Search Results (356)

Blue-green spaces are critical for diversified landscape planning. However, rapid urbanization and habitat fragmentation continue to disrupt ecological connectivity in river-basin landscapes. This study focuses on the Xiu River Basin, a major tributary of Poyang Lake and a key node of the East Asian–Australasian Flyway. We developed a multi-guild avian ecological network framework to support biodiversity-oriented landscape planning. Birds were classified into four functional guilds: aquatic resident, aquatic wintering, forest resident, and forest wintering. For each guild, we designed a specific set of environmental variables. We integrated MaxEnt and InVEST to identify ecological sources by combining habitat suitability with habitat quality. The results showed that 68.75% of the basin qualifies as good-quality habitat, although suitable habitats remained highly heterogeneous and fragmented among guilds. We identified 1839.93 km² of ecological sources, 157 corridors, 215 pinchpoints, and 344 barriers, revealing clear differences in the connectivity requirements between aquatic and forest birds and between resident and wintering birds. We further delineated four ecological priority areas and proposed targeted restoration strategies for wetlands, river–lake systems, forested mountains, and urban–rural transition zones. Overall, this study demonstrates that multi-guild connectivity analysis can provide a spatial framework for informing urban forest conservation, blue-green infrastructure planning, and diversified landscape planning in complex basin landscapes. Full article

Waste-to-hydrogen (W2H) technology is gaining recognition as a viable pathway for simultaneous waste valorisation and clean energy production in the Gulf Cooperation Council (GCC). However, the water resource implications of hydrogen production pathways in this acutely water-scarce region have received insufficient analytical attention. This paper presents the first systematic comparative analysis of water consumption across grey, blue, green, and waste-to-hydrogen production pathways calibrated to the GCC context, using the ISO 14046 water footprint framework and accounting for the desalination penalty that arises when hydrogen facilities draw on energy-intensive desalinated water. The analysis shows that green hydrogen, widely promoted in GCC national hydrogen strategies, incurs a compound water–energy burden substantially greater than global benchmark figures suggest, with electrolysis requiring 9 to 18 litres of water per kilogram of hydrogen and desalination accounting for 4 to 20 per cent of GCC electricity consumption. In contrast, W2H gasification exhibits considerably more modest water demands at 10 litres per kilogram of hydrogen, with high potential for treated wastewater substitution and co-location with municipal waste infrastructure, positioning it as the most water-compatible near-term hydrogen production pathway for arid GCC economies. Drawing on the water–energy nexus and water governance literature, the paper proposes a Water–Hydrogen Governance Framework comprising four policy pillars: water efficiency standards for hydrogen production facilities, water allocation policy for industrial hydrogen projects, integrated water–energy planning at the national level, and regional GCC coordination on water–hydrogen governance. The framework is aligned with SDGs 6, 7, 13, and 17 and provides a structured and practical tool for GCC governments and development institutions seeking to integrate water security into hydrogen strategy. The findings contribute to the emerging literature on resource-constrained hydrogen deployment and offer a replicable governance model for other arid economies pursuing clean hydrogen transitions. Full article

Urban wildscapes (UWS), characterized by low levels of management and spontaneous vegetation, are increasingly recognized as components of blue–green infrastructure with potential benefits for climate adaptation, health equity, and socio-ecological resilience. However, these benefits depend on individuals’ actual environmental exposure in daily life, which is shaped by mobility, activity patterns, and temporal constraints, leading to unequal access across social groups. Despite this, existing research has largely focused on public perceptions and acceptance of UWS, with limited attention to whether such evaluations reflect real-world exposure processes. This study conducts a systematic review of 30 empirical studies, examining spatial types, evaluation methods and media, and psychological dimensions. The results reveal three patterns: a focus on marginal spaces, the dominance of visual media and scale-based methods, and an emphasis on affective and cognitive responses over functional dimensions. These findings suggest that current research captures mediated perceptions rather than lived exposure, potentially constraining understanding of health outcomes and equity. This paper calls for a shift toward an exposure-oriented framework integrating mobility, activity spaces, and environmental contact. Full article

Nature-based solutions (NbS) are increasingly promoted in European policy for their potential to support climate adaptation and contribute to human health. Yet evidence on their health impacts remains fragmented across disciplines and limited to specific health outcomes or ecosystems. We carried out a systematic review of studies assessing the links between NbS and human health in Europe, covering multiple ecosystem types (agricultural, coastal, forest, mountain, urban, rural and freshwater ecosystems) and both mental and physical health outcomes. A total of 115 studies met the inclusion criteria and were concentrated in the United Kingdom (38%) and Spain (17%), with urban (45%) and forest (17%) ecosystems most frequently examined. Most studies evaluated Type 1 NbS (minimal intervention) and focused on adult populations (58%). Mental health outcomes were studied nearly twice as often as physical health, including positive mental health, circulatory diseases and mental and behavioural disorders. Nearly 88% of quantitative studies reported at least one positive association, whereas qualitative studies highlighted that perceived health benefits of NbS were often shaped by participants’ subjective experiences. Our findings emphasise the need for more longitudinal and experimental research designs, attention to NbS types and equity considerations, and better integration of human health into NbS planning and policy. Full article

Rising temperatures within the urban context, as a result of climate change and the Urban Heat Island effect, have deteriorated thermal comfort conditions in outdoor urban spaces, especially during hot, Mediterranean summer days. This study investigates the potential cooling effects of integrating individual urban green spaces into a connected network, with the aim of improving thermal conditions in public areas. Thermal conditions of an 800 m² urban area in the city of Athens, Greece, were evaluated for a typical summer day using the environmental model ENVI-met. Based on an assessment of the current microclimatic conditions, a potential thermal adaptation strategy was developed, aiming to redesign the study area as a network of green-blue infrastructure. This includes a 1.5 km walking route connecting various spaces, such as squares, parks, and schools. Air temperature (Tair) and the bioclimatic index PET (Physiologically Equivalent Temperature) were used to evaluate the thermal conditions of the study area. In addition, a new function of the ENVI-met model, Dynamic Comfort, has been implemented to calculate the dynamic Physiological Equivalent Temperature (dPET) index for the selected route. The results revealed significant Tair and PET reductions compared to the current layout, indicating that the integration of open spaces into a network of green-blue infrastructure can improve thermal conditions and reduce the hazardous effects of thermal stress on people. Some notable results include the spatial and temporal decrease of the Tair of up to 6 °C, mainly in the proximity of buildings and fountains. Similarly, PET values decreased mainly by 3 to 5 °C. The Dynamic PET showed a slight reduction during the hours of maximum temperature and a higher decrease during the evening, ranging from 1 to 2 °C. Full article

Amid rapid urbanisation and the associated environmental challenges, such as increased flood risk, the urban heat island effect, and ecosystem degradation, Blue–Green Infrastructure (BGI) has emerged as a vital sustainable development strategy. Some countries have successfully implemented BGI projects, shaped by their unique geographical conditions, socioeconomic contexts, and governance structures. Although the BGI concept is highly relevant worldwide, strategies for integrating BGI into urban environments vary significantly across regions and countries due to their distinct urban structures and spatial planning systems. This study provides a comparative study of BGI implementation into spatial planning systems of Ljubljana (Slovenia) and Kraków (Poland), as Central European cities, and Shanghai and Guangzhou, as Chinese cities. Through a systematic analysis of semi-structured interviews with key stakeholders, the study evaluates how different enablers, i.e., (1) guidelines, strategies, and actions, (2) land-use strategy for BGI, and (3) potential of factors for BGI implementation, including planning scale, financial, technical, and spatial, facilitate BGI implementation. This comparative study reveals contrasting yet complementary BGI paradigms, most notably related to top-down versus bottom-up implementation and different prioritisation of BGI functions. These varying paradigms are shaped by specific urban challenges, governance, and spatial planning systems. Full article

With global warming and the increasing frequency of extreme heat events, heat health risk assessment (HHRA) has become a critical topic in climate change studies. However, the study themes, methods, and governance orientation of HHRA vary significantly across spatial scales, limiting the comparability and practical integration of assessment outcomes. This study conducts a review of the HHRA literature from 2007 to 2025, analyzing publication trends and evolving research paradigms. The results indicate the following: (1) rapid growth in the field with a notable shift from identifying static vulnerabilities to adopting “Hazard–Exposure–Vulnerability–Adaptability” (HEVA) frameworks, particularly at the micro-scale; (2) a clear scale-dependent hierarchy in assessment focus, where macro-scale studies identify regional trends, meso-scale research targets urban spatial heterogeneity and green–blue infrastructure, and micro-scale assessments emphasize housing conditions and individual perceptions; and (3) machine learning has been widely applied to capture complex nonlinear mechanisms and threshold effects. Finally, this study further emphasizes the importance of establishing a full-process feedback mechanism from macro-level early warning to meso-scale planning and micro-scale intervention, bridging the gap between regional policy and community-level action and providing a theoretical foundation for building climate-resilient cities. Full article

Urban water–vegetation systems play an important role in mitigating surface heat, yet the spatial decay structure of shoreline-mediated cooling remains insufficiently quantified in high-density urban environments. Focusing on seven urban water bodies within the heritage buffer zone of the Beijing Central Axis, this study combines 120 m shoreline segmentation with 0–600 m ring-buffer analysis to examine seasonal shoreline cooling patterns using Landsat-derived land surface temperature (LST) and Sentinel-2 vegetation information. The results show that shoreline cooling followed a layered spatial decay structure rather than a single fixed-distance effect. The most rapid LST increase generally occurred within the first 200 m from the shoreline, forming a nearshore rapid-gradient zone, while cooling distance (CD) represented a broader outward reach of detectable cooling. Cooling intensity (CI) was strongest in summer, whereas the seasonal differentiation of CD was weaker than that of CI. Vegetation greenness was generally negatively associated with LST, especially in the near and middle shoreline zones, and this relationship was supported by the same-date Landsat NDVI robustness test. After controlling for built-up intensity and waterbody-specific differences, shoreline distance, vegetation greenness, and built-up intensity mainly operated as additive spatial predictors of LST, while the NDVI × Distance interaction provided limited additional explanatory power. These findings suggest that shoreline cooling in high-density heritage urban areas should be understood as a spatially differentiated interface process, and that planning should prioritize the nearshore rapid-gradient zone while managing the broader shoreline transition area according to local vegetation and built-up conditions. Full article

Green and blue-green infrastructures are key for reducing the effects of urban heat islands driven by rapid city expansion. However, the spatial relationship between land-cover patterns and air-temperature distribution, plus the combined cooling effects of green and blue spaces, remains insufficiently explored. This study applies the InVEST Urban Cooling Model to analyze the spatiotemporal changes in land use and their impact on the heat-mitigation service provided by green and blue spaces in the city of Arequipa, Peru, between 2006 and 2024. Furthermore, land-use change is projected for 2030 using the CA-Markov model and the InVEST Scenario Generator tool. These projections enabled the evaluation of two heat-mitigation scenarios by modifying the spatial distribution of green, blue-green, and urbanized areas. The findings indicate that urbanized areas doubled over the measurement period. The greatest loss of agricultural land and tree-covered areas occurred between 2020 and 2024, with a decline of up to 5%. Correspondingly, the percentage of low heat mitigation index areas (0.1–0.2 and ≤0.1) increased by 3.8%, reaching a total increase of up to 6.7%. Scenario simulations showed that reducing both green and blue-green infrastructure had similar impacts on the heat-mitigation index, providing valuable insights for urban planning and environmental management. Full article

This manuscript creates a framework for decision support based on green urbanism to direct the sustainable development of Gamasa, an Egyptian seaside city. The paper aims to convert the concepts of green urbanism into a multi-criteria evaluation that can support strategic urban development and prioritize spatial interventions. Sustainable mobility, green and blue infrastructure, energy and resource efficiency, urban form and density, social livability and public space quality, and governance and implementation feasibility are the six dimensions that are defined. These dimensions are derived from international sustainability literature and tailored to Gamasa’s particular challenges. The study’s methodology combines a multi-criteria decision-making approach based on the AHP with spatial analysis of land use, street hierarchy, building shape, and green space distribution. Weights for these dimensions are determined by expert-based pairwise comparisons, which are backed by a SWOT analysis. To prioritize priority zones for green transformation, the weighted framework is applied to four important urban areas: residential districts, a large urban park, the waterfront, and the main urban corridor. The top priorities, according to the results, are climate-responsive coastal design, increased green and blue infrastructure, and sustainable transportation. For quickly urbanizing coastal cities, the method demonstrates how the AHP operationalizes green urbanism into quantifiable, context-sensitive goals. Full article

This study assesses the configuration potential of embedded outdoor sports facilities in high-density urban areas in response to persistent challenges related to supply–demand imbalance, limited accessibility, and low spatial efficiency under stock-based urban renewal. Embedded sports facilities, characterized by multifunctional land use and efficient resource integration, offer a promising pathway to alleviate these pressures. This study proposes a multidimensional framework to assess configuration potential by integrating multi-source data, spatial analysis, and quantitative evaluation methods. The assessment system is structured around three core dimensions: supply–demand improvement, use convenience, and environmental suitability. The TOPSIS model is applied to evaluate the configuration potential of 1268 parcels at the micro-scale. Results reveal a spatial pattern characterized by clustered low-potential parcels in central areas and scattered high-potential parcels in peripheral zones. The results reveal that low-potential clusters notably coincide with areas characterized by concentrated educational land uses and complex natural topographic conditions. Notably, more than 40 percent of high-potential parcels are located within blue–green infrastructure spaces. These findings provide practical evidence to support precise sports facility planning and community-scale renewal strategies in high-density urban environments. Full article

StoryMapping has emerged as an accessible geotechnological approach that combines spatial analysis, interactive cartography and digital storytelling to communicate urban landscape transformations. This study aims to demonstrate the methodological potential of StoryMaps for integrating historical cartography, GIS-based analysis and narrative visualisation to explain long-term urban landscape change in an accessible and scientifically rigorous way. Using a case study of Madrid, the research integrates more than 150 years of historical maps, georeferenced images and thematic GIS layers to visualise shifts in blue–green infrastructures, land-use patterns and morphological configurations. The methodology includes the compilation of historical cartographic sources, GIS processing of contemporary datasets, georeferencing of archival materials and the construction of an interactive narrative using ArcGIS Pro 3.6 StoryMaps. Results show that StoryMapping enhances public understanding of complex urban processes, supports participatory planning, and provides a bridge between technical analyses and community engagement. The study concludes that StoryMapping is not only a powerful communication tool but also a valuable geotechnological solution for sustainable landscape planning, complementing traditional GIS approaches and promoting interdisciplinary perspectives in urban studies. Full article

Urban destinations increasingly incorporate green–blue infrastructure, sensory-balanced public spaces, and microclimate-responsive design to mitigate visitor fatigue and support sustainable tourism experiences. To understand how insights from broader tourism environments, particularly nature-based contexts, can inform emerging urban well-being strategies, this study conducts a global bibliometric review (2005–2025) on psychological restoration, stress relief, and visitor well-being. Using Scopus and a Boolean search combining mental health constructs, tourism setting, and analytical approaches, 825 records were identified, and 149 articles were retained after applying eligibility criteria. Science mapping and performance analyses reveal accelerated post-2018 growth and three dominant knowledge clusters centered on restoration pathways, environmental determinants, and behavioral/hospitality components. Based on these patterns, this study introduces the RESTOR-URBAN model, integrating environmental moderators, psychological mechanisms, and behavioral interactions that jointly shape stress reduction and emotional well-being across urban tourism systems. The results show increasing relevance of micro-restorative experiences, thermal comfort management, and stress-aware service design, while highlighting persistent methodological heterogeneity and limited integration of environmental co-data (Universal Thermal Climate Index (UTCI), Physiological Equivalent Temperature (PET), and Discomfort Index (DI)). The findings suggest that restoration-based evidence from nature-based tourism can inform sustainable urban tourism planning, hospitality practice, and visitor experience design, and propose a research agenda emphasizing standardized well-being indicators, longitudinal and structural equation modeling (SEM)-based approaches, and environmental quality variables for resilient, health-oriented urban destinations. Full article

Biogas production through anaerobic digestion is increasingly recognised as a strategic renewable energy pathway capable of addressing South Africa’s energy insecurity, organic waste management challenges, and climate mitigation goals. However, the water-intensive nature of anaerobic digestion raises critical sustainability concerns in water-scarce regions. This systematic review critically examines the water footprint of biogas-based bioenergy systems, with a specific focus on South Africa’s water-stressed context, to understand how water availability, feedstock selection, digester configuration, and governance frameworks influence system viability and scalability. This study adopts a systematic literature review (SLR) approach guided by the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) methodology; peer-reviewed literature published between 2010 and 2025 was retrieved from Scopus and Web of Science and synthesised through descriptive analysis and qualitative meta-synthesis. The review integrates blue, green, and greywater footprint concepts to assess water use across diverse biogas pathways, including livestock manure, agricultural residues, food waste, wastewater sludge, and aquatic biomass. Findings indicate that wet digestion systems, dominant in South Africa, are highly sensitive to freshwater availability, particularly where slurry dilution relies on blue water. In contrast, wastewater-integrated, semi-wet, and co-digestion systems substantially reduce freshwater demand while enhancing methane yields and process stability. The reuse of greywater, industrial effluents, and digestate emerges as a key strategy for lowering water footprints and strengthening circular water–energy linkages. Despite strong technical potential, the adoption of water-efficient anaerobic digestion systems remains constrained by fragmented governance, infrastructure deficits, and limited empirical data on dry and low-water digestion technologies. The review concludes that embedding water footprint considerations into bioenergy planning, policy, and system design is essential for the sustainable expansion of biogas in South Africa. Integrated water–energy–waste governance, coupled with targeted technological innovation, is critical to ensuring that biogas development enhances both energy security and water sustainability in water-scarce regions. Full article

Climate-driven intensification of pluvial and fluvial flooding increasingly challenges lowland cities in Central Europe, while conventional protection and land-use controls offer limited flexibility under growing hydrological variability. A planning-oriented framework is developed and tested to integrate hydro-adaptive housing into climate-resilient urban development using three typologies: elevated foundations, amphibious dwellings and modular floating platforms. The framework links hazard profiles and site-enabling conditions to typology selection and considers supporting blue–green measures within the broader adaptation context. It is applied to three flood-prone settings in northern Poland representing a coastal delta, a river confluence and a lower-river terrace. The methodology combines GIS-based hazard mapping; one-dimensional unsteady-flow HEC-RAS simulations for 50-, 100- and 500-year design events; and parametric structural modelling in Rhino–Grasshopper. Performance is assessed using maximum inundation depth, surface-water retention time, and a probabilistic building damage index. Amphibious dwellings reduce modelled 100-year flood damage by 62% relative to slab-on-grade construction, while modular floating platforms maintain habitability under water-level rises exceeding 5.0 m. In addition, bioretention and blue–green corridors reduce retention time by 18–31%. The results provide a planning-oriented decision logic for expanding adaptive housing options in flood-prone lowland settings under increasing hydrological variability. Full article