Search Results (2,144)

This study investigates the effect of mass-based replacement of natural coarse aggregate with electric arc furnace (EAF) slag on the performance of ordinary Portland cement (OPC) concrete. Replacement levels of 0%, 30%, 50%, and 100% were examined, with particular attention to the volumetric changes induced by the higher density of EAF slag, which leads to an increase in paste volume. Fresh, mechanical, durability-related, and microstructural properties were evaluated. Results show a continuous reduction in workability with increasing slag content, despite the increase in paste volume, indicating the dominant influence of aggregate morphology on rheological behavior. Mechanical performance exhibited a non-linear response. Within the tested series, the 50% replacement mixture showed the highest mean compressive and splitting tensile strengths; however, the compressive strength difference relative to the control mixture remained small and within typical experimental scatter. In contrast, water absorption decreased progressively, reflecting improved matrix densification. However, this densification did not translate into enhanced mechanical performance, highlighting a decoupling between durability-related indicators and strength. A screening-level CO₂ assessment further showed that reductions in aggregate-related emissions were offset by increased cement content associated with mass-based replacement. The results emphasize the importance of considering volumetric effects when interpreting the behavior and sustainability of slag-based concrete. Note: all strength comparisons are based on mean values from three-specimen sets without formal statistical testing and should be regarded as exploratory observations. Full article

The growing interest in functional bakery products has driven research toward the incorporation of non-conventional plant materials rich in dietary fiber. In this study, the effects of partial substitution of wheat flour with ground kudzu root (Pueraria lobata) at levels of 3%, 6%, 9%, and 12% on dough rheology and bread quality were investigated. Farinograph analysis showed that kudzu addition slightly increased water absorption and dough development time, while significantly improving dough stability and the farinograph quality number. At the same time, a higher degree of dough softening indicated partial weakening of the gluten network at higher substitution levels. The incorporation of kudzu root significantly increased bread yield due to enhanced water retention associated with its high dietary fiber content. However, a reduction in specific volume was observed at the highest substitution level (12%), indicating limitations in gas retention capacity. Crumb structure analysis revealed a shift toward a finer and more homogeneous pore distribution with increasing kudzu content, accompanied by a reduction in large pores. These structural changes were reflected in texture profile analysis, where increased hardness and chewiness were observed, particularly at higher substitution levels, while cohesiveness and springiness were only slightly affected. Partial substitution with kudzu root powder also resulted in a significant increase in total phenolic content, flavonoid content, and antioxidant potential of the breads, with the highest values observed in samples containing 12% kudzu root powder. In addition, breads enriched with kudzu root showed reduced digestible starch content compared with the control sample. Despite these modifications, breads enriched with up to 9% kudzu root maintained acceptable technological quality, balancing improved water retention with moderate changes in structure and texture. The results demonstrate that kudzu root can be used as a functional ingredient in wheat bread, contributing to increased dietary fiber content while maintaining satisfactory processing and quality characteristics. Full article

(1) Background: Climate change and inequality are topics of major interest in Mediterranean Archaeology. However, comparatively less attention has been dedicated to how these themes are interlinked in the literature. No scoping review has ever addressed this issue. This study aims to identify major research trends on inequality and climate change in the Mediterranean c. 4000 BC–AD 500. It also pinpoints current research gaps on the topic and nascent areas of enquiry. (2) Method: We performed a scoping review on JSTOR, Scopus, Google Scholar and PubMed in December 2025–January 2026. A modified version of the PRISMA-ScR protocol was followed. We sampled journal articles, book chapters, edited volumes and monographs published between 2015 and 2025 which matched the search and inclusion criteria. Additional searches were done on Google Scholar in February 2026 to expand upon emerging research trends relevant to our topic but largely absent from the scoping review. We manually extracted, charted, analysed and synthesised the data. (3) Results: A total of 154 studies were eligible for the scoping review. We identified six research trends prominent in the sampled literature: 1. the rise and fall of world systems, macroscale causal links, and collapse research; 2. inequality, subalternity, and marginality; 3. agriculture, crops, and diet; 4. natural resource management, and water supply; 5. epistemology and methodology; and 6. natural archives and climate proxy datasets. We also recognised the following research gaps or topics that were comparatively less addressed: collapse research applied to the microscale level and marginalised communities; isotope analysis applied to both climate change and inequality in the same study; biomedical approaches applied to both climate change and inequality in the same study; social marginality as a complex construct in human–climate interactions; and the environmental and climate dimensions of the early Roman expansion, especially regarding marginality and the microscale. Finally, we identified artificial intelligence (AI), Big Data, environmental and climate activism, and the perception of climate hazards by subaltern communities as nascent topics of interest that might rise to prominence in the future. (4) Conclusions: We identified major research trends and gaps on climate change and inequality in the ancient Mediterranean in literature published 2015–2025. We also recognised nascent or unexplored topics. The review is intended as a benchmark for developing novel research on the cutting-edge of Mediterranean Archaeology. Full article

The growing penetration of renewable energy sources has intensified the demand for safe, sustainable, and cost-effective energy-storage technologies. Aqueous lithium-ion batteries are promising candidates because of their intrinsic safety and high ionic conductivity, though their deployment is limited by narrow electrochemical stability window of water. Lithium titanate oxide (LTO) has emerged as an ideal anode material for aqueous systems because of its exceptional structural stability, negligible volume change during lithiation/delithiation, and relatively high operating potential that suppresses hydrogen evolution. This review examines the peer-reviewed literature (2010–2026) on LTO-based aqueous lithium-ion batteries, focusing on the interdependence between material synthesis, electrode fabrication, electrolyte engineering, and electrochemical performance. Scalable fabrication techniques, such as spray deposition and tape casting, are discussed alongside their pact on electrode quality. Attention is given to water-in-salt, gel-polymer, and localized high-concentration electrolytes that expand the stability window and improve interfacial behavior. Overall, the review highlights how electrolyte design, electrode architecture, and processing methods can be jointly tailored to support stable and scalable LTO-based aqueous lithium-ion batteries systems. Full article

Subsurface freshwater in oceanic islands is typically shaped like a thin lens due to limited land area and recharge, often the primary freshwater source for local communities and highly vulnerable to seawater intrusion (SWI). Freshwater injection (FI) is considered as a feasible strategy for mitigating SWI in coastal aquifers. However, its transient effectiveness for freshwater lens (FWL) development and SWI mitigation in island aquifers and how the design parameters like FI depth, intensity, duration and injectant concentration affect its performance remain poorly understood. To address this, this study employs a two-dimensional, variable-density island groundwater model to simulate the transient responses of FWL development and SWI mitigation to various FI patterns. Five indicators are developed for comprehensive evaluation, including (1) freshwater recovery efficiency (FRE), and the relative changes in (2) average water table elevation (WTE), (3) FWL depth, (4) FWL volume, and (5) total aquifer salt mass. Results reveal FI universally raises average WTE, expands FWL dimensions, and promotes aquifer desalinization. Injection intensity is the primary driver of WTE rises and salt mass reduction, with higher intensities consistently yielding greater WTE rises and salt mass reductions. Deeper injection within the mixing zone increases FWL depth, but reduces the net gain in FWL volume. Moreover, early-stage FI is highly efficient for expanding FWL volume, often yielding FRE values above 100%, but FRE converges toward zero over time as the system moves toward a new hydrodynamic equilibrium, returning diminishing marginal benefits for long-term FI. Full article

Subsurface freshwater in oceanic islands is typically shaped like a thin lens due to limited land area and recharge, often the primary freshwater source for local communities and highly vulnerable to seawater intrusion (SWI). Saltwater abstraction (SA) is considered as a feasible strategy for mitigating SWI. However, its transient effectiveness for freshwater lens (FWL) development and SWI mitigation in island aquifers, and how the design parameters like SA depth, intensity, and duration affect its performance, remain poorly understood. Therefore, this study employs a two-dimensional, variable-density island groundwater model to simulate the transient responses of FWL development and SWI mitigation to various SA patterns. Six indicators are developed for comprehensive evaluation, including: (1) freshwater recovery efficiency, and the relative changes in (2) average water table elevation (WTE), (3) WTE at the SA well, (4) FWL depth, (5) fresh groundwater volume, and (6) total aquifer salt mass. Simulation results highlight SA depth as the primary determinant of its effectiveness, characterized by critical thresholds that dictate whether SA imposes net positive or negative effects on FWL depth, volume, and aquifer desalinization, with SA intensity and duration serving as scaling factors that amplify the magnitude of these responses. Moreover, while SA can effectively expand FWL volume and shift it toward a more favorable hydrodynamic equilibrium, the diminishing marginal benefits over time cause the FRE to approach zero, indicating SA is a potent short-term restoration strategy rather than a long-term solution from a cost–benefit perspective. Full article

The textile and clothing industry has historically exerted a significant negative impact on the environment. Excessive water consumption, chemical pollution, and soil degradation are just a few of the pressing environmental concerns linked to this sector. Addressing these issues has become a priority not only for regulatory bodies, at the National and European levels, but also for the industry itself. More recently, growing attention has turned to reducing the huge volume of waste generated by consumers’ unbridled purchase of clothing. In this context, the Circular Economy (CE) and the Digital Product Passport (DPP) have emerged as complementary approaches for improving product circularity, transparency, and traceability. However, in the textile and clothing sector, their effective implementation also depends on consumer participation in practices such as prolonged use, repair, reuse, and responsible end-of-life management. This article presents EcoProve, a gamified platform designed to encourage consumer engagement with CE practices through smart wardrobe management. The platform allows users to register garments, track usage, record maintenance and repair actions, and document sharing, donation, remaking, and recycling activities. These functionalities aim both to promote more sustainable clothing-related behaviours and to support the structured recording of use phase data relevant to DPP-oriented lifecycle information. This study reports the development and pilot validation of the platform with end users. The results suggest positive effects on environmental awareness, perceived understanding of sustainable textile-related practices, and initial self-reported changes in habits associated with clothing use and disposal. The findings support the potential of gamified digital platforms to foster consumer participation in CE systems in the textile and clothing sector while also indicating the need for broader and longer-term evaluations. Full article

The common pea (Pisum sativum L.) is widely cultivated due to its nutritional value and adaptability, though climate change and increasing food demand require improved agricultural strategies. The genus Metarhizium, an entomopathogenic fungus, has shown potential to enhance plant growth and physiology. This study aims to evaluate the effect of naturalized Metarhizium spp. isolates on agronomic parameters and root architecture of Pisum sativum seedlings under greenhouse conditions. Fungi were isolated from rhizosphere soils using Tenebrio molitor larvae. Six Metarhizium strains and a control (sterile distilled water) were tested, with eight replicates per treatment. After 36 days, growth parameters and chlorophyll content were measured at ambient temperatures between 12.1 ± 1.5 and 42.4 ± 2.4 °C. Significant differences were analyzed using Tukey’s HSD post hoc test (p < 0.05). Significant increases in shoot length were observed in strains MM23B and MM26B (13.2 ± 0.6 and 13.0 ± 1.1 cm). Stem diameter was higher in MM23B, G9C, and MM30D (3.1–3.2 mm). Chlorophyll content increased moderately, with MM29C reaching 296.7 ± 35.9 compared to 242.5 ± 22.8 µmol m⁻² in the control. Shoot biomass was highest in G9C, MM23B, and MM26B (0.27–0.29 g) with higher shoot/root ratios in MM23B and MM26B (2.41 and 2.58). Root biomass showed no significant differences. However, root system architecture was modified, particularly in MM26B, which significantly increased root length (239.08 ± 34.22 cm) and area (20.70 ± 2.13 cm²), without changes in volume or diameter. Finally, naturalized Metarhizium spp. isolates demonstrated potential as plant growth-promoting fungi, improving physiological and morphological parameters in early P. sativum development. Full article

Alpine glaciers are a vital resource for mountain regions. They provide water reserves, support energy production and tourism, and promote biodiversity. However, they are highly susceptible to climate change. In fact, they are recognised as being among the areas most affected by, and increasingly exposed to, natural hazards. The Rutor glacier in Aosta Valley, Italy, which has been the subject of repeated measurements since the 19th century and currently covers an area of around 8 km², is undergoing significant and continuous retreat. It thus serves as an exemplary case study of the impact of climate change on the Italian Alps. This ongoing research has made it possible to conduct multi-temporal analysis of the glacier. Within this framework, Politecnico di Torino, in collaboration with ARPA Valle d’Aosta, has developed a multidisciplinary research approach focused on the characterisation of alpine environments. This study illustrates the geomatic workflows and derived geospatial products that can be used to carry out a 4D monitoring of the extent and volume of the Rutor Glacier and estimate its mass balance over the past six years. A specific focus of the study is the propagation of errors in multi-temporal analyses used to quantify glacier melt, with particular attention to the precision of input 3D geospatial data and to the Limit of Detection of elevation differences, ultimately enabling the estimation of the uncertainty associated with the derived quantities and their temporal trends. Finally, advantages and limitations in the multi-temporal and multi-sensor monitoring of glaciers are presented and discussed. Full article

The surface disturbance caused by coal mining and the ecological restoration have changed the vegetation coverage and ecosystem functions of the Shengli mining area. This disturbance has affected the carbon and water cycles, resulting in complex response characteristics of water use effectiveness (WUE). To reveal these response characteristics, this paper uses multi-source remote sensing data from 2001 to 2024 and applies random forests to scale down MODIS 500 m net primary productivity (NPP) and MODIS 1 km evapotranspiration (ET) to 30 m resolution. Then, it calculates the WUE of the Shengli mining area to reveal the temporal and spatial variation patterns and characteristics of WUE in the mining area and the spoil dump. It also uses the Pearson correlation coefficient to analyze the driving factors of WUE. The results show that the determination coefficients R² of the NPP and ET scaling models are 0.961 and 0.7142 respectively. The WUE in the study area and four spoil dumps from 2001 to 2024 all follow the pattern of “decrease due to disturbance—recovery and rise—gradual stabilization”, with the peak WUE in the mining area reaching 1.123 g·C·m⁻²mm⁻¹ in 2002, a fluctuation decline from 2002 to 2011 with a valley value of 0.398 g·C·m⁻²mm⁻¹ in 2010, an annual increase trend from 2011 to 2013, and a basic stabilization from 2013 to 2024, with an average value of 1.001 g·C·m⁻²mm⁻¹ during this period. Compared to the average value of 1.061 g·C·m⁻²mm⁻¹ from 2001 to 2022, WUE has not yet returned to the initial level. The Pearson correlation coefficients ranked from high to low are: NDVI (0.59, +) > | deformation (−0.39, −) | > temperature (0.27, +) > rainfall (0.26, +) > mining area (0.072, +), indicating that NDVI and deformation are important factors affecting WUE. Further analysis of the relationship between NDVI disturbance and WUE reveals that the mean NDVI disturbance and recovery in the study area from 2001 to 2024 are 0.438 and 0.392 respectively. WUE shows a “first decline—then rise—then stabilization” phased evolution pattern during the “disturbance—recovery—stability” process of vegetation, and the disturbance intensity and recovery intensity are positively correlated with the rate of WUE decrease and increase. The combination analysis of deformation and WUE indicates that the deformation areas in the mining area and the inner spoil dump show a trend of WUE reduction due to the increase in deformation volume. The study shows that the continuous mining of open-pit coal mines continues to affect the water usage function of vegetation in the mining area. Subsequent restoration should prioritize strengthening surface stability, soil water retention, and vegetation reconstruction in the mining area, inner spoil dump, and areas with large deformation to improve the stability and water usage efficiency of ecological restoration. Full article

The growing demand for long-distance green methanol transportation highlights the critical need to evaluate the safety and reliability of pipeline sealing materials. This study investigates the swelling mechanisms of fluorocarbon rubber (FKM), nitrile butadiene rubber (NBR), and polytetrafluoroethylene (PTFE) under simulated methanol pipeline conditions. Static immersion tests were conducted under simulated pipeline conditions with water contents of 0–20% and temperatures of 25–55 °C, supplemented by thermogravimetric analysis (TGA), Fourier transform infrared spectroscopy (FTIR), and gas chromatography–mass spectrometry (GC–MS). FKM exhibited severe physical swelling, with the volume increase reaching up to 80% in pure methanol. Notably, the addition of 5% water markedly suppressed this swelling, reducing the volume change of FKM sealing rings to approximately 3% and the mass change to 1%. Conversely, NBR experienced volume shrinkage and mass loss due to the extraction of the plasticizer Bis(2-ethylhexyl) phthalate by methanol, a process also inhibited by water. PTFE demonstrated exceptional chemical stability and negligible dimensional changes owing to its high crystallinity and rigid structure. Consequently, PTFE is recommended as the optimal sealing material for pure methanol pipelines. When utilizing FKM or NBR, strict control over the fluid’s water content and operating temperature is essential to prevent degradation and ensure long-term pipeline integrity. Full article

The “New Arctic” regime represents a prominent climatic feature of the Arctic Ocean under global warming, characterized by persistently low summer sea ice extent, a marked reduction in sea ice thickness, and an expansion of open water areas at high latitudes. As a key indicator of the Arctic sea ice system, the spatiotemporal evolution of sea ice thickness and its underlying driving mechanisms remain incompletely understood. Using reanalysis datasets and remote sensing observations, this study identifies major abrupt shifts in Arctic sea ice thickness under the New Arctic regime, reveals the spatiotemporal distribution characteristics of winter sea ice thickness, and examines the driving factors from both thermodynamic and dynamic perspectives. The results show that the evolution of Arctic sea ice thickness can be divided into three phases: a high-level period during the “Traditional Arctic” (1979–1992), a rapid thinning period during the New Arctic transition (1993–2012), and a low-level stabilization period in the New Arctic regime (2013–2023). The first EOF mode of winter sea ice thickness depicts a spatially consistent thinning pattern across the entire Arctic, with the most significant reduction occurring in the multi-year ice regions north of the Canadian Arctic Archipelago and Greenland. The second EOF mode exhibits an out-of-phase variation between the Atlantic and Pacific sectors of the Arctic, accompanied by a shrinking amplitude and weakened regional oscillations. The coupling between surface air temperature and sea ice thickness displays distinct phase dependence: their negative correlation is strongest during the transition period (r = −0.78, p < 0.001) but becomes statistically insignificant in the New Arctic regime. Sea ice motion speed exhibits an overall accelerating trend, which extends from the marginal seasonal ice zones toward the high-latitude multi-year ice regions, accompanied by a notably enhanced sensitivity of sea ice motion to wind forcing. Sea ice volume flux through the Fram Strait is primarily controlled by ice motion speed, whose contribution to the flux is approximately 2.6 times that of ice thickness. The recovery of ice drift speed offsets the thinning of sea ice cover, leading to a partial rebound in volume flux during the New Arctic steady state. This study identifies the evolutionary patterns and drivers of Arctic sea ice thickness under the New Arctic regime, providing a scientific basis for further understanding the changes in the Arctic climate system and associated air–sea ice interactions. Full article

Background: Centella asiatica has been widely recognized for its dermatological benefits; however, clinical evidence supporting the efficacy of oral supplementation for improving skin aging parameters remains limited. This randomized, double-blind, placebo-controlled study evaluated the effects of oral Centella asiatica extract on skin wrinkles and related skin parameters in middle-aged women. Methods: A total of 112 participants were randomized to receive either Centella asiatica extract (200 mg/day) or placebo for 12 weeks. Skin wrinkle parameters were quantitatively assessed using a three-dimensional skin imaging system (PRIMOS^®). Skin hydration, transepidermal water loss (TEWL), elasticity, and skin color (brightness and redness) were additionally measured using validated non-invasive instruments. Efficacy analyses were performed in the per-protocol population. Results: After 12 weeks of supplementation, the Centella asiatica extract group demonstrated significant improvements in multiple wrinkle parameters compared with the baseline. Average wrinkle depth decreased by 11.1%, and the mean depth of the largest wrinkle decreased by 14.4%. Maximum wrinkle depth and total wrinkle volume were reduced by 13.3% and 13.7%, respectively, while surface roughness (Ra) decreased by 10.4%. In contrast, the placebo group showed minimal or inconsistent changes. Epidermal hydration at the cheek site significantly increased, while transepidermal water loss decreased, indicating improved skin barrier function. However, the magnitude of changes in epidermal hydration (2.7%), skin elasticity (R2; 0.7%), and skin brightness (L*; 0.7%) were relatively small. Skin elasticity and skin brightness showed statistically significant differences compared with the placebo group (p < 0.05), but these changes should be interpreted as modest improvements. No serious adverse events were reported, and all hematological and biochemical safety markers remained within normal reference ranges during the 12-week intervention period. Conclusions: Oral supplementation with Centella asiatica extract for 12 weeks was associated with improvements in wrinkle-related parameters and TEWL, while changes in skin hydration, elasticity, and brightness were modest and of limited magnitude. These findings suggest a potential role for short-term supplementation; however, further studies are required to confirm long-term efficacy and broader applicability. Full article

The interaction between crossflows from sprinkler nozzles and airflow is crucial for engineering applications, particularly affecting the efficiency of sprayed areas. This study investigates the deformation of a continuously injected conical water spray subjected to horizontal airflow, using a planar laser imaging method as a visualisation technique. Experiments were conducted in a wind tunnel at a constant water pressure of 0.2 MPa and four airflow rates (0.1, 0.2, 0.4, and 0.6 m³·s⁻¹) to systematically vary the air-to-water momentum ratio. A grayscale-based analysis method was developed using a per-pixel Look-Up Table (LUT), enabling indirect assessment of droplet concentrations and spray structure. This approach allowed for a detailed examination of changes in the spray cone shape under flowing air. By assessing the water spray across three vertical planes intersecting the spray cone, it became possible to calculate lateral area and cone volume at different air-to-water mass flow ratios. The spray formation region exposed to airflow exhibited larger cone volumes than those with minimal airflow. The changes in apparent spray angles for the tested nozzles were determined to characterize the cone shape. The apparent spray angle varies systematically with the air-to-water mass flow ratio, confirming the dominant role of aerodynamic forces. These findings improve the understanding of spray behavior under crossflow and provide a basis for validating numerical models of air–water interactions. Full article

Objectives: This study investigated the associations of biochemical and body water distribution parameters with dengue status, as well as their discriminatory ability, among hospitalized adults with febrile illnesses and evaluated whether dynamic changes in body water volumes were associated with length of hospital stay (LOS) in dengue patients. Methods: A prospective observational cohort study was conducted at a tertiary care hospital involving 186 hospitalized adults (age ≥ 18 years) with fever onset ≤ 5 days and suspected dengue. Body water parameters were assessed by bioelectrical impedance analysis (BIA) using the InBody S10 body composition analyzer at admission (T1), defervescence (T2), and discharge (T3) in dengue patients and at admission only in other febrile illness (OFI) cases. Laboratory data and LOS were retrieved from the hospital information system. Linear and logistic regression models were used to examine the associations and interactions. Discriminative performance was assessed using a receiver operating characteristic (ROC) curve analysis. Results: The proportion of dengue cases was 55.9% (n = 104). Higher levels of lymphocytes, hematocrit, hemoglobin, AST, and ALT were associated with an increased likelihood of dengue, whereas elevated WBC counts, neutrophils, platelets, CRP, sodium, chloride, and the extracellular water-to-total body water ratio (ECW/TBW) were associated with a reduced likelihood of dengue. ROC analysis indicated that WBC showed the best diagnostic performance. In dengue patients, a greater increase in ECW volume from admission to defervescence was associated with a longer LOS in males, and ratio-based body water parameters showed longitudinal variation across dengue phases. Conclusions: Several hematologic, biochemical, and BIA-derived body water parameters were associated with dengue status. Among dengue patients, dynamic ECW changes were associated with longer LOS in males, and ratio-based fluid indices were more sensitive than absolute water volumes in reflecting fluid redistribution throughout the dengue course. Full article