Enhancing the productivity of forage crops while maintaining soil health remains a critical objective in sustainable agriculture. Excessive application of inorganic nitrogen (N) fertilizers, particularly urea, has contributed to soil degradation and environmental concerns, prompting the need for biologically sustainable alternatives. In this study, the effects of substituting urea with bioorganic fertilizer on soil quality and forage yield in an intercropping system of Pennisetum purpureum and Macroptilium atropurpureum were investigated. A randomized block design (RBD) was employed with six substitution treatments: no fertilizer (T), 0% substitution (S0), and 25% (S1), 50% (S2), 75% (S3), and 100% (S4) substitution of urea-N with bioorganic fertilizer. Each treatment was replicated four times, resulting in 24 experimental plots. Parameters evaluated included soil properties, populations of nitrogen-fixing bacteria (NFB) and phosphorus-solubilizing bacteria (PSB), and growth and biomass characteristics of the forage association. Substitution treatments significantly improved soil fertility indices. The highest soil organic carbon (SOC) (3.23%) was observed in S3, while total N content (Total N) in S2, S3, and S4 exceeded that of T and S0. Available phosphorus (P) was greatest in S3 and S4, and the highest cation exchange capacity (CEC) (24.08 me 100 g^-1) was recorded in S4. The S2 and S3 treatments yielded the highest leaf dry weights (1.55 and 1.49 kg plot^-1, respectively), stem dry weights (1.84 and 1.70 kg plot^-1), and total dry forage weight (3.38 and 3.19 kg plot^-1). Leaf-to-stem ratios and leaf areas in S2 and S3 were comparable to S0 and significantly greater than T. The lowest leaf area-to-total forage ratios (14.39 and 15.05 m² kg^-1) were also observed in these treatments. It was demonstrated that 50% and 75% substitution levels of urea-N with bioorganic fertilizer not only enhanced soil quality parameters but also significantly increased forage productivity compared to exclusive urea application. These findings underscore the potential of bioorganic fertilizer as a sustainable alternative to inorganic N sources, contributing to improved soil health, higher forage yields, and more resilient agroecosystems.

The widespread adoption of electric vehicles (EVs) has brought about critical challenges in brake rotor performance, primarily attributed to the reduced reliance on conventional friction braking systems. This decreased usage, owing to the predominant application of regenerative braking, has inadvertently increased the susceptibility of brake rotors—particularly those manufactured from grey cast iron (GCI)—to corrosion and non-traditional wear mechanisms due to extended exposure to environmental elements. These challenges are compounded by the global imperative for sustainable transportation solutions, as emphasized in the European Union (EU)’s roadmap for climate-neutral mobility. In this context, the development and implementation of sustainable strategies to improve the wear and corrosion resistance of EV brake rotors have become paramount. This review synthesizes recent advancements in environmentally conscious approaches, including the application of eco-friendly surface treatments, alloying modifications, microstructural engineering, and solid or dry lubrication techniques tailored for GCI rotors. The analysis extends to the evaluation of scalability, cost-efficiency, tribological stability, and environmental compatibility over the rotors' service life. Particular attention is devoted to emergent solutions such as bio-inspired multifunctional coatings, integration of intelligent condition-monitoring technologies, and rotor design optimized through data-driven predictive modelling. The necessity for robust life cycle assessments (LCA) is underscored, aiming to holistically quantify environmental impact from raw material extraction through end-of-life disposal or recycling. Key research gaps are identified, including the limited real-world validation of novel materials under EV-specific load profiles and insufficient understanding of synergistic degradation modes under mixed braking regimes. It is suggested that a multidisciplinary research agenda—merging materials science, tribology, electrochemistry, and intelligent systems—is essential to advance the next generation of high-performance, low-impact braking solutions. In doing so, a comprehensive framework for sustainable brake rotor innovation in EVs can be established, aligning material resilience with broader environmental and regulatory goals.

Accurate and consistent road boundary detection remains a fundamental requirement in autonomous driving, traffic surveillance, and intelligent transportation systems, particularly under diverse lighting and environmental conditions. To address the limitations of classical edge detectors in complex outdoor scenarios, a novel multi-channel edge detection framework is proposed, termed the Multi-Channel Functional Gradient–Entropy (MC-FGE) model. This model has been specifically designed for colour road imagery and incorporates a mathematically principled architecture to enhance structural clarity and semantic relevance. The initial phase involves channel-wise normalization of RGB data, followed by the computation of a fused gradient magnitude that preserves edge information across heterogeneous spectral distributions. Two original mathematical constructs are introduced: the Spectral Curvature Function (SCF), which quantifies local geometric sharpness by leveraging first- and second-order differential operators while exhibiting resilience to noise; and the Colour Entropy Potential Function, which captures local texture complexity and intensity-driven irregularity through entropy analysis of chromatic distributions. These functions are combined into a unified Functional Edge Strength Map (FESM), designed to emphasize semantically meaningful road-related boundaries while suppressing irrelevant background textures. A central innovation is the Log-Root Adaptive Thresholding Function (LRATF), which adaptively modulates threshold sensitivity by integrating curvature and entropy cues in a logarithmic-root formulation, thereby improving robustness to illumination variability, occlusions, and shadow interference. The final binary edge map is derived through precision thresholding of the FESM and refined using morphological post-processing to ensure topological continuity and suppress artefactual edge fragments. Quantitative and qualitative evaluations conducted across varied outdoor datasets demonstrate that the MC-FGE model consistently outperforms conventional edge detectors such as Canny, Sobel, and Laplacian of Gaussian, particularly in scenarios involving texture-rich road surfaces, poor lighting, and partial occlusion. The model not only exhibits enhanced detection accuracy and edge coherence but also offers improved interpretability of road features, contributing both a rigorous theoretical foundation and a scalable computational framework for adaptive edge-based scene understanding in road environments.

The transition toward Industry 5.0 has necessitated a deeper understanding of sustainable supply chain development, particularly within organic agricultural cooperatives operating in rural environments. In this context, a comprehensive assessment was conducted to examine the determinants influencing sustainable supply chains and to evaluate their maturity within organic agricultural cooperatives in Vietnam’s rural regions. A sample of 250 cooperatives was selected for analysis. The data were processed through a two-stage methodology: initially employing an ordinal logistic regression (OLR) model to identify key influencing factors, followed by the application of a sustainable supply chain maturity model to assess the developmental stage of these cooperatives. The results revealed that the average maturity level of sustainable supply chains among the surveyed cooperatives approached Level 3, suggesting a moderate stage of development with partial integration of sustainability practices. Among the evaluated dimensions, quality issues (mean score: 3.53), customer and marketing management (3.22), and supplier management (3.05) were found to exert the most substantial influence on supply chain sustainability. Furthermore, policy implications were proposed to support cooperative development. The study contributes to the existing literature by offering an empirically grounded maturity model framework tailored to the unique dynamics of rural organic agriculture and by advancing the discourse on sustainable supply chain management in emerging economies undergoing industrial transformation.