Search Results (2,473)

Urban wastewater treatment plants face increasing challenges in mitigating environmental impacts while achieving high treatment efficiency. This study explores the optimization of quorum-quenching (QQ) media materials for scalable membrane bioreactor (MBR) applications, focusing on their potential to reduce operational footprints and enhance sustainability. Six immobilization media were evaluated—sodium alginate (SA), polyvinyl alcohol (PVA) beads (P), magnetic beads (M), chitosan magnetic beads (CM), polymer-coated beads (PS), and flat media (SAP)—using a multi-criteria decision analysis (MCDA) framework. Key parameters, including porosity, mechanical strength, quorum-quenching activity, and durability in sludge, were quantitatively weighted according to their operational significance. SA demonstrated the most balanced performance, exhibiting superior durability and cost-effectiveness, whereas SAP showed potential in applications prioritizing high porosity and enhanced QQ activity. The incorporation of QQ media led to a significant reduction in membrane fouling, chemical consumption, and energy consumption in pilot-scale MBR systems. Ecological footprint assessment revealed a 15% reduction in indirect blue water footprints and a 20% decrease in Scope 2 carbon emissions, attributable to reduced operational energy demands. These findings highlight the efficacy of QQ media in improving MBR performance and advancing system-level sustainability. Overall, this study highlights the critical importance of material engineering and ecological footprint integration in the development of next-generation urban wastewater treatment technologies. Full article

Mountain pastoralism in the Pyrenees has undergone profound transformations in recent decades, driven by socio-economic change, rural depopulation, and the adoption of new technologies. This study examines the evolution of shepherding practices in the Jacetania region of the Western Spanish Pyrenees, with a focus on the interplay between technological innovation and the preservation of traditional ecological knowledge (TEK), which includes a detailed understanding of pasture dynamics, animal behavior, and environmental conditions that guide grazing management. Drawing on interviews with experienced shepherds, and participant observation, we compared historical management of the Collarada mountain pasture—previously under continuous human supervision—with its current use under free-grazing conditions monitored via GPS. The results show a shift from continuous human oversight to technology-assisted management, with reduced labor demands, while traditional ecological knowledge remains essential for effective grazing decisions and adaptation to environmental conditions. We argue that combining modern technologies with the experiential knowledge of pastoralists offers the best pathway toward sustaining both the ecological integrity of high-altitude landscapes and the cultural continuity of pastoral traditions. These findings have the potential to generate broader impacts beyond the study area, contributing to improved ecosystem management, supporting rural livelihoods, and informing policy frameworks aimed at sustaining mountain pastoral systems. Full article

Driven by increasing demand in the health and wellness industry, Traditional Chinese Medicine (TCM) agriculture currently faces significant challenges related to supply–demand imbalances and continuous cropping obstacles (CCOs). Intercropping and crop rotation can mitigate yield decline and environmental stress by improving microclimates and rhizosphere ecology. However, there is still a lack of bibliometric synthesis within this research area. To analyze research hotspots and evolutionary trends, 192 articles on the intercropping and crop rotation of medicinal plants were collected from the Web of Science Core Collection (1998–2025), including databases such as the Science Citation Index Expanded (SCIE), the Social Science Citation Index (SSCI) and the Conference Proceedings Citation Index (CPCI). The results revealed a steady increase in publication volume over time. China emerged as the most prolific contributor (93 articles), while the United States occupied a pivotal position in the global collaborative network, achieving a high centrality of 0.90. Research hotspots in this field have evolved from an early emphasis on plant yield and quality toward the mechanisms for alleviating CCOs, interspecific interactions within the rhizosphere microbiome, and the ecological management of soil health. Keyword bursts indicate that “microbial community” and “carbon” have emerged as the current research frontiers. To clarify the micro-mechanisms by which intercropping and crop rotation patterns mitigate or prevent CCOs, future research should prioritize the integration of multi-omics approaches to resolve molecular interactions within the “microbe–plant–soil” nexus. Key priorities include the development of functional Synthetic Microbial Communities (SynComs) and the establishment of comprehensive evaluation systems for ecological cultivation. Furthermore, aligning these models with global climate neutrality strategies would facilitate the balance between high-quality medicinal production and ecosystem stability. Full article

Rapid urbanization in plateau mountain regions exacerbates the tension between rigid resource demands and fragile ecological carrying capacities. Enhancing the resilience of the Water–Energy–Food (W–E–F) nexus is therefore essential for coping with external shocks. This study constructs a multidimensional resilience evaluation framework based on the Pressure-State-Response (PSR) model, taking the Kunming Metropolitan Area—a typical plateau mountain region—as a case study. Integrating the TOPSIS model, Coupling Coordination Degree (CCD) model, and spatial autocorrelation analysis, we systematically assessed both individual subsystem and comprehensive W–E–F nexus resilience from 2005 to 2020. Results show that W–E–F nexus resilience generally improved from 2005 to 2020, but subsystem development remained uneven across space, with water resilience characterized by a peripheral-high/central-low pattern, energy resilience by a core-high/periphery-low structure, and food resilience by the strongest spatial heterogeneity and volatility. By 2020, the mean comprehensive resilience reached 0.67, with 58.3% of counties above the average, exhibiting significant spatial clustering. Based on resilience levels and limiting subsystems of 2020, the metropolitan area was classified into Enhancement, Adjustment, and Maintenance zones, comprising 6, 16, and 2 counties respectively, to support differentiated regional governance. This study provides a spatially explicit regulation paradigm to bolster urban resilience against resource constraints and climate uncertainty. Full article

China’s rural public open spaces (POS) are largely governed as common-pool resources through self-organized collective arrangements, often regarded as a viable pathway to sustainable commons management. Yet, in practice, these systems remain prone to overuse and under-maintenance, reflecting collective action failures associated with the tragedy of the commons. The governance of rural POS therefore constitutes a complex social–ecological problem shaped by the interplay of institutional rules, biophysical conditions, and user–stakeholder interactions. Taking Taigu District in Shanxi Province—characterized by heterogeneous social–ecological contexts and collective action dilemmas—as the empirical case, this study develops a meso-level baseline model to identify the key conditions (design principles) for sustainable rural POS governance. Adopting an expert-based epistemological approach, 24 specialists in rural governance (scholars, planners, and local administrators) were engaged. Grounded in commons and collective action theories within the Social–Ecological Systems (SES) framework and informed by Transaction Cost Economics (TCE), the study operationalizes a Delphic Hierarchy Process (DHP), combining three rounds of Delphi to establish consensus on governance conditions with the Analytic Hierarchy Process (AHP) to derive their relative weights. The model specifies 14 governance conditions across four interrelated dimensions: ecological (e.g., clearly defined resource boundaries and congruence between resource characteristics and user needs), institutional (e.g., simple and enforceable rules, accessible conflict-resolution mechanisms, accountable monitoring, and calibrated external support), social (e.g., social capital, leadership capacity, clearly defined user boundaries, and group interdependence), and interactional (e.g., resource dependence, equity in benefit distribution, and supply–demand alignment). It further clarifies their relative importance and systemic interdependencies. By operationalizing commons design principles within a meso-level analytical framework, the study advances their empirical application in rural planning and offers five targeted managerial implications to strengthen institutional robustness and the long-term sustainability of self-governed rural POS. Full article

The digital transformation has intensified demands for university teachers to develop technology-enhanced teaching competence, especially under China’s High-Quality Course initiative for blended learning excellence. While existing well-recognized frameworks (e.g., TPACK, DigCompEdu) provide valuable foundational guidance, they inadequately capture the dynamic, ecological processes through which teachers systematically reconstruct curricula and professional identities in blended contexts. This study addresses this gap by proposing an ecological model of competence development, building on the strengths of existing frameworks while capturing the dynamic interplay between teachers, technology, and blended environments. Using a qualitative multiple-case design, we conducted semi-structured interviews with six national recognized exemplary university English teachers. Data were analyzed via Braun & Clarke’s six-phase thematic analysis in MaxQDA. Findings reveal that technology-enhanced teaching competence comprises five co-evolving dimensions: Curriculum Empowerment (systematic course redesign), Role Transformation (shifting from lecturer to learning designer), Environment Integration (orchestrating online-offline spaces), Technology Application (selective tool use), and Competence Spanning (transferring expertise across contexts). These dimensions form an ecological system: when teachers redesign curricula, they simultaneously rethink their professional identities; when they adopt technologies, they reshape classroom environments; and when all four dimensions align, higher-order spanning competence emerges naturally. Theoretically, this ecological model advances beyond technology addition by illuminating relational mechanisms and emergent properties of competence. Practically, it informs a shift from fragmented tool-training to systemic faculty support architectures that honor the complexity of blended teaching transformation. Full article

Rattans of the genus Korthalsia are ecologically and economically important non-timber forest resources in Southeast Asia, yet their conservation is limited by knowledge of species-specific distribution patterns and environmental constraints. We modeled the potential distributions of four Korthalsia species (K. flagellaris, K. laciniosa, K. rigida, and K. scortechinii) using species distribution models (SDMs). Models were fitted in R using the sdm package, and ensemble maps were generated by combining predictions from Random Forest (RF), Generalized Linear Models (GLMs), Generalized Additive Models (GAM), and GLMnet. The top predictors influencing habitat distribution included soil physical structure, atmospheric moisture demand, and canopy light availability. The dominance of these factors reflects three distinct and non-interchangeable environmental axes that regulate belowground moisture dynamics, atmospheric constraints on gas exchange, and the energetic requirements for recruitment. All four species ensemble models significantly outperformed the null model, and spatial block cross-validation (k = 5, 200 km blocks) indicated a marginal drop in area under the curve (AUC) values, confirming a predictive signal under geographically independent evaluation. Ensemble suitability maps identified Peninsular Malaysia, Borneo, and Sumatra as centers of predicted habitat. Core habitat was estimated to be less than 0.6% of total suitable area for all species, ranging from 980 km² (K. scortechinii) to 19,256 km² (K. rigida), with anthropogenic modification exceeding 50% in the core habitat in K. flagellaris and K. rigida. These results provide the first species-specific baseline for these Korthalsia across Southeast Asia, supporting more targeted conservation and restoration planning under varying habitat constraints. Full article

The United States faces a maternal health crisis marked by stark racial disparities. Although doula support has emerged as an evidence-based intervention to improve perinatal outcomes by addressing social determinants of health, its integration into healthcare systems remains limited. This qualitative study, informed by phenomenological principles, examined multi-level experiences, perceived barriers, and perceived facilitators of integrating doula services into perinatal care systems and their intersection with health equity goals. We conducted 17 semi-structured interviews with 20 participants across Nebraska and Tennessee, including doulas, midwives, physicians, Medicaid administrators, and public health professionals, and analyzed data using reflexive thematic analysis guided by the Socio-Ecological Model. Three themes emerged: the integration paradox, an overarching theme capturing tensions between doula independence and healthcare system demands for standardization, including divergent views on practice models, provider dynamics, and certification; sustainable financing as the prevailing barrier, encompassing grant limitations, private pay inequities, absent Medicaid reimbursement, and the need for cost-effectiveness evidence; and cultural concordance as the prevailing facilitator, including cultural matching, addressing social determinants, and lived experience as motivation. Sustainable doula integration requires reconciling system demands for standardization with the relational, culturally responsive characteristics that define effective care, through Medicaid reimbursement pathways and policy reforms developed in partnership with doula communities. Full article

Background: Fetal alcohol spectrum disorders (FASDs) are lifelong neurodevelopmental conditions resulting from prenatal alcohol exposure. Despite high FASD rates in high-risk adoptive populations, little is known about the experiences of adoptive parents in Israel, where underdiagnosis and limited professional awareness persist. Drawing on ecological and family systems theory, this study explored the daily challenges, coping strategies, and service-related barriers encountered by adoptive parents raising children with FASD. Methods: Using a qualitative, exploratory design, semi-structured interviews were conducted with 12 adoptive parents of children aged 9–18 years with a parent-reported clinical diagnosis of FASD made by a healthcare professional. The interviews focused on child-related difficulties, coping mechanisms, diagnostic experiences, and interactions with health, education, and welfare systems. The data were analysed using reflexive thematic analysis. Results: Five themes were identified: (a) child-related neurodevelopmental and behavioral challenges, (b) emotional and practical caregiving burden, (c) systemic barriers, including limited professional knowledge and fragmented diagnostic pathways, (d) coping strategies and family strengths, and (e) unmet needs and recommendations. Parents described fluctuating child functioning, chronic caregiving demands, and significant gaps in diagnostic and educational support. Conclusions: Adoptive parents raising children with FASD face substantial daily challenges compounded by systemic limitations. This study’s findings underscore the need for improved professional training, clearer diagnostic pathways, FASD-informed educational practices, and coordinated multidisciplinary services. These results provide direction for policy and service development to improve support for families affected by FASD. Full article

The rapid demand for sustainable and efficient energy storage solutions has prompted the pursuit of eco-friendly electrode materials. Biomass-derived carbons from food waste offer a promising pathway to meet this need by combining waste valorization, environmental benefits, and high electrochemical performance. This review highlights that food waste biomass is an effective and inexpensive source of precursors for producing high-performance carbon materials for supercapacitors. Food waste, which includes fruit peels and vegetable residues, cereal husks, and oilseed residues, is a good source of lignocellulosic components, heteroatoms, and structural features that determine the electrochemical characteristics of the derived carbons. These wastes produce hierarchically porous carbons with high surface areas (>1500 m² g⁻¹) on pyrolysis and activation that provide superior ion transport, wettability and pseudocapacitive behaviour. Their electrochemical performance includes capacitances up to 520 F g⁻¹ and energy densities of 35–70 Wh kg⁻¹ in optimized systems, particularly under extended voltage windows or in hybrid supercapacitor configurations, and high cycling stability is equal to or even better than traditional carbons such as activated carbon and graphene. Additionally, biomass valorization contributes to a high level of greenhouse gas capture, decreases landfill, and correlates with the idea of a circular economy. The commercialization potential of biomass-based supercapacitors is supported by recent developments in AI-based optimization, combined with scalable synthesis methods, which would support ecologically, economically, and technologically sustainable energy storage on a large scale. Full article

Achieving sustainable development requires moving beyond pollution metrics to holistic measures, such as the load capacity factor (LCF), which balances ecological demand and supply. While recent studies have provided important insights into the determinants of LCF in OECD countries, further research is needed to incorporate additional determinants and updated estimation approaches. This study addresses this gap by examining the impacts of financial innovation, forestry, urbanization, population, and economic growth on the LCF in Organization for Economic Cooperation and Development (OECD) economies from 1990 to 2023. Using second-generation panel econometric methods, including tests for cross-sectional dependence, slope heterogeneity, second-generation unit roots, and cointegration techniques, this paper confirms a stable long-run relationship among the variables. The core analysis applies the method of moments quantile regression to uncover the heterogeneous effects across the LCF distribution. The results indicate that financial innovation consistently enhances the ratio of biocapacity to ecological footprint. In contrast, economic growth and urbanization exert significant negative pressure on the LCF, whereas population size shows a uniformly detrimental effect. Forestry has a positive but less pronounced influence. Robustness checks using fully modified ordinary least squares, dynamic ordinary least squares, and panel-corrected standard errors confirm these results. The present study concludes that targeted financial innovation and stringent urban demographic policies support OECD nations in improving ecological balance and reducing ecological deficits. Full article

Dietary transition is reshaping cropland demand and intensifying the challenge of matching food demand with land supply in rapidly urbanizing regions. This study examines how different dietary structure scenarios generate differentiated cropland demand, how these demands match with land supply under alternative development pathways, and how the land system responds when diet-driven demand is incorporated into land-use simulation. Using Jiangsu Province, China, as a case study, we developed a coupled diet–land simulation framework. On the demand side, five dietary structure scenarios—current, balanced, U.S., Japanese, and Greek—were constructed based on seven food categories, and their cropland demand in 2035 and 2050 was estimated using the cropland footprint approach and LSTM forecasting. On the supply side, the GeoSOS-FLUS model was used to simulate future land-use patterns under four development scenarios: natural development, cultivated land protection, ecological protection, and economic development. The cropland demand associated with each dietary scenario was then introduced into the land-use simulation process as an external demand constraint to identify land-system feedbacks and scenario differences. The results show that cropland demand differs markedly across dietary scenarios, forming a clear gradient from moderate-demand to high-demand diets. These differences are driven primarily by changes in the composition of key food categories, especially grains, livestock and poultry meat, plant oils, and fruits, rather than by proportional increases across all foods. In terms of supply–demand matching, the cultivated land protection scenario provides the strongest support for high-demand diets, whereas the natural development, ecological protection, and economic development scenarios are more compatible with moderate-demand dietary pathways. Once diet-driven demand is incorporated into land-use simulation, the land system shows clear sensitivity and strong scenario dependence. High-demand dietary scenarios intensify cropland compensation pressure and trigger structural reallocation among cultivated land and flexible land types. Under natural development, the response is mainly reflected in cropland expansion and grassland compression; under cultivated land protection and ecological protection, it is expressed more through substitutions among grassland, water bodies, and unused land; under economic development, the most prominent feedback is the competitive reallocation among cultivated land, construction land, and water bodies, with high dietary demand even constraining construction land expansion. Overall, the robustness of cropland supply–demand matching depends not only on the scale of dietary demand but also on how different dietary pathways interact with development-oriented land-use structures. Full article

The Andean walnut (Juglans neotropica Diels), locally known as tocte, is a keystone tree species of major socio-ecological importance in South American mountain ecosystems, facing severe anthropogenic pressure associated with genetic erosion, habitat fragmentation, and unregulated selective logging. This article presents a case study applying a qualitative phenomenological approach to examine the power relations and institutional failures shaping the sustainable management of its value chain in Imbabura Province, Ecuador. Drawing on 21 in-depth semi-structured interviews with key actors (including woodcarvers, sawyers, traders, and environmental authorities) conducted between March and September 2025 until theoretical saturation was achieved, and supported by thematic analysis in ATLAS.ti, we identified five thematic categories revealing the tension between cultural valuation and market pressure. The findings confirm the existence of a value paradox, whereby high timber demand paradoxically accelerates resource depletion rather than incentivizing conservation, as premature harvesting of young trees undermines the viability of non-timber forest products such as nuts and accelerates the loss of local genetic resources. We conclude that the long-term conservation of the species requires a transition toward polycentric stewardship, community forestry enterprises, and integrated landscape management in which the standing tree is formally recognized as carrying greater ecological and economic value than harvested timber. Full article

Background: South African university students face escalating levels of psychological distress driven by academic overload, financial precarity, and social challenges. Health professions students are particularly vulnerable due to the demanding nature of clinical training and repeated exposure to human suffering. Aim: This study aims to propose an Integrated Student Well-being and Resilience Model tailored to the South African health professions education context. Methods: This conceptual paper draws on empirical evidence from South African studies on student mental health, global campus well-being frameworks, and socio-ecological theory. Bronfenbrenner’s Socio-Ecological Systems Theory and a tiered public health approach were synthesized to develop a multi-level model aimed at addressing the academic, financial, and social determinants of student mental health. Conceptual synthesis: The study unequivocally identified a syndemic of interconnected factors predisposing students to depression, which included the interplay of academic rigour and cognitive burnout, financial vulnerability as a determinant of mental health, the crisis of social connection and psychological safety, and institutional failure and the resilience fallacy. Conclusions: The Integrated Student Well-being and Resilience (ISWR) Model is a systemic architecture designed to coordinate institutional governance with the complex psychosocial needs of health professions students. The model provides a holistic, scalable framework for strengthening student well-being within health professions education. By shifting from reactive counselling to proactive, system-level interventions, the model offers a strategic blueprint for creating resilient, supportive learning environments capable of improving student mental health and fostering a healthier future healthcare workforce. Full article

The synergistic and mutually reinforcing relationship between the development of the new energy industry and comprehensive land consolidation is crucial for integrating ecologically fragile areas into the national “dual carbon” goals and supporting regional high-quality development. Based on a systematic literature review, field investigations in typical regions, and multi-case comparative analysis, this paper analyzes the challenges and opportunities for the new energy industry in ecologically fragile areas as well as the mutually reinforcing mechanisms between new energy industry development and land consolidation. On this basis, it explores pathways for comprehensive land consolidation in coordination with new energy development. Building on local practices, it further identifies five typical models. The results show the following: (1) The development of the new energy industry in ecologically fragile areas faces multiple challenges, including a fragile ecological environment, inadequate infrastructure, a mismatch between resource supply and demand, and land use conflicts. Against the backdrop of the energy transition, breakthroughs in key technologies, and the guidance of territorial spatial planning, the value of wind and solar resources in these areas are becoming increasingly prominent, offering broad prospects for the new energy industry. (2) The development of the new energy industry and comprehensive land consolidation in ecologically fragile areas are mutually reinforcing. Factors such as resource endowment, ecological constraints, new quality productive forces, and investment and financing mechanisms interact and integrate with each other, resulting in diversified synergistic pathways. (3) Based on the priorities of new energy industry development and the primary objectives of consolidation, five models are identified: Ecological Restoration-led Model, Resource Development-led Model, Industrial Collaboration-led Model, Technological Innovation-led Model and Integrated Development Model. Each model has distinct priorities and applicable scenarios. This study will provide a reference for new energy development and sustainable development in ecologically fragile areas, including desertified and Gobi desert areas, coal mining subsidence areas, and areas rich in wind, solar, and hydropower resources. Full article