Background: The olive stone, a primary by-product of olive oil extraction, is mainly composed of a lignified shell and inner seed. It represents a substantial portion of the olive industry's biomass waste, contributing over 40 Mt annually. While typically regarded as waste, olive stones contain a variety of nutrients and bioactive compounds like lipids, proteins, phenolic compounds, and minerals found in the seed, as well as fibers in the shell. These elements hold significant value across multiple sectors, including food, energy, and agriculture. These phenolic compounds and nutrients provide notable antioxidant, anti-inflammatory, chemopreventive, and antimicrobial effects, supporting health and disease prevention. Scope and approach: This review explores the sustainable utilization of olive stone by-products, highlighting their potential to contribute to human health and environmental sustainability. It discusses the practical applications of olive stones in various domains, from functional ingredients in food products and pharmaceuticals to renewable energy sources and soil-enhancing agricultural inputs. Key findings and conclusions: Olive stones, particularly olive seeds, are rich in dietary fiber (47.6 %), lipids (30.4 %), proteins (13.5 %), and phenolic compounds (8.10 %), especially n & uuml;zhenide, n & uuml;zhenide 11-methyl oleoside and methoxyn & uuml;zhenide, and demonstrate a range of health-promoting properties. Additionally, they are shown to benefit metabolic health by combating disorders such as diabetes, hyperlipidemia, obesity, and car- diovascular and neurodegenerative diseases while also protecting organ functions like those of the liver and kidneys. The review underscores the promise of olive stone by-products as a sustainable, health-benefiting resource in circular economy practices within the olive oil industry.

Date palm trees, especially Alhayani, Barhi, and Majhool, have a rich history in Palestine. However, the waste produced by these trees, such as unripe dates, date pits, and palm fronds, is usually burned on farms, leading to environmental concerns, or collected inside the farms for long periods, which leads to the emergence of the red date palm weevil, which works to damage palm trees. These wastes are a significant source of excellent biomass that can be used in many applications such as energy production, livestock feed, fertilizer for soil, and wooden boards, and can even be used as insulating materials as they have an excellent insulation value up to 0.083 W/ m.K [1]. This study focuses on utilizing agricultural waste from date palm trees in Palestine by grinding and transforming it into wooden blocks or pellets for use in heating, bakery ovens, household wood stoves, and other applications. The effectiveness of these waste materials for use as excellent heat value resources has been demonstrated, especially when compared to other tree waste. The heating values that were measured for date kernel (17.127 MJ/kg), palm leaf (16.887 MJ/kg), and palm frond petiole (15.990 MJ/kg) indicate their promising potential for use in heating applications. A feasibility study was conducted for a production line that converts these waste materials into wooden blocks for use in heating applications. The annual profits were estimated at approximately 41000 $, with a payback period of around 2.4 years and a return-oninvestment rate of 36 %.

Soil erosion has both on-farm and off-farm effects. On-farm, reduced soil depth can decrease land productivity, while off-farm, sediment transfer can damage streams, lakes, and estuaries. Therefore, optimal soil erosion modeling is a crucial first step in soil erosion research. One of the most important aspects of this modeling is the accuracy and applicability of the soil erosion factors used. Various methods for calculating these factors are discussed in the literature, but no single method is universally accurate. After an extensive review of the literature, we propose using the existing revised universal soil loss equation (RUSLE) factors for global application. Additionally, we conducted a grassroots-level experiment to demonstrate the effectiveness of the proposed methods. RUSLE is identified as the most suitable model for global-scale soil erosion modeling. We evaluated the potential impacts of climate and land use and land cover (LULC) by utilizing shared socio-economic pathways (SSPs) alongside projected LULC scenarios. A suitable general circulation model (GCM) was selected after comparing it with recorded data from a base period. This model was validated with experimental observations, confirming its effectiveness. This review article outlines the future direction of soil erosion modeling and provides recommendations.Graphical AbstractThe graphical abstract visually summarizes the comprehensive methodology and key findings associated with optimal soil erosion modeling and management. It highlights a structured approach, beginning with identifying optimal methods for assessing soil erosion factors: Rainfall and Runoff Erosivity (R), Soil Erodibility (K), Slope Length and Steepness (LS), Cover and Management (C), and Support Practice (P) integral components of the Revised Universal Soil Loss Equation (RUSLE). It illustrates the detailed methodological framework, emphasizing selecting suitable climate models for projecting future R factors, combined with projected land use and land cover (LULC) scenarios derived from Shared Socio-economic Pathways (SSPs). The scenarios shown range from lower emissions (SSP 126) to higher emissions (SSP 585), indicating progressive increases in future erosion risk. Moreover, it explicitly ties the research findings to policy recommendations, underscoring a holistic approach aligning soil conservation with Sustainable Development Goals (SDGs): specifically, Climate Action (SDG 13), Life on Land (SDG 15), and Zero Hunger (SDG 2). Suggested measures include integrating soil erosion control into broader policy frameworks, promoting sustainable land management practices such as agroforestry and contour plowing, and fostering policy integration and collaboration to enhance conservation effectiveness. Overall, the graphical abstract succinctly depicts how climate change, socio-economic dynamics, and LULC variations amplify future soil erosion risks, reinforcing the need for targeted, sustainable, and integrated soil conservation strategies globally.

Potato (Solanum tuberosum L.) cultivation faces significant challenges: highland cultivation leads to soil erosion and fertility degradation, while medium-land cultivation is constrained by suboptimal temperature and humidity conditions. Processing potatoes into starch improves shelf life and economic value, however, native potato starch has limited food applications due to heat sensitivity, high viscosity, and its propensity for retrogradation and syneresis. This study investigated the effects of cultivation altitude and modification methods on the physicochemical and functional properties of potato starch from 'Medians' cultivar, comparing samples from medium-land (765 m above sea level) and highland (1312 m above sea level) locations. Starch modifications included Heat Moisture Treatment (HMT), crosslinking with Monosodium Phosphate (MSP), and a combined treatment (CLM-HMT). A factorial randomized complete block design was employed to analyze physicochemical characteristics, functional properties, and pasting behavior, with statistical significance determined using two-way ANOVA and Duncan's Multiple Range Test (p < 0.05). Results revealed significant effects of cultivation altitude, modification method, and their interaction on starch properties. Highland-grown modified starch exhibited superior characteristics in color properties and thermal stability. Modification methods improved starch thermal stability and minimized retrogradation, with the combined CLM-HMT treatment yielding optimal results. This study provides valuable insights into optimizing potato starch production and modification techniques, contributing to sustainable agriculture and broadening its applications in the food industry.

Soils and geosynthetics are terms used interchangeably whenever the physical and mechanical properties of the soil are unlikely to sustain the load coming over it. Several studies have been undertaken to determine the benefits of using geosynthetic products instead of conventional procedures such as stone columns, jet grouting, soil nailing, and so on. As far as geotechnical applications are concerned, geogrid is the most widely utilised polymeric product. This paper provided an overview of geogrid's numerous applications, including pavements, airport runways, railroads, building foundations, MSE walls, bridge embankments, and landfills. Furthermore, this bibliometric analysis has revealed the important laboratory model experiments done on geogrids as well as numerical finite element and finite difference model analysis. An overview of several case studies involving geogrid reinforcement in large projects was also documented; the review also discussed the present trends and opportunities for future development of new geogrid reinforcement technologies within the same of the literature collection to have better clarity for comparison.

Maize ranks as the 3rd most economically valuable cereal crop worldwide but its productivity is under severe threat by an invasive pest, Spodoptera frugiperda (Lepidoptera: Noctuidae). The 3rd instar S. frugiperda larvae are most damaging stage of lifecycle, that's why the present study is planned to evaluate the impacts of silicon dioxide (SiO2), potassium silicate (K2SiO3), and sodium silicate (Na2SiO3) @ 400 and 800 ppm against the 3rd instar larvae of S. frugiperda by using two application methods (soil drenching and foliar spray). Moreover, the impact of Si supplementation on biological parameters (pupation, adult emergence, and egg laying) was also recorded. The findings showed that SiO2 application through foliar spray @ 800 ppm concentration caused maximum mortality (12-36%) followed by K2SiO3 (8-32%) and Na2SiO3 (4-24%). The soil drenching method of silicon application was less effective in comparison to foliar spray. The surviving larvae showed negative impacts on growth and development, including pupation (48, 52, and 60%), adult emergence (41.67, 46.15, and 53.33%) and fecundity (46.20, 52.60, and 54.20) by SiO2, K2SiO3 and Na2SiO3 foliar spray @ 800 ppm respectively. The present study revealed that Si had a significant detrimental impact on immature stages of S. frugiperda. Consequently, Si treatment can reduce S. frugiperda reproduction which may ultimately decrease S. frugiperda establishment and early harm in maize. Silicon applications may offer a sustainable way to lessen S. frugiperda infestations, improving maize protection and lowering the need for conventional insecticides.

Loess has poor engineering performance and needs to be improved for engineering applications by adding a large amount of lime or cement, which is not consistent with the goal of carbon peaking and carbon neutrality. In this study, nano-SiO2 (NS) and nano-MgO (NM) were applied to improve the engineering performance of lowdosage lime/cement- stabilized loess. The improvement mechanisms of each binder on loess were analyzed by X-ray diffraction (XRD) and scanning electron microscopy-energy dispersive spectrometer (SEM-EDS) tests. The impact of binder dosage and curing time (T) on unconfined compressive strength (UCS), resilient moduli (MR), California bearing ratio (CBR), internal friction angle (phi), cohesion (c), and compression coefficient (a1-2) of each stabilized loess were also explored by conducting a range of laboratory experiments. The results show that the addition of NS did not result in the formation of new substances. However, the formation of MH was noted with the addition of NM. The combination of lime and NS can significantly enhance the UCS, CBR, MR, and c of the stabilized loess, followed by the combination of cement and NS. With the increasing NM content, the above mechanical indices first increased and then decreased for the stabilized loess. Both the binder content and type caused a lesser impact on the phi and a1-2 than on other mechanical indices. Moreover, the mix ratio and feasibility of each stabilized loess applied in various engineering fields were analyzed based on relevant standards and the construction requirements of lime and cement. Finally, estimation models were established for the above mechanical indices of lime-NS stabilized loess, which can provide a reference for engineering design and quality control.

Agricultural production is facing challenges such as water scarcity, declining soil quality, and excessive use of chemical fertilisers and pesticides, and there is an urgent need to find sustainable solutions. Hydrogel, as a novel functional polymer material, is considered as a potential agro-material to solve these problems due to its excellent water retention, swelling, slow release, biocompatibility and biodegradability. However, there are still challenges in designing efficient agrohydrogels, such as sustainability of the materials, environmental impacts of cross-linking methods, adaptability of the network structure to the crop growing environment, as well as the cost of the materials and the effectiveness of the practical applications. Therefore, a systematic review of the design, properties and applications of agrohydrogels is of great theoretical and practical significance. This paper reviews the design methods of agricultural hydrogels, including network structure design, material source selection, crosslinking technology and its mechanism research. Then, the key properties of agricultural hydrogels, such as water retention, swelling, slow release, biocompatibility and biodegradability, are discussed in detail. Finally, the applications of hydrogels in the fields of soilless cultivation, soil improvement and smart agriculture are presented. This paper concludes that with the continuous progress of technology, agricultural hydrogels will play an important role in future agricultural production.

A rich diversity of radiation-resistant (Rr) and desiccation-resistant (Dr) bacteria has been found in arid habitats of the world. Evidence from scientific research has linked their origin to reactive oxygen species (ROS) intermediates. Rr and Dr. bacteria of arid regions have the potential to regulate imbalance radicals and evade a higher dose of radiation and oxidation than bacterial species of non-arid regions. Photochemical-activated ROS in Rr bacteria is run through photo-induction of electron transfer. A hypothetical model of the biogeochemical cycle based on solar radiation and desiccation. These selective stresses generate oxidative radicals for a short span with strong reactivity and toxic effects. Desert-inhibiting Rr bacteria efficiently evade ROS toxicity with an evolved antioxidant system and other defensive pathways. The imbalanced radicals in physiological disorders, cancer, and lung diseases could be neutralized by a self-sustaining evolved Rr bacteria antioxidant system. The direct link of evolved antioxidant system with intermediate ROS and indirect influence of radiation and desiccation provide useful insight into richness, ecological diversity, and origin of Rr bacteria capabilities. The distinguishing features of Rr bacteria in deserts present a fertile research area with promising applications in the pharmaceutical industry, genetic engineering, biological therapy, biological transformation, bioremediation, industrial biotechnology, and astrobiology.

Circular economy envisages resource efficiency and minimization of the negative impacts of waste on the environment and human health. This work considers municipal solid waste incineration bottom ash (IBA) for safe use in geotechnical works, through physical, chemical, ecotoxicological, and geotechnical analysis of samples with different weathering periods. Low leaching potential and no relevant ecotoxic effects were found for IBA. Better compaction was obtained for IBA mixtures with sand. All materials showed reasonable permeability after compaction. IBA stiffness and shear strength values, consistently assessed through different tests, were within dense granular soils range. Weathering seems to positively influence IBA geotechnical properties, which in any case seem compatible with environmentally safe and sustainable geotechnical applications.