, *ENVIRONMENTAL research, *SANDY soils

Abstract

Bare land, as a significant land cover type on the Earth's surface, plays a crucial role in supporting land-use planning, urban management, and ecological environmental research through the investigation of its spatial distribution. However, due to the diversity of land-cover types on the Earth's surface and the spectral complexity exhibited by bare land under the influence of environmental factors, it is prone to confusion with urban and other land features. In order to extract bare land rapidly and efficiently, this study introduces a novel bare land extraction index called the Bare Land Extraction Index (BLEI). Then, considering both Ganzi Tibetan Autonomous Prefecture and Urumqi, China as the study areas, we compared BLEI with three presented indices: the Bare-soil Index (BI), Dry Bare Soil Index (DBSI), and Bare Soil Index (BSI). The results show that BLEI exhibits excellent efficacy in distinguishing bare land and urban areas. It gets the most outstanding accuracy in bare land identification and mapping, with overall accuracy (OA), kappa coefficient, and F1-score of 98.91%, 0.97, and 97.89%, respectively. Furthermore, BLEI is also effective in distinguishing bare land from sandy soil, which can not only improve the mapping accuracy of bare land in soil-deserted areas but also provide technological support for soil research and land-use planning. [ABSTRACT FROM AUTHOR]

Published

2024

164. Use of municipal solid waste incineration (MSWI) bottom ash as a permeable subgrade material: An experimental and mechanism study.

Author

Angran Tian, Yu Zhou, Yuru Chen, Deming Kan, Yanling Lu, and Qiang Tang

Subjects

*SOLID waste, *WASTE treatment, *INCINERATION, *FLY ash, *ADSORPTION capacity, *SHEAR strength, *SANDY soils

Abstract

As a traditional method of waste treatment, municipal solid waste incineration (MSWI) has become one of the main methods of urban waste treatment. However, as a byproduct of MSWI, a large amount of MSWI bottom ash is not reused in current practice. This study innovatively posits MSWI bottom ash as an eco-friendly adsorbent rather than a pollutant, exploring its potential application as a permeable subgrade material. The results reveal that MSWI bottom ash exhibits promising properties to serve as a permeable subgrade material to achieve the permeability and improve the sustainability for subgrade. Due to the arrangement of its particles, it shows excellent performance in shear strength and permeability, which are comparable to or surpass those of sandy soils. The average pore width of 14.200 nm allows heavy metal substances to be encapsulated within the matrix, significantly reducing their leachability, thereby aligning with environmental friendliness standards. Its adsorption capacity is about 6.60 mg/g, and the adsorption capacity per volume is 3.66 times and 2.04 times that of fly ash and clay, respectively. The mechanism analysis shows that the adsorption process is monolayer heterogeneous adsorption. This paper presents a novel perspective on reusing MSWI bottom ash and provides evidence supporting its effective utilization as a permeable subgrade material, offering substantial environmental benefits through enhanced adsorption ability. Implications: Municipal solid waste incineration (MSWI) is a common method for municipal solid waste treatment, while the MSWI bottom ash is often not reused. This paper explored the explores the feasibility of using MSWI bottom ash as a permeable road base material. The results show that the particle arrangement enables excellent shear strength and permeability, comparable to sandy soil. It meets safety requirements for the leaching of heavy metals and acts as an adsorbent for pollutants leaching from permeable pavements. Furthermore, the mechanisms underlying these behaviors of MSWI were confirmed by microstructural and mineralogical analyses. These indicate that MSWI bottom ash has great potential as a permeable road base material. This paper provides a clear understanding of the physical, mechanical and environmental properties of MSWI bottom ash, which can promote its reuse in practice. [ABSTRACT FROM AUTHOR]

Published

2024

165. N2O consumption, uptake, and microbial reduction processes in flooded sandy loamy paddy soils.

Author

Wang, Wei, Li, Kun, Li, Jun, Zhong, Jinmei, Xia, Lei, Chen, Wenqin, Li, Zhaohua, and Wang, Ling

Subjects

*LAKE sediments, *SOILS, *SANDY soils, *NITROUS oxide, *SOIL depth

Abstract

Sandy loamy soils are widely distributed in fluvial floodplains and experience flooding events frequently, resulting in a large amount of nitrous oxide (N2O) emissions. This case is more serious when the soil use is changed to paddies. It is of great significance to figure out the N2O consumption and its influencing factors in sandy loamy paddy soils to mitigate N2O emissions. In this study, three sandy loamy paddy soils (0–5 cm) originated from lake deposits were selected (S1, S2, and S3) as objectives. A certain concentration of exogenous N2O was added at the bottom of the flooded soil column to monitor the dynamics of N2O and nitrogen (N2) on the soil surface. Total N2O consumption, N2O uptake, and N2 production were quantified, and the abundance of nitrous oxide reductase genes (nosZI, and nosZII) and other soil properties (ammonium‐nitrogen, nitrate‐nitrogen, and dissolved organic carbon [DOC] content) were analyzed. The results showed that the sandy loamy paddy soil column with a depth of 0–5 cm could intercept more than 95% of the exogenous N2O under the flooded anaerobic condition, indicating that the three sandy loamy paddy soils all had extremely strong N2O consumption capacities. And the increment of N2 accounted for 68.73%–76.09% of the total N2O consumption, which had a stronger relationship with the increase of nosZI gene abundance than nosZII gene. In addition, the total N2O consumption and N2 increment of S1 and S3 soils were significantly higher than those of S2 soil. This difference was mainly related to soil organic matter content, total nitrogen content, DOC consumption, and the increase of nosZI gene abundance (p < 0.05). The strong N2O consumption potential of sandy loamy soils can provide feasible solutions for regulating N2O emissions in a wide range of similar environments in fluvial floodplains. Core Ideas: Over 95% of N2O in 5‐cm‐soil depth was consumed by flooded sandy loamy paddy soils.The microbial reduction of N2O to N2 is the main pathway of N2O consumption.N2O consumption and N2 increment dominated by nosZI‐containing microorganisms. [ABSTRACT FROM AUTHOR]

Published

2024

166. A Properly Chosen Rate of NPK Fertilizers Has a Positive Effect on C Sequestration in Sandy Soils in the Conditions of a Changing Climate.

Author

Šimanský, Vladimír, Jonczak, Jerzy, Horváthová, Jarmila, and Juriga, Martin

Subjects

*SANDY soils, *SOIL management, *SANDY loam soils, *FERTILIZERS, *SOIL structure, *TROPICAL cyclones

Abstract

Soil organic carbon (SOC) plays a significant role in climate change. Its content can be modified by soil management practices, however, the effect of mineral fertilization on SOC is not clear. For this reason, a long-term effect of gradually increasing rates of NPK fertilizers on changes in soil organic carbon (SOC) in bulk soil and in water-stable aggregates (WSA) in soils with sandy loam and loamy sand texture at two experimental sites (Skierniewice, Poland, and Dražovce, Slovakia) was quantified. In both sites, soil samples were collected from the following treatments: NF – no fertilization, NPK1 and NPK2 – 1st level and 2nd level of NPK fertilization, respectively. The results showed that 100-year long application of NPK1 increased total carbon (TC) and SOC content by 24%, while NPK2 decreased it by 5% compared to NF at the Skierniewice site. The content of water-stable macroaggregates (WSAma) increased because of NPK application. In NPK1, the content of WSAma was higher and the content of water-stable microaggregates (WSAmi) was lower than in NPK2 or NF. However, as a result of NPK application, the content of agronomically favorable WSAma in size fraction 0.5–3 mm was reduced by 8 and 24% in NPK1 and NPK2, respectively, compared to NF. Overall, SOC in WSAma was lower than in bulk soil. The SOC in WSAma in NF, NPK1 and NPK2 treatments was 6.51, 7.77 and 5.89 g.kg−1, respectively. Similar tendency of SOC in WSAma 0.5–3 mm was observed (NF: 6.12 g.kg−1, NPK1: 7.35 g.kg−1, and NPK2: 6.88 g.kg−1). The SOC in WSAmi in NF, NPK1 and NPK2 was 8.33, 7.39 and 7.24 g.kg−1, respectively. At Dražovce site, TC content decreased significantly due to the graded rates of NPK, not because of SOC mineralization but as a result of carbonate dissolution for a period of 14 years. The carbonate content decreased from 20 g.kg−1 in NF to 6.5 g.kg-1 in NPK1 and 3.0 g.kg-1 in NPK2, while SOC did not change significantly: (NF: 23.8 g.kg−1, NPK1: 25.9 g.kg−1, and NPK2: 23.4 g.kg−1). In NPK1, the WSAma content was reduced significantly when compared to NPK2 and NF treatments. No significant difference was observed between NF and NPK2. On the contrary, the content of WSAma 0.5–3 mm significantly increased when compared to NF and NPK1. No difference was observed between NF and NPK1. Lower SOC content was found in WSA than in the bulk soil. Overall, higher SOC content was observed in WSAma when compared with WSAmi. The application of NPK1 and NPK2 increased SOC in WSAma as well as in WSAma 0.5–3 mm. The effect was more significant in NPK1 than NPK2 treatments when compared to NF. [ABSTRACT FROM AUTHOR]

Published

2024

167. A rigorous analytical approach to predicting the load–settlement behavior of axially loaded piles embedded in sands incorporating the SANISAND model.

Author

Pang, Li, Jiang, Chong, and Zhang, Chaoyang

Subjects

*SANDY soils, *SAND, *ORDINARY differential equations, *INITIAL value problems, *AXIAL loads, *SOIL mechanics, *SAND waves

Abstract

The paper presents a rigorous analytical approach to predicting the load–settlement behavior of axially loaded piles embedded in sandy soils, adopting the advanced SANISAND model. The problem of the soil state around the pile during loading is formulated as a system of first-order ordinary differential equations, which can be solved as an initial value problem. The derived load–settlement (t–z) curve is then implemented into the load-transfer method to determine the pile's load–settlement behavior in sands and the deformation mechanism of the soil around the pile during axial loading. To verify the proposed analytical approach, a FEM simulation is performed with a user-defined subroutine, demonstrating its capacity to capture the dilatancy behavior of sands as the pile moves downwards. Additionally, a parametric analysis is conducted to assess the influence of the initial void ratio on the stress–strain relationship of the sandy soil around the pile during the loading process. The proposed analytical approach is also compared with a well-established finite-element model and a centrifuge test. The results indicate that the present approach can well predict the elastoplastic load–settlement response of the pile and reflect important phenomena observed from pile tests. [ABSTRACT FROM AUTHOR]

Published

2024

168. Strength and Fracture Properties of Sandy Subgrade Soil Treated with Sodium Polystyrene Sulfonate.

Author

Huang, Jianxin, Grajales, Javier A., Akula, Pavan, Little, Dallas N., Kim, Yong-Rak, and Rushing, John F.

Subjects

*SANDY soils, *SOIL conditioners, *FRACTURE strength, *POLYMER solutions, *FRACTURE toughness, *POLYSTYRENE

Abstract

Organic polymers have been extensively studied over the last decades, and most of the research focused on the mechanical performance of the soils treated with polymer at different dosages without addressing the effects of the unique polymer characteristics such as molecular weight and concentrations of polymer solutions. This paper investigates an anionic polyelectrolyte, sodium polystyrene sulfonate (PSS) as a soil stabilizer. The effects of the molecular weight of PSS, concentrations of PSS solutions, and the dosages on the strength of a siliceous sandy subgrade soil are examined. Fracture toughness of the PSS-treated soil is determined and discussed based on semicircular bending test. Three molecular weights (1,000,000, 200,000, and 70,000 g/mol) along with solution concentrations of 10%, 17%, 23%, and 30% by weight are considered. The dosages of PSS solutions at 2%, 4%, 6%, and 8% by weight of dry soil are discussed. All the dosages studied showed strength improvement of the sandy soil that increased with concentrations of the PSS solutions as well as the increasing dosages. PSS with the highest molecular weight performed the best among all three molecular weights. The addition of the organic polymer also improved the fracture toughness of the soil, indicating better resistance to crack propagation. The stabilization mechanism in terms of particle linkage and aggregation morphology are examined using scanning electron microscope. Aggregation of the fine soil particles and binding between the fine and coarse soil grains are observed and discussed, which contribute to the improvement of mechanical strength of the soil. [ABSTRACT FROM AUTHOR]

Published

2024

169. Investigations of Soil Models Used to Study Soil Base Liquefaction.

Author

Sidorov, V. V. and Le, Duc Anh

Subjects

*SOIL liquefaction, *CLAY soils, *EARTHQUAKE zones, *SOILS, *SANDY soils

Abstract

Evaluating the liquefaction capacity of saturated loose sandy and clayey soils is an important task to be completed in the course of implementing new construction projects in seismic areas. This article addresses the main characteristics and input parameters of three soil models, including HS small, UBC3D-PLM, and PM4Silt. The behavior of the "soil base–pile foundation–structure" system is examined by using these models to simulate the soil behavior during an earthquake. The results demonstrate the main differences between these models and draw attention to the importance of the choice of a soil model for seismic analysis, particularly when soil liquefaction is considered. [ABSTRACT FROM AUTHOR]

Published

2024

170. EFFECT OF POTASSIUM SOURCES ON SOME POTATO CULTIVARS GROWN IN SANDY SOIL BY USING PIVOT IRRIGATION SYSTEM.

Author

Mousa, T. A. E., Samar, A. Bardisi, Esmail, H. E. M., and Zayed, G. A.

Subjects

*PLANT growth, *POTASSIUM silicate, *SANDY soils, *TUBERS, *SUMMER, *POTATOES

Abstract

Study was carried out during two successive summer seasons of 2021 and 2022 at private filed in El-Salhyia El-Gadida District,Sharkia Governorate, to study response of some potato cultivars to potassium sources as foliar application under sandy soil conditions using pivot irrigation system .This experiment included 25 treatments, which were the combinations between five potato cultivars (Spunta, Santana, Cara, Lady Rosetta and Hermes) and four potassium sources treatments, i.e. spraying with potassium silicate( KSil, (potassium citrate (KCit,)potassium folvate( KF) and potassium thiosulpahte( KTS) as well as control (without spraying). These treatments were arranged in a split plot design with three replicates. Potato cultivars were randomly arranged in the main plots and potassium sources were randomly distributed in the sub plots .Spraying Cara cultivar with KCit increased number of tubers/ plant and total yield/ hectare, whereas spraying Spunta cultivar with KCit increased average tuber weight in both seasons .While, spraying Hermes cultivar with KSil as foliar spray increased DM, starch and total carbohydrates in tubers .Spunta cultivar with water only increased total sugars in tubers .In addition, the fertilization of Cara cultivar with KCit as a foliar application recorded a relative increase in the total yield of tubers amounting to about 72.50% as an average of the two seasons compared to the same cultivar without. [ABSTRACT FROM AUTHOR]

Published

2024

171. Testing strategies to enhance transplant success under stressful conditions at a tidal marsh restoration project.

Author

Pausch, Rachel

Subjects

*SALT marshes, *PSYCHOLOGICAL stress, *SALT marsh plants, *CONFIGURATION management, *SEA level, *SANDY soils

Abstract

Tidal marsh restoration is becoming an increasingly common tool to plan for future sea level rise. Subsided marshes' elevation can be restored through sediment additions, which may necessitate the reestablishment of vegetation. Understanding key actions to increase vegetation cover at areas that remain persistently bare following elevation restoration is a critical component of a project's long‐term success. Dominant species can shape ecosystem function, as well as ameliorate stressful environments. We transplanted the dominant species, Salicornia pacifica, into bare areas of a restored tidal marsh in central California, United States, 3 years following a sediment addition. We tested salt hardening of plants before transplanting, targeted irrigation, transplant size, and planting configuration to identify management actions that could help vegetation persist in the most stressful areas of the high marsh. Weekly targeted irrigation until the first rains began was critical for small plant survivorship. We found that larger plants had increased survivorship and contributed higher amounts of growth and cover but did not facilitate the performance of nearby smaller plants. After 2 years, we determined that using lone, larger plants was more cost‐effective than multiple smaller plants at our tidal marsh. However, performance was highly site‐specific with dramatically less growth at a drier site with sandier soil. Our results highlight the importance of identifying site‐specific restoration strategies that either ameliorate or help plants tolerate stressful conditions, contributing to the continued success of tidal marsh restoration for climate resilience. [ABSTRACT FROM AUTHOR]

Published

2024

172. Strength and Kaolin Nucleation in Biotreated Coarse Sand.

Author

Xiao, Yang, Ma, Guoliang, He, Xiang, Liu, Hanlong, and Zaman, Musharraf

Subjects

*KAOLIN, *SANDY soils, *COMPRESSIVE strength, *NUCLEATION, *SAND, *CALCIUM carbonate

Abstract

Microbially induced carbonate precipitation (MICP) is an effective method for stabilizing sandy soil. However, this method is not effective for coarse sands. A kaolin-nucleating method was proposed in this study to improve the biotreatment of coarse sands. We comprehensively studied the effect of the kaolin concentration, the volume ratio of the bacterial solution to the cementation solution, the grouting interval between two slurry injections, and the bacterial density on the compressive strength of biotreated coarse sands. We found that the kaolin concentration and the bacterial density are positive factors for enhancing the compressive strength and there are also suitable values for the volume ratio of the bacterial solution to the cementation solution and the grouting interval to improve the biotreatment when other factors are specified. Interestingly, the biotreated condition for the specimen with the maximum strength was identical to that with the maximum ratio of the precipitate volume to the specimen void but different from that with the maximum calcium carbonate content. [ABSTRACT FROM AUTHOR]

Published

2024

173. RESPONSE OF YIELD AND HEAD QUALITY OF LETTUCE TO NITROGEN FERTILIZATION AND SEAWEED EXTRACT FOLIAR APPLICATION UNDER NEW VALLEY CONDITIONS.

Author

Ali, Mohamed A. M.

Subjects

*LETTUCE, *UREA as fertilizer, *MARINE algae, *SANDY soils, *VITAMIN C, *NITROGEN, *DISTILLED water

Abstract

Two field experiments were conducted at the Agricultural Research Farm of the Faculty of Agriculture, New Valley University, New Valley Governorate, Egypt, during the two successful seasons of 2022/2023 and 2023/2024 to study the effect of nitrogen fertilization at rates of 45, 60, 75, and 90 kg N/feddan in the form of urea and foliar spraying with seaweed extract (SWE) at concentrations of 2, 4, and 6 ml/l beside untreated control and their interactions between them on growth, productivity, nitrogen use efficiency (NUE), and head quality of lettuce cv. Dark Green, grown in sandy soil. The results clearly demonstrated that the interaction between fertilizing lettuce plants with 90 kg N/fed. and foliar spraying with SWE at 6 ml/l significantly enhanced plant growth parameters, leaf pigments, i.e., chlorophyll a, b, and carotenoides, head traits such as head diameter, head fresh weight, dry matter percentage in leaves, and the total yield (ton/fed.), leaves content of N, P, and K, total soluble solids, and vitamin C in both seasons. Moreover, this interaction treatment scored relative increases about 65.84% acreage of the two seasons over the interaction between fertilizing plants with 45 kg N/fed. and foliar spraying with distilled water (control plants). As for NUE and nitrate concentration in lettuce plants, fertilizing plants with 45 kg N/fed. and foliar spraying with SWE at 6 ml/l record the maximum NUE (average two seasons, 286.35 kg yield/one kg N) and the minimum nitrate concentration in leaves (average two seasons, 174.00 ppm). Despite the use of a high rate of nitrogen fertilization (90 kg/fed.) and spraying lettuce plants with SWE at 6 ml/l, which recorded the maximum yield per feddan, the percentage of nitrate (295.15 average two seasons) that was estimated in the leaves did not reach the maximum permissible limit of nitrates (2 g/kg DW). [ABSTRACT FROM AUTHOR]

Published

2024

174. The Estimation of Shear Wave Velocity for Shallow Underground Structures in the Central Himalaya Region of Nepal.

Author

Thapa, Umesh Jung, Paudel, Satish, Bhusal, Umesh Chandra, Ghimire, Hari, and Khadka, Shyam Sundar

Subjects

UNDERGROUND construction, SHEAR waves, TUNNEL design & construction, SANDY soils, SOIL classification

Abstract

A subsurface investigation was conducted to assess the suitability of a site for potential tunnel construction, focusing on the determination of shear wave velocities (Vs) in subsurface materials. This study employed three distinct methods to analyze Vs in weathered soft rock: drilling mechanism, multichannel analysis of surface waves (MASW), and microtremor array measurement (MAM). Through the utilization of MASW and MAM, empirical relationships were established, enabling the determination of Vs based solely on soil type and depth, offering a practical alternative to the limitations of SPT N-Value, particularly when exceeding 50 blows. The comparison of Vs values obtained from these methods revealed a close alignment between empirical techniques and MASW/MAM, which proved to be cost-effective and an efficient alternative to drilling for comprehensive underground structure assessments. The reliability of MASW was further underscored through its comparison with existing empirical methods. Moreover, the empirical approach demonstrated its efficacy in predicting velocities in weathered soft rock within the Central Himalayan region of Nepal, thus enhancing the feasibility study of underground structures. Lastly, this study proposed a Vs-Depth correlation specifically tailored for highly weathered meta-sandstone bedrock resulting in clay and sandy soils. [ABSTRACT FROM AUTHOR]

Published

2024

175. Microtomographic Measurements of Total Air‐Water Interfacial Areas for Soils.

Author

Brusseau, Mark L., Araujo, Juliana B., Narter, Matt, Marble, Justin C., and Bigler, Matt

Subjects

X-ray computed microtomography, SOILS, SAND, SANDY soils, GLASS beads

Abstract

Synchrotron X‐ray microtomography (XMT) was used to measure total air‐water interfacial areas (Aaw) as a function of water saturation (Sw) for several soils that comprise a range of physical and geochemical properties. Measurements were also conducted for glass beads and quartz sands for comparison. Apparent near‐linear Aaw‐Sw relationships are observed for the three sands and the three sandy soils. In contrast, the measured interfacial areas for two soils that contain greater proportions of silt and clay are strongly nonlinear functions of water saturation. The greater degree of nonlinearity observed for these two soils is due to their much greater particle‐size distributions (i.e., uniformity coefficients) and their concomitant greater range in pore sizes. Interfacial areas determined with the thermodynamic method were used to benchmark the XMT measurements. XMT‐measured interfacial areas compare well to the thermodynamic‐determined values for the sands and sandy soils. In contrast, the XMT‐measured interfacial areas for the two soils with larger particle‐size distributions are not fully congruent with the thermodynamic‐determined values. Both of these soils have large fractions of pore space comprising nominal pore diameters smaller than the resolution of the XMT imaging. These results suggest that air‐water interfacial area may not always be fully characterized by standard XMT for soils with large particle‐size distributions. Plain Language Summary: High‐resolution pore‐scale imaging is conducted for several sands and soils to examine the relationship between the magnitude of air‐water interfacial area and water saturation as well as to evaluate the effectiveness of the imaging method. Key Points: X‐ray microtomography (XMT) measurements of air‐water interfacial area are reported for soilsThe relationship between air‐water interfacial area and water saturation is nonlinearBenchmarking results indicate that XMT may not measure all interfacial area for soils with higher silt and clay contents [ABSTRACT FROM AUTHOR]

Published

2024

176. Estimating the Thermal Conductivity of Unsaturated Sand.

Author

Liu, Xuejun, Gao, Yucong, and Li, Yanjun

Subjects

THERMAL conductivity, SAND, HEAT conduction, SANDY soils, NUMERICAL analysis, HEAT transfer

Abstract

A modified parallel model for estimating the thermal conductivity of unsaturated sand was proposed in this study. The heat conduction in the solid phase of sand depends mainly on the form of contacts between solid particles, while water bridges at the particle contacts increase the contact areas and remarkably enlarge the transfer paths of heat conduction in sandy soils. However, the thermal conductivity of the solid particle itself (λs) cannot describe the influence of the form of contacts and water bridges on heat conduction through the solid phase. In this study, the equivalent thermal conductivity of the solid particle (λes) was presented which reflected the influence of the form of contacts and water bridges between particles under dry conditions or a low degree of saturation, respectively. The relationship between λes and degree of saturation was described by hyperbolic expression. The modified model was calibrated using measured values of the thermal conductivity from published datasets, including those for 41 types of sand from 15 studies. Numerical analyses of the temperature field of the energy pile were performed and validated against laboratory measurements. The results illustrated that the modified model was more applicable than the original model for predictions of sand thermal conductivity. [ABSTRACT FROM AUTHOR]

Published

2024

177. Improving cotton yield and fiber quality in different tropical soils with boron fertilization.

Author

Cordeiro, Luis Fernando dos Santos, Malenowtch, João Vitor Cordeiro, Cordeiro, Carlos Felipe dos Santos, Detoni Filho, José Ari Castilho, Furlani Júnior, Enes, and Ferrari, Samuel

Subjects

COTTON fibers, CLAY soils, SANDY soils, SOILS, BORON

Abstract

Cotton (Gossypium hirsutum L.) is responsive to boron (B) fertilization when there is low soil availability, but the best source and rate to be used and whether this response is dependent on soil texture are still unknown. This study aimed to adjust boron fertilization for cotton as a function of the production environment and B source used. Two field experiments were conducted in the 2020/2021 season in Chapadão do Sul, MS (clayey soil—adequate B content) and Dracena, SP (sandy soil—low B content), Brazil. Treatments consisted of B sources (ulexite [low solubility], borax pentahydrate [BP] [intermediate solubility], and boric acid [BA] [high solubility]), and B rates (0, 1, 2, 4, and 6 kg ha−1) applied to the soil at 25 days after plant emergence. In sandy soil with low B content, application of 2 (high and medium solubility sources) and 4 kg B ha−1 (low solubility source) improved fiber yield between 10% (210 kg ha−1 fiber) and 28% (555 kg ha−1), respectively, as well as micronaire index, strength, elongation, uniformity, and short fibers. Application of B greater than 4 kg ha−1 via soluble sources reduced (between 9% (175 kg ha−1)—BP and 14% (257 kg ha−1)—BA) fiber yield only in sandy soil. When B content in the soil is adequate, B fertilization did not improve yield, but increased fiber strength (4%—1.1 g tex−1) and reduced the short fiber index (16%) by applying 1 kg B ha−1, regardless of the source used. The highest fiber yields were obtained with leaf B contents between 12 and 17 mg kg−1 (sandy soil) and 25 and 27 mg kg−1 (clayey soil). We recommend applying 2 kg B ha−1 (solubility sources) and 4 kg B ha−1 (low solubility source) in sandy soils with low B content to improve yield and fiber quality, and 1 kg B ha−1 in clayey soil with adequate B content to improve fiber quality and replace B amounts removed through harvesting. Core Ideas: Boron fertilization in sandy soils increased fiber yield by 210–555 kg ha−1.There are no effects of B fertilization in clayey soils on fiber yield, but there are improvements in fiber quality.Rates greater than 4 kg ha−1 of B via soluble sources reduce fiber yield in sandy soils.Cotton grown in clayey soil is more resistant to B toxicity. [ABSTRACT FROM AUTHOR]

Published

2024

178. Enhancing the Ability of the Square Footing to Resist Positive and Negative Eccentric-inclined Loading Using an Inclined Skirt.

Author

Alhalbusi, Ghazwan Salah and Al-Saidi, A'amal A. H.

Subjects

SKIRTS, SANDY soils, DISPLACEMENT (Psychology), SHALLOW foundations

Abstract

Copyright of Journal of Engineering (17264073) is the property of Republic of Iraq Ministry of Higher Education & Scientific Research (MOHESR) and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

179. Effect of Moisture Content and Wet–Dry Cycles on the Strength Properties of Unsaturated Clayey Sand.

Author

Wang, Chuan, Yang, Weimin, Zhang, Ning, Wang, Senwei, Ma, Chuanyi, Wang, Meixia, and Zhang, Zhiyuan

Subjects

SANDY soils, CLAY soils, SHEAR strength, SOIL moisture, SAND, SOIL wetting

Abstract

Based on the actual situation of the project on the Weihai–Yanhai Expressway section of Rongwu Expressway, the effects of water content change and the dry–wet cycle on the mechanical behavior of unsaturated clayey sandy soil were analyzed in this study. In this study, ventilated undrained triaxial shear tests were carried out on unsaturated clayey sandy soils with different water contents (6%, 8%, 10%, 12%, 14% and 16%). Concurrently, the soil samples were subjected to three distinct wet and dry cycle pathways (2~22%, 2~12%, and 12~22%) to gain an understanding of how the mechanical features of the soil changed under the different conditions. The test findings demonstrate that when the water content increases, the unsaturated clayey sandy soil's cohesiveness and shear strength diminish. The strength of shear decline exhibits a pattern of first being quick, followed by sluggish. The strength of shear and cohesiveness of clayey sandy soil declined under the influence of the dry and wet cycles, with the first cycle primarily affecting variations in cohesiveness and strength of shear. Furthermore, the strength of shear and cohesiveness of clayey sandy soil diminish more with increasing wet and dry cycle amplitude and upper water content limits. Lastly, the drying shrinkage and hygroscopic expansion of clay particles in clayey sandy soils during wet and dry cycles are not significant, resulting in less structural damage and deterioration of the mechanical properties of the soils. The study's findings have a significant impact on the durability of roadbeds made of unsaturated clayey sandy soil in both wet and dry situations. [ABSTRACT FROM AUTHOR]

Published

2024

180. PERFORMANCE OF MEHLICH-1 AND MEHLICH-3 EXTRACTORS IN QUANTIFYING PHOSPHORUS IN SOILS FERTILIZED WITH LIQUID SWINE MANURE.

Author

Arruda-Oliveira, João C., Silva, Josimar B., Miranda, Emerson S., Ribeiro-Santos, Jholian M., and Weber, Oscarlina L. S.

Subjects

SWINE manure, PHOSPHORUS in soils, PHOSPHATE fertilizers, SANDY soils, SOIL testing

Abstract

Copyright of BIOAGRO is the property of Revista BIOAGRO and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

181. Sandy soil reclamation technologies to improve crop productivity and soil health: a review.

Author

Musei, Sylus Kipngeno, Kuyah, Shem, Nyawira, Sylvia, Ng'ang'a, Stanley Karanja, Karugu, Winifred N., Smucker, Alvin, and Nkurunziza, Libère

Subjects

SANDY soils, SOIL productivity, SOIL moisture, SODIC soils, CARBON in soils, SOIL amendments

Abstract

Sandy soils are characterized by low soil moisture content and nutrient retention due to high permeability, limiting crop productivity and threatening food security in arid and semi-arid regions worldwide. Various reclamation technologies have been developed to address these challenges, but their effectiveness has not been comprehensively evaluated. This systematic review evaluated the performance of 42 sandy soil reclamation technologies reported in 144 studies from 27 countries that met specified selection criteria. Performance was evaluated based on response ratio (RR) of aboveground biomass and grain yield, as indicators of productivity, and soil moisture content and soil organic carbon (SOC), as indicators of soil health. The 42 technologies employed four main soil amendments: biochar, organic amendments, organic amendments combined with biochar, and soft rock. Overall, all technologies increased productivity and improved soil health. Biochar application was found to be the most effective technology, increasing grain yield by 51.6%, aboveground biomass by 67.4%, soil moisture content by 17.3%, and SOC by 74.2%. Soft rock application increased grain yield by 20.3%, aboveground biomass by 27.6%, soil moisture content by 54.5%, and SOC by 12.8%. Organic amendments increased grain yield by 48.7%, aboveground biomass by 45.6%, soil moisture content by 20.8%, and SOC by 36.7%. However, the combination of biochar and organic amendments showed lower improvements, with increases of 25.4%, 15.6%, 1.3%, and 25.4% for grain yield, aboveground biomass, soil moisture content, and SOC, respectively. Our conclusion is that the findings provide strong evidence that sandy soil reclamation technologies can significantly improve crop productivity and food security. Considering the variability in technologies responses across continents, there is need for further research to determine the optimal technology for specific locations, crops, and management practices. [ABSTRACT FROM AUTHOR]

Published

2024

182. Effects of arbuscular mycorrhizal fungi on the reduction of arsenic accumulation in plants: a meta-analysis.

Author

Shangyan Hao, Ye Tian, Zhiqing Lin, Linzhi Xie, Xinbin Zhou, and Bañuelos, Gary S.

Subjects

VESICULAR-arbuscular mycorrhizas, SOIL texture, ARSENIC, SANDY soils, PLANT-soil relationships

Abstract

Arsenic (As) accumulation in plants is a global concern. Although the application of arbuscular mycorrhizal fungi (AMF) has been suggested as a potential solution to decrease As concentration in plants, there is currently a gap in a comprehensive, quantitative assessment of the abiotic and biotic factors influencing As accumulation. A meta-analysis was performed to quantitatively investigate the findings of 76 publications on the impacts of AMF, plant properties, and soil on As accumulation in plants. Results showed a significant dose-dependent As reduction with higher mycorrhizal infection rates, leading to a 19.3% decrease in As concentration. AMF reduced As(V) by 19.4% but increased dimethylarsenic acid (DMA) by 50.8%. AMF significantly decreased grain As concentration by 34.1%. AMF also improved plant P concentration and dry biomass by 33.0% and 62.0%, respectively. The most significant reducing effects of As on AMF properties were seen in single inoculation and experiments with intermediate durations. Additionally, the benefits of AMF were significantly enhanced when soil texture, soil organic carbon (SOC), pH level, Olsen-P, and DTPA-As were sandy soil, 0.8%-1.5%, ≥7.5, ≥9.1 mg/kg, and 30-60 mg/kg, respectively. AMF increased easily extractable glomalin-related soil protein (EE-GRSP) and total glomalin-related soil protein (T-GRSP) by 23.0% and 28.0%, respectively. Overall, the investigated factors had significant implications in developing AMF-based methods for alleviating the negative effects of As stress on plants. [ABSTRACT FROM AUTHOR]

Published

2024

183. Influence of Biochar Application Rate, Particle Size, and Pyrolysis Temperature on Hydrophysical Parameters of Sandy Soil.

Author

Vitková, Justína, Šurda, Peter, Lichner, Ľubomír, and Výleta, Roman

Subjects

BIOCHAR, HYDRAULIC conductivity, SANDY soils, PYROLYSIS, CONTACT angle, PLANT-water relationships

Abstract

Sandy areas occupy a huge amount of land worldwide, but due to their characteristics, they are mostly low in fertility and low in organic matter. Sandy soils have coarse texture, high saturated hydraulic conductivity, low soil organic carbon, and poor aggregate stability and water retention capacity; therefore, it is necessary to add organic additives to them. The objective of this study was to assess the effect of particle size and application rate of biochar (BC) produced under different pyrolysis temperatures on the porosity P, available water content for plants AWC, saturated hydraulic conductivity Ks, and contact angle CA of sandy soil. The results show that an application of BC to sandy soil significantly increased AWC by 76–168%, CA by 252–489%, P by 6–11%, and significantly reduced Ks by 37–90%. Statistical analysis of the effect of three examined factors (BC application rate, particle size, and pyrolysis temperature) revealed that P, AWC, and Ks were affected by all three factors, while CA was affected only by BC application rate and particle size. The statistically significant interaction between the two factors was found for P (temperature × rate and size × rate), AWC (temperature × size), and Ks (size × rate). Statistically significant interaction among the three factors was not found for any hydrophysical parameter. The application of BC to amend sandy soils can be seen as a strategy to mitigate drought conditions and to reduce the amount of irrigation, saving water. Further investigations are needed with regard to the BC application under climate conditions with long hot and dry periods, which may promote soil water repellency. [ABSTRACT FROM AUTHOR]

Published

2024

184. Clonal propagation, scale dependent assembly, and nucleation drives natural regeneration in a restinga sandy coastal plain.

Author

Matias, Lidiane, Demetrio, Guilherme Ramos, da Silva, Milena Dutra, and Moura, Flávia

Subjects

COASTAL plains, SANDY soils, BINOMIAL distribution, SPECIES diversity, ECOLOGICAL succession, URBAN renewal, ANIMAL species

Abstract

On the sandy coastal plains, environmental filters that limit seedling establishment and survival create a naturally heterogeneous landscape, formed by vegetation patches inserted in a matrix of bare sandy soil. The succession processes in these ecosystems depend on some pioneer species that facilitate the recruitment and survival of other species. Here, we evaluated the spatial pattern and changes of vegetation patches of restinga (i.e., coastal sandy plain vegetation) over one decade (2011–2021). The research was carried out in Alagoas State, Northeast of Brazil. We considered as patches the vegetation islands inserted in a matrix of bare sandy soil and applied methodologies of photointerpretation. Landscape metrics included patch area, edge, shape, and core area. To test the effect of landscape metrics on species occurrence and species richness per patch, we applied generalized linear models (GLM) with binomial and quasi‐Poisson distributions, respectively. We used the "betapart" package to evaluate the importance of turnover and nestedness as drivers of beta diversity among patches. Our data indicate that a key plant (Myrciaria floribunda), which can propagate by root suckers, initiates a succession process, creating regeneration nuclei, which seem to follow a deterministic succession pattern until the patch reaches 10 m2 in area. In the successional sequence, the patches grow and coalesce with neighboring patches. Species richness of patches presented an unimodal response to patch size. Overall, there is a greater contribution of species turnover to among‐patch beta diversity. However, for patches smaller than 10 m2, beta diversity was mostly driven by nestedness, reflecting a process of species addition to the growing patches. The succession pattern found in the study area should be considered for the formulation of nature‐based restoration models, expected to be more efficient and effective for ecosystems with similar environmental filters. [ABSTRACT FROM AUTHOR]

Published

2024

185. Developing soil conditioner composites for enhancing nitrogen mineralization to mitigate the negative effects of climate change in a sandy soil.

Author

Tóth, Florence Alexandra, Magyar, Tamás, Tamás, János, and Nagy, Péter Tamás

Subjects

*SOIL conditioners, *POULTRY manure, *SUPERABSORBENT polymers, *SANDY soils, *NITROGEN in soils

Abstract

Self-developed soil conditioner composites containing fermented chicken manure as a raw material alongside bentonite and super-absorbent polymer in different doses and combinations were tested in a 112 day long soil incubation experiment. This study aimed to determine their effects on soil N mineralization, and the changes in the amount of soil mineralized nitrogen forms, cumulative mineralized nitrogen (Nmin), and C/N ratio in a sandy soil (Lamellic Arenosol) at two different soil water holding capacity (SWHC) levels and soil layers. Potentially mineralized nitrogen (PMN), net mineralization rates (NMR), and nitrifi cation rates (NNR) were also calculated to study the effectiveness of treatments. Soil NH4-N decreased by 50-70% while NO3-N increased by 150-200% in the treated soil, so the NO3-N and NH4-N ratio changed from 1/3 to 2/1 during the incubation. Nmin gradually increased and was described by a linear tendency (R≥0.99) for both soil layers and SWHC levels. Composite treatments increased signifi cantly the PMN, and NMR values by 2-4 times and NNR values by 40-240% compared to the control. Applied composites enhanced the mineralized proportion of total nitrogen content by 2-6%. It was found that the composites were more effective at lower SWHC level and in their application layer than chicken manure alone. Overall, the developed organic-based composites are able to cope with changing soil conditions, which can help mitigate the negative effects of climatic anomalies, especially in arid areas with limited water resources by improving soil nutrient supply, thus contributing to sustainable nutrient management. [ABSTRACT FROM AUTHOR]

Published

2024

186. Influence of skidding in two mechanized tillage systems for quinoa cultivation.

Author

García-Zanabria, Roque Orlando

Subjects

*TILLAGE, *PLOWING (Tillage), *QUINOA, *SOIL compaction, *FARM tractors, *AGRICULTURE, *SANDY soils

Abstract

he mechanized tillage systems of agricultural soils for the cultivation of quinoa in the central Ecuadorian highlands are influenced by several factors, among them: the skidding that occurs in soil tillage, with different implements used both in conventional tillage and in minimum or reduced tillage, in plowing, harrowing, furrowing, which are executed for the cultivation of quinoa, without considering the slope, humidity, soil compaction and the increase in cost and time. The objective of the study was to determine the percentage of skidding in sandy textured soils for quinoa cultivation, with slope ranges from 5 to 12% with moisture contents from 13 to 18% under conventional and minimum or reduced tillage systems in plowing, harrowing, furrowing, using disk plow, chisel plow, disk harrow, furrower coupled to an agricultural tractor of 95 KW of power with assisted traction. [ABSTRACT FROM AUTHOR]

Published

2024

187. Shifts from an extensive to an intensive root nutrient‐acquisition mode with stand development of three Pinus species.

Author

Wang, Guangru, Lin, Guigang, Zhang, Yansong, Zheng, Linlin, Zeng, De‐Hui, and Lambers, Hans

Subjects

*ROOT hairs (Botany), *PINE, *PLANT exudates, *SPECIES, *SANDY soils, *NUTRIENT uptake, *PINACEAE

Abstract

Plant roots employ diverse strategies to acquire soil nutrients, including direct nutrient uptake through absorptive fine roots and root hairs, scavenging nutrients by forming symbioses with mycorrhizal fungi, and mining nutrients by releasing root exudates. However, whether these three strategies are differently coordinated among phylogenetically closely related tree species and how this coordination shifts with stand development remains largely unclear.To fill these knowledge gaps, we measured 13 root morphological, architectural, physiological and mycorrhizal traits tightly related to nutrient‐acquisition of three Pinus species (P. sylvestris var. mongolica, P. densiflora and P. tabuliformis) at young (20‐year‐old) and mature (50‐year‐old) stages planted in nutrient‐impoverished sandy soils, in Northeast China.We found that young trees had thinner absorptive fine roots and a higher specific root length than mature trees across three Pinus species, indicating that roots become morphologically less efficient in 'do it yourself' scavenging nutrients during stand development. Moreover, young stands had greater root length density and root area index, and mature stands had faster root‐exudation rates, suggesting that young stands rely more on expanding soil volumes to scavenge nutrients and mature stands depend more on root exudation to 'mine' nutrients. The three Pinus species exhibited different nutrient‐acquisition strategies at the mature stage; P. densiflora had higher root length density and root area index, and the other two Pinus species had greater ectomycorrhizal colonization rates.Synthesis. Our findings highlight that phylogenetically closely related tree species may exhibit different nutrient‐acquisition strategies and suggest a shift from an extensive nutrient‐acquisition mode depending more on absorptive fine roots to an intensive nutrient‐acquisition mode relying more on root exudation during stand development. [ABSTRACT FROM AUTHOR]

Published

2024

188. Effect of Different Nitrogen Levels on Water and Nitrate Distribution in Aeolian Sandy Soil under Drip Irrigation.

Author

Dou, Chaoyin and Sun, Yidi

Subjects

*FERTIGATION, *MICROIRRIGATION, *WATER distribution, *NITROGEN in water, *SANDY soils, *WATER levels, *SOIL moisture, *SPELEOTHEMS, *STALACTITES & stalagmites

Abstract

Understanding the distribution of water and nitrate nitrogen in the soil profile is crucial for the reasonable operation of fertigation, and it is also fundamental for controlling and regulating nitrate nitrogen in the root zone, thereby meeting a crop's requirements. The application rates of fertilizer and water directly influence this distribution of water and nitrate nitrogen. However, the effects in Aeolian sandy soil, a type of developing soil bordering deserts, remain ambiguous. In this study, field experiments for different drip fertigation treatments in Aeolian sandy soil were conducted to investigate the soil water distribution, as well as that of nitrate nitrogen. A completely randomized experimental design was implemented, encompassing three levels of irrigation amount: low (W1), medium (W2), and high (W3), and three levels of nitrogen application rate: low (F1), medium (F2), high (F3). After the completion of each irrigation treatment, soil samples were extracted at 10–20 cm intervals. The soil water and nitrate nitrogen contents in the profiles of these samples were measured. The experimental results revealed that increasing the nitrogen application rate facilitated the retention of greater amounts of water and nitrate nitrogen in the soil profile. However, with an increase in the nitrogen application rate, both soil water and nitrate nitrogen exhibited a radial tendency to move away from the drip emitter. Some moved upward and accumulated in surface soil near a ridge furrow, while some moved downward and remained in a deeper area approximately 30 cm horizontally from the emitter at depths of 40–60 cm. The uniformity of the water distribution decreased with increasing nitrogen application under low water conditions, with a reversal of this trend observed in medium and high water treatments. The effect of nitrogen application level on the uniformity of the nitrate nitrogen distribution was not significant. There was no significant correlation between the average soil water content and nitrate nitrogen content along the horizontal direction, however, a positive correlation existed in the vertical direction. In the whole profile, increasing the nitrogen application enhanced the correlation under low water conditions, but under medium and high water conditions, this trend was the opposite. This implies that, to avoid nitrate nitrogen leaching or limiting in a specific area, a moderate nitrogen application level is advisable. Under low water conditions, nitrogen application showed a positive effect on the nitrate nitrogen content, and a higher application is recommended. In cases of substantial water irrigation or rainy years, the nitrogen application rate should be decreased. [ABSTRACT FROM AUTHOR]

Published

2024

189. A Comprehensive Study on the Consequences of Gap-Graded Sands Considering the Loss of Fine Particles.

Author

Liu, Weiping, Gan, Yu, Cui, Yunwei, Huang, Faming, and Hu, Lina

Subjects

*PARTICULATE matter, *WATER leakage, *SOLUTION (Chemistry), *MATERIAL erosion, *SAND, *SANDY soils, *SAND dunes

Abstract

Water and sand leakage disasters are likely to occur during construction in water-rich sand layer areas, resulting in ground collapse. The stress-strain action characteristics of discontinuous graded sand under different internal erosion degrees, and the evolution mechanism of water and sand leakage disasters caused by the internal erosion need to be further explored. Therefore, this paper takes the discontinuous graded sand in a water rich sand layer area in Nanchang City of China as the research object. Considering the influence of different fine particle losses (0, 10%, 20% and 30%) under the internal erosion of sand, the salt solution method is used to realize the specified loss of fine particles in the internal erosion. The stress-strain behavior after the loss of fine particles due to internal erosion is studied by triaxial shear test. Meanwhile, the physical model test and PFC-CFD method are both used to study the evolution rules of water and sand leakage disaster considered the influence of internal erosion degrees. Results show that: (1) under the same confining pressure, the peak failure strength of sand samples decreases along with the increase of fine particle loss. (2) In the water and sand leakage test of saturated sand, a natural filter channel is formed above the observed soil arch. The greater the loss of fine particles, the steeper and wider the collapse settlement area. (3) The relationship between the cumulative amount of water and sand leakage and time is nonlinear. The total mass loss of sand increases along with the increase of internal erosion degree. (4) After the soil arch is formed around the damaged opening, the sand continues to converge above the soil arch under the action of water flow, resulting in the dense convergence of contact force chains. [ABSTRACT FROM AUTHOR]

Published

2024

190. Geophysical Methods Reveal Aviation Impacturbation and Inform Forensic Archaeological Recovery of Historic Aircraft Crash Sites.

Author

Chadwick, William and Palmiotto, Andrea

Subjects

*GROUND penetrating radar, *ARCHAEOLOGICAL geology, *ARCHAEOLOGICAL excavations, *HISTORIC sites, *SANDY soils, *MILITARY personnel

Abstract

This paper demonstrates the utility of ground‐penetrating radar (GPR) to inform forensic archaeology recovery efforts of missing service members from historic conflict‐related aircraft crash sites. This approach is becoming more common and improving recovery strategies by pinpointing potential subsurface anomalies prior to excavation. Two examples of recovery efforts at WWII aircraft crash sites are presented, revealing the diversity of landscape upheaval signatures that result from aircraft impacts. In both situations, the GPR successfully located feature boundaries and identified aviation impacturbation. The landscape signature varied in both cases due to factors including the trajectory and velocity of the aircraft crash and the topography of the impacted landscape. Notably, a 'halo' effect was identified in association with one crash site, revealing the force of the impact on sandy soils. Recognition of these anthropogenic signals is important to promote effective recovery strategies, thus saving time, labour and funds, particularly in historic sites where postincident taphonomic conditions have severely altered the morphology of the landscape. [ABSTRACT FROM AUTHOR]

Published

2024

191. Study on the differential disintegration mechanism of water glass cured sandy soil: analysis from the perspective of the coexistence state of gel and particles.

Author

Chen, Guoqing, Xu, Yitian, Zhang, Yan, and Yan, Ming

Subjects

*SOLUBLE glass, *HYDROTHERAPY, *SANDY soils, *SOIL testing, *DECAY rates (Radioactivity), *POROSITY, *GEOTECHNICAL engineering

Abstract

In the field of geotechnical engineering, many researchers have studied the disintegration of wet geotechnical bodies, but few have investigated the disintegration of sandy soils cured with water glass. In this study, the effects of modulus and Baume degree on the consolidation rate, particle size structure, pore size structure and gel state of sandy soils cured with water glass were investigated. The disintegration of cured specimens with different compositions was analyzed and discussed from the microscopic point of view. The results of the study show that the time required for consolidation of cured sandy soil decreased with increasing modulus and Baume degree. The Baume degree and modulus of sodium silicate affected the particle size and pore size structure of solidified soil. Due to differences in pore size and particle size structure, the disintegration of the specimens differed. For the samples with high Baume degree, their strength is high, but their water stability is poor, and the maximum disintegration degree is 95.72%. The sample with low Baume degree has low strength, but the water stability is good under the immersion condition, and the disintegration rate is less than 10%. The disintegration mechanism of solidified specimens was analyzed from the aspects of particle size, pore size structure and gel state. It is suitable to use water glass with high Baume degree in projects with dry environment and requiring high strength, while water glass with low Baume degree can be used for curing in wet environment. [ABSTRACT FROM AUTHOR]

Published

2024

192. Permeability and strength characteristics of silty sands grouted with cement and polymer.

Author

Wang, Shengnian, Hui, Honglei, Guo, Shuangfeng, Zhang, Peng, and Chen, Zewei

Subjects

*GROUT (Mortar), *PERMEABILITY, *CEMENT slurry, *SANDY soils, *SOIL permeability, *KAOLIN, *GYPSUM, *SAND, *SLURRY

Abstract

Hydrophilic polymer grouting with a particular water-to-binder ratio could block soil pores in a short time to prevent the loss of cement slurries in sandy strata in water-rich areas. Meanwhile, when combined with cement, the setting time and permeability of sandy soils could be minimized significantly. In this study, a series of indoor permeability tests, unconfined compression tests, and field grouting tests were conducted to investigate the influence of the ratio of polymer to water, the ratio of water to cement, polymer and cement content on the solidification time, setting time, impermeability effect, and compression resistance of silty sands and summarize the recommended grouting parameters of cement and polymer for the water-rich sandy stratum. The results illustrated that the recommended ratio of the primary and auxiliary agents in the polymer was 2:1. If the solidification time was required to be earlier than the initial hydration time of cement as the standard, the ratio of polymer to water should be higher than 1:3. The setting time of cement- and polymer-stabilized silty sands decreased with curing temperature and polymer content. The permeability coefficient of cement- and polymer-stabilized silty sands decreased nonlinearly with the increase in polymer and cement contents. Their permeability coefficients were basically within the range of 10−6 cm/s. The compressive strength of cement- and polymer-stabilized silty sands decreased with polymer dosage but increased linearly with cement content. The compressive strength and permeability coefficient of the field grouted samples showed that the cement and polymer grouted silty sand had better impermeability than that grouted with the mixture of cement and metakaolin and the mixture of cement, red mud, and phosphogypsum. The permeability coefficient of cement and polymer grouted silty sand after 28 days could reach 0.89 × 10−7 cm/s, while the improvement of their compressive strength was relatively low, with an average value of 2.46 MPa. The failure of cement- and polymer-stabilized silty sands showed typical plastic shear characteristics rather than brittle and splitting characteristics that appeared in the failure of silty sand grouted by cement and metakaolin, or the mixture of cement, red mud, and phosphogypsum. The results of this study can provide a reference for the construction of low-permeability barriers at sandy strata in water-rich areas. [ABSTRACT FROM AUTHOR]

Published

2024

193. Characterization of Cement-Polymer-Treated Soils under Repeated Loading.

Author

Kumar, Prince, Puppala, Anand J., Congress, Surya Sarat Chandra, and Tingle, Jeb S.

Subjects

*SOILS, *SOIL cement, *CRACKING of pavements, *COMPRESSION loads, *SANDY soils

Abstract

The mechanistic-empirical pavement design guide (M-EPDG) recommends the use of resilient modulus (MR) for characterization of subgrade soils. Subgrade soils may not always have enough strength and stiffness to support the pavement structure. Therefore, a certain type of soil improvement method using cement, lime, or other stabilization techniques is often needed to enhance the strength and stiffness properties of weak subgrade soils. The cement-stabilized soils show brittle behavior under compression loading, which can induce cracking in overlying pavement layers. In general, polymer-treated soils show a semiductile or ductile behavior. It is important to look for combined cement and polymer treatments to address brittle behavior issues as well as moisture susceptibility while maintaining strength and moduli properties. A research study was conducted to understand the strength, resilient, and ductile behaviors of sandy soils treated with cement and a combination of cement and vinyl acetate ethylene (VAE) copolymer. Engineering tests such as unconfined compressive strength (UCS) and resilient modulus tests were conducted on both control and treated soil specimens cured for 7 days. Tests were conducted on specimens before and after immersing in water bath for 4 h to investigate the moisture susceptibility. In these tests, an increase in UCS was observed after cement and cement-VAE treatments as compared to control soil specimens. Results showed that cement-VAE-treated soils exhibited an increase in the axial strain at failure, indicating the semiductile behavior compared to cement-treated specimens. An improvement in the resilient moduli was observed after treatments. Subsequently, two of three-parameter models were used to analyze resilient modulus formulations with stress conditions and determined the regression constants. In conclusion, the study revealed that the use of VAE copolymer improved the stress-strain responses of cement-treated soils and imparted closer to the semiductile behavior, which will reduce cracking in overlying pavement structures. [ABSTRACT FROM AUTHOR]

Published

2024

194. Nitrogen Use Efficiency and Yield Levels Using Soluble and Controlle-drelease Urea Formulations in Tomato Production.

Author

Jalpa, Laura, Mylavarapu, Rao S., Hochmuth, George, Li, Yuncong, Rathinasabapathi, Bala, and van Santen, Edzard

Subjects

*UREA as fertilizer, *NITROGEN fertilizers, *TOMATOES, *GLOBAL warming, *UREA, *SANDY soils

Abstract

This research study evaluated the suitability of controlled-release urea (CRU) as an alternate nitrogen (N) fertilizer source to conventional soluble urea (U) for tomato production under a humid, warm climate in coastal plain soils. Tomatoes are typically produced on raised plastic-mulched beds, where U is fertigated through multiple applications. On the other hand, CRU is applied once at planting, incorporated into soil before the raised beds are covered with plastic mulch. N source and management will likely impact tomato yield, N use efficiency (NUE), and apparent recovery of N fertilizer (APR). A 2-year field study was conducted on fall and spring tomato crops in north Florida to determine the crop N requirement and NUE in tomatoes (var. HM 1823) grown in sandy soils under a plastic-mulched bed system. In addition to a no N fertilizer treatment, three urea N sources [one soluble source and two polymer-coated CRU sources with different N release durations of 60 (CRU-60) and 75 (CRU-75) days] were applied at three N rates (140, 168, and 224 kg.ha-1 ). Across all N sources and N rates, fall yields were at least 20% higher than spring seasons. At the 140 kg.ha-1 N rate, APR and NUE were improved, especially when U was applied in fall tomato, whereas preplant CRUs improved N efficiency in spring tomato. Based on the lower APR values found in spring production seasons (0% to 16%) when compared with fall (57.1% to 72.6%), it can be concluded that residual soil N was an important source for tomatoes. In addition, the mean whole-plant N accumulation of tomato was 102.5 kg.ha-1, further indicating that reducing the N rate closer to crop N demand would greatly improve conventional vegetable production systems on sandy soils in north Florida. In conclusion, polymer-coated CRU and fertigation U applications were able to supply the N requirement of spring and fall tomato at a 38% reduction of the recommended N rate for tomato in Florida (224 kg.ha-1 ). Preliminary results show that adoption of CRU fertilizers can be considered a low-risk alternative N source for tomato production and the ease of applying CRU once during the bed preparation period for tomato may be an additional incentive. [ABSTRACT FROM AUTHOR]

Published

2024

195. ADJUSTING THE ANTIOXIDANT DEFENSE SYSTEM BY SULFUR-CONTAINING COMPOUNDS TO IMPROVE THE GROWTH AND YIELD OF FLAX UNDER SANDY SOIL CONDITIONS.

Author

EL-BASSIOUNY, H. M. S., AL-ASHKAR, N. M., BAKRY, B. A., ABDALLAH, M. M. S., and RAMADAN, A. A.

Subjects

*INDOLEACETIC acid, *SANDY soils, *SATURATED fatty acids, *FLAX, *PHOTOSYNTHETIC pigments, *PLANT pigments

Abstract

Cysteine and thiourea represent natural antioxidants (compounds containing sulfur) that can protect plants against a broad spectrum of environmental stresses. A field trial directly assessed the probable influence of foliar treatment of cysteine (50, 75, and 100 mg L-1) and thiourea (200, 400, and 600 mg L-1) on growth parameters, photosynthetic pigments, seed yield quantity and quality, and some biochemical characteristics of flax plants grown in sandy soil. A foliar spray of cysteine and thiourea markedly increased growth characters, concurrently with an increase in Indole acetic acid content and photosynthetic pigments. Compatible osmolytes and yield components also improved compared with untreated plants. All treatments increased seed yield, oil content, and its components. The ratio of unsaturated fatty acids to saturated fatty acids bore enrichment in the yielded seeds. It was also noticeable that the 400 mg L-1 thiourea was the most pronounced in increasing to maximum the tested parameters of the flax plant. It could be a conclusion that foliar sprays of cysteine and thiourea were active in ameliorating flax performance through increasing antioxidant compounds and enzymes. [ABSTRACT FROM AUTHOR]

Published

2024

196. SILICON AS STIMULANT TO MITIGATE WATER STRESS IN SUGAR BEET PRODUCTIVITY AND QUALITY UNDER DEFICIT IRRIGATED CONDITIONS IN EGYPT.

Author

ABO-BASHA, D. M., ABDEL-KADER, H. H., ELSAYED, S. A. A., and HELLAL, F. A.

Subjects

*DEFICIT irrigation, *POTASSIUM silicate, *CROP quality, *SILICA gel, *SANDY soils, *SUGAR beets

Abstract

Egypt suffers from limited water resources, which threatens food security and reduces the chances of horizontal expansion by reclaiming new desert lands. Therefore, it was necessary to achieve this target for the productivity and quality of crops under harsh conditions. Field experiments proceeded at the Nubaria research station under sandy soil conditions to evaluate the effects of different silicon sources (silica gel, algae rich in silicon, and potassium silicate) on sugar beet yield and quality under different irrigation regimes (100%, 75%, and 50%) of water requirement (WR) during the growing seasons of 2020 and 2021. Results showed that potassium silicate was most effective for increasing chlorophyll content and growth parameters compared with other sources under water stress conditions. Also, improved nutrient contents in the root and shoot of sugar beet gave the highest values on N (0.58%, 2.54%), P (0.132%, 0.318%), K (0.42%, 1.05%), Fe (67.18, 83.28 ppm), and Zn (11.29, 12.73 ppm) content, respectively, when applied with K2SiO3 compared with deficit irrigation conditions. Stimulating rich-Si remains the most effective for enhancing the growth, quality, and yield of sugar beet grown under deficit irrigation regimes, which makes plants more resistant to weather conditions and water stress. [ABSTRACT FROM AUTHOR]

Published

2024

197. PRODUCTIVITY AND STABILITY ANALYSES TO CHARACTERIZE SESAME GENOTYPES UNDER NORMAL AND DROUGHT CONDITIONS IN SANDY AND CLAY SOILS.

Author

ANTER, A. S., ABDELRAOUF, R. E., ABDEL-AZIZ, M. A., and SAMAHA, G. M.

Subjects

*CLAY soils, *CULTIVARS, *SEED yield, *SESAME, *DROUGHTS, *GENOTYPES, *SANDY soils

Abstract

Sesame (Sesamum indicum L.) is an oilseed crop flourishing in marginal lands. It has a high nutritional value because it is rich in protein and fat and has many health benefits. However, the varieties of this crop available in Egypt are very few. Seventeen new sesame lines incurred evaluation in two crop seasons, 2021-2022, for seed yield under eight environments comprising normal and drought conditions in sandy and clay soils. Applying 16 parameters and non-parameters of stability helped select stable and adaptive sesame lines under ideal and drought conditions, with the genotypes arranged in a randomized complete block design with three replicates. Line C5.8 achieved the highest relative productivity in sandy and clay soils and exhibited a good source for breeding programs under drought conditions. Four lines, C1.3, C9.15, C9.6, and C9.20, under eight different environments had higher seed yield than the control. A genetic-environment interaction (GEI) effect on seed productivity occurred in all sources of the combined analysis. The association between seed yield and stability parameters showed the possibility of using a selection index that included some of them to identify sesame genotypes with higher yield and genetic stability. [ABSTRACT FROM AUTHOR]

Published

2024

198. Influence of Tire-Shred Aspect Ratio on Performance of Mechanically Stabilized Retaining Walls.

Author

Kazemzadeh, Michael, Moghadam, Matin Jalali, and Zad, Amirali

Subjects

*RETAINING walls, *SANDY soils, *PARTICLE image velocimetry, *WASTE tires, *DEAD loads (Mechanics), *TIRE recycling

Abstract

The reuse of scrap tires to save storage space and lower traditional disposal risks is an environmental challenge. Currently, recycled tires are considered low-cost, lightweight materials that can be used to improve soil, retaining walls, backfills and roadbeds. The present study investigated the effect of the tire-shred aspect ratio and weight percentage on the bearing capacity and displacement of a stabilized mechanical retaining wall with multi-plate anchors under static loading. To this end, sandy soil containing tire shreds with widths of 1 and 2 cm, aspect ratios of 1, 2, 3, 4 and 5 at 5%, 10%, 15% and 20% contents (weight percentage of soil) was examined. Direct shear tests were conducted to determine the shear strength parameters of the mixtures. It was found that an increase in the tire-shred content in the mixture at a fixed aspect ratio, the bearing capacity of the mixture increased. Also at a fixed aspect ratio, the horizontal wall displacement increased with an increase in the tire-shred content. The wall bearing capacity was determined to increase at a fixed tire-shred content with an increase in the aspect ratio of the tire shreds. The results of the particle image velocimetry showed that an increase in the tire-shred aspect ratio increased the strain on the particle slip surface. [ABSTRACT FROM AUTHOR]

Published

2024

199. Investigation of the Feasibility of Increasing the Tail-grouting Zone during Mechanized Tunneling in Sandy Soils.

Author

Barri, Faezeh, Chakeri, Hamid, Haghkish, Hamed, and Manafi, Milad

Subjects

*TUNNELS, *SANDY soils, *SOIL permeability, *EARTH pressure, *TUNNEL design & construction, *SOIL depth

Abstract

Nowadays, excavation in urban environments can have many risks; one of these hazards is improper tail-grouting of Earth Pressure Balance Machine (EPBM) and the consequent ground surface settlement. Failure to fill the tail space with suitable grout significantly affects the surface displacements. Injecting more grout to penetrate deeper around the tunnel will play a more effective role in reducing displacements and permeability of the soil. Therefore, experimentally investigation of the feasibility of increasing the tail-grouting zone during excavation around the tunnel space and the effect of this penetration on the amount of ground surface displacements is the main purpose of this paper. Thus, experimental tests were performed with different grout injection pressure and the effect of each of the pressure on the penetration depth of grout into the soil new laboratory model were examined. Then to study the effect of the grout penetration depth on surface settlement to determination of the adequate amount of grout injection pressure a numerical modeling of Tabriz metro line 2 by FLAC3D software were completed. For this purpose, the results of the laboratory tests (the penetration depth of grout) were used in numerical modeling. The results indicated that the amount of penetration in the implemented granulation has increased due to the increase in pressure, so doubling the pressure causes a 30% increase in grout penetration in the surrounding soil. The results of numerical studies showed that increasing the range of injection in the modeling causes a significant reduction (80 percent) in the ground surface settlement. [ABSTRACT FROM AUTHOR]

Published

2024

200. Survival of experimentally buried large, winged seeds from open sandy habitats defies the established theory of relatedness between seed size, shape, and longevity.

Author

Bahadoran, Marzieh, Ejtehadi, Hamid, Memariani, Farshid, Tamás, Júlia, and Csontos, Péter

Subjects

*SEED size, *SOIL seed banks, *SEEDS, *SEED viability, *SOIL cracking, *SANDY soils

Abstract

Accumulated evidence indicates that species with small, rounded seeds predominantly maintain a persistent soil seed bank, while those having larger and less isodiametric seeds have a transient seed bank. We assumed that species in certain special habitats may be exceptions to this rule. In habitats with sandy soil and open vegetation, the seeds do not necessarily have to penetrate the deeper soil layers through cracks in the soil. Instead, the seeds can become buried by a windblown layer of sand, thus seed morphology does not really affect the burial process. To test our hypothesis, we selected five semi-desert shrubs and one perennial herb of open sandy grasslands, all of which had large and flattened seeds. For each species, 12 repetitions of 50 seeds were buried in the soil. Seeds were recovered after 3, 20 and 26 months of burial and subjected to germination tests. Seeds of each species germinated in all test occasions, with final germination as follows: Atriplex canescens 89.0%, Haloxylon ammodendron 11.5%, H. persicum 11.5%, Pteropyrum aucheri 43.5%, Xylosalsola richteri 12.0% and Asclepias syriaca 26.0%. The results confirm the hypothesis that each of the six species is capable of forming a persistent soil seed bank. The results also show that in habitats where seed burial can take place passively through windblown soil, plant species might bypass the tradeoff between seed size/shape and seed longevity. [ABSTRACT FROM AUTHOR]

Published

2024