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Keywords = green façades

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29 pages, 16028 KB  
Article
Quantifying Natural and Built-Cultural Color Relationships for Architectural Color Control in a Traditional Mountain Village: A Case Study of Qingmuchuan, China
by Jiarui Yang, Yuan Liu and Xiaoyue Liang
Buildings 2026, 16(13), 2648; https://doi.org/10.3390/buildings16132648 - 2 Jul 2026
Viewed by 187
Abstract
Conservation-oriented renewal of traditional rural settlements increasingly requires evidence-based color control that considers both natural environmental backgrounds and built-cultural interfaces. This study examined whether built-cultural colors in a traditional mountain village are differentiated from natural environmental colors in hue composition while remaining proximate [...] Read more.
Conservation-oriented renewal of traditional rural settlements increasingly requires evidence-based color control that considers both natural environmental backgrounds and built-cultural interfaces. This study examined whether built-cultural colors in a traditional mountain village are differentiated from natural environmental colors in hue composition while remaining proximate in NCS attribute space and explored how such quantitative findings can inform carrier-specific architectural color-control guidance. Taking Qingmuchuan Village in the Qinba Mountain region as a case study, 145 representative color samples were recorded, including 59 natural environmental samples and 86 built-cultural environmental samples. The samples were encoded using the Natural Color System (NCS) and their hue composition, blackness–whiteness–chroma attributes, nonparametric differences, exploratory structural order assessment, and attribute-space proximity were analyzed. Among the retained carrier-oriented samples, natural environmental samples were dominated by green-yellow hues (54.2%), whereas built-cultural environmental samples mainly contained yellow-red, red-blue, and neutral hues (31.4%, 18.6%, and 12.8%, respectively). Blackness did not differ significantly between the two systems, while whiteness and chroma differed significantly; the mean pairwise cosine similarity was 0.824, indicating attribute-space proximity rather than direct hue correspondence. Based on these empirical results, the study proposes provisional, carrier-specific guidance for facade renewal, roof and eave replacement, paving repair, and signage regulation. Full article
(This article belongs to the Section Architectural Design, Urban Science, and Real Estate)
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27 pages, 1659 KB  
Article
Parametric Multi-Criteria Sustainability Assessment of Building Renovation Elements: A BIM-Based Three-Pillar Framework
by Maria Grazianova, Andrea Hrubovcakova, Ivana Halaszova and Peter Mesaros
Buildings 2026, 16(13), 2640; https://doi.org/10.3390/buildings16132640 - 2 Jul 2026
Viewed by 167
Abstract
The building renovation sector is under growing pressure to balance environmental responsibility, economic efficiency, and occupant well-being simultaneously. Existing evaluation approaches are predominantly finance-driven, marginalising ecological and social dimensions. This study develops and validates a parametric multi-criteria assessment framework for building renovation elements, [...] Read more.
The building renovation sector is under growing pressure to balance environmental responsibility, economic efficiency, and occupant well-being simultaneously. Existing evaluation approaches are predominantly finance-driven, marginalising ecological and social dimensions. This study develops and validates a parametric multi-criteria assessment framework for building renovation elements, structured around the three pillars of sustainability: environmental, economic, and social. A dataset of 33 renovation elements—encompassing green façade systems, extensive and intensive green roofs, interior wall, floor, and ceiling solutions, and exterior envelope and site components—was compiled and digitized as BIM objects in ArchiCAD 26, enriched with non-graphic parameters including cost, lifespan, recyclability, eco-index, maintenance effort, and qualitative social descriptors. Parameters were aggregated using type-specific logic: additive summation for economic indicators, minimum-value selection for lifespan, arithmetic mean for environmental indicators, and descriptive consolidation for social attributes. Five renovation scenarios (A–E), each composed of nine elements, were evaluated to demonstrate how the sustainability profile changes with selection priorities. Scenarios A, B, and C confirmed single-dimension dominance (environmental, economic, and social, respectively), Scenario D achieved a balanced three-pillar profile, and Scenario E revealed a latent economic bias in an apparently random element selection. The framework is scalable and extensible, and its data structure may provide a basis for future exploration of integration with BIM environments. Full article
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14 pages, 3514 KB  
Article
Microclimate Impacts of Urban Green Redevelopment: A Thermal Comfort Simulation in Imola, Italy
by Zhengyang Xu, Teodoro Georgiadis, Letizia Cremonini, Sofia Marini, Fausto Ravaldi and Stefania Toselli
Land 2026, 15(6), 942; https://doi.org/10.3390/land15060942 - 30 May 2026
Viewed by 364
Abstract
Urban green spaces (UGSs) are increasingly recognised as critical infrastructure for mitigating climate extremes and promoting public health; indeed, the microclimatic mechanisms through which vegetation structure translates into measurable improvements in human comfort at the neighbourhood scale are of significant interest, particularly in [...] Read more.
Urban green spaces (UGSs) are increasingly recognised as critical infrastructure for mitigating climate extremes and promoting public health; indeed, the microclimatic mechanisms through which vegetation structure translates into measurable improvements in human comfort at the neighbourhood scale are of significant interest, particularly in the context of new urban developments. This study examines the cooling effects of an urban redevelopment project in the Marconi district of Imola, Italy, using ENVI-met (Version 6.0.0, ENVI-met GmbH, Essen, Germany) simulations to compare ex ante (current) and ex post (planned) scenarios under extreme heat conditions. Physiological Equivalent Temperature (PET) was computed at the pedestrian level for both standard adult and elderly models to assess spatial patterns of thermal comfort. The results demonstrate that tree canopies are the primary determinant of local cooling, with newly planted trees reducing PET by up to 3.5 °C at the core of the regenerated block and by 1–2 °C along adjacent pavements, while grass and low vegetation provided negligible mitigation. However, new buildings generated localised warming bands of 0.5–2 °C along façades, revealing a trade-off between densification and outdoor liveability. Elderly populations experienced slightly stronger thermal stress near buildings, highlighting spatial concentrations of vulnerability. These findings reinforce the need to prioritise tree planting and canopy management as core climate adaptation strategies, while simultaneously addressing near-building heat accumulation through integrated design approaches such as façade greening and ventilation preservation. The study demonstrates the value of spatially explicit microclimate simulation for evidence-based urban planning, contributing to the development of sustainable and liveable urban environments. Full article
(This article belongs to the Special Issue Urban Ecological Indicators: Land Use and Coverage)
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38 pages, 3414 KB  
Article
Integrated Urban Climate Resilience and Sustainability Assessment System for Urban Regeneration and Building Renovation
by Jeongmin Kim, Birte Meller, Junhee Woo, Amarpreet Singh Arora and Thorsten Schuetze
Land 2026, 15(6), 920; https://doi.org/10.3390/land15060920 - 27 May 2026
Viewed by 529
Abstract
Urban areas are increasingly vulnerable to climate-related stresses such as heatwaves, flooding, and resource inefficiencies, requiring integrated, data-driven strategies to enhance resilience and sustainability. This study presents a modular assessment and planning framework that combines Geographic Information Systems (GIS), Building Information Modeling (BIM), [...] Read more.
Urban areas are increasingly vulnerable to climate-related stresses such as heatwaves, flooding, and resource inefficiencies, requiring integrated, data-driven strategies to enhance resilience and sustainability. This study presents a modular assessment and planning framework that combines Geographic Information Systems (GIS), Building Information Modeling (BIM), City Information Modeling (CIM), microclimate simulations (ENVI-met, SWMM), Life Cycle Assessment (LCA), and remote sensing within a unified decision support interface (DSI). The framework operates across multiple spatial scales—from individual buildings to entire cities—to assess climate vulnerability, support evidence-based urban regeneration, and inform sustainable renovation strategies. It enables the identification of multifunctional interventions that reduce climate risks while improving energy efficiency, resource management, and environmental quality. Urban areas are classified based on their exposure and sensitivity to climate stressors, providing a systematic basis for prioritizing adaptation and mitigation measures. The approach is validated through a case study in Daegu, Republic of Korea, a city facing an aging building stock and increasing climatic pressures. The framework is presented as a conceptual design operating at Technology Readiness Level (TRL) 3–4, indicating that it has passed its proof-of-concept, with key components including ENVI-met microclimate simulations and Sentinel-2/Landsat remote sensing processing demonstrably operational for the Daegu context. Illustrative performance benchmarks drawn from the peer-reviewed literature demonstrate that framework-guided interventions can achieve urban heat island reductions of 1.5–4.0 °C via green roof and reflective surface combinations; stormwater runoff reductions of 30–60% through sustainable urban drainage systems; and building energy savings of 25–45 kWh/m2/yr from deep façade renovation. Its modular and transferable design ensures applicability across diverse urban contexts with similar climatic and infrastructural challenges. Full article
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16 pages, 9270 KB  
Article
Performance of Coloured Building-Integrated Photovoltaic Modules: A Three-Colour East-Oriented Façade
by Nuria Martín-Chivelet, José Cuenca, Miguel Alonso-Abella, Manuel Rodrigo, Carlos Sanz-Saiz, Jesús Polo and Zayd Valdez
Energies 2026, 19(10), 2367; https://doi.org/10.3390/en19102367 - 15 May 2026
Viewed by 340
Abstract
The market for coloured photovoltaic modules offers a key opportunity for building-integrated photovoltaics (BIPV), as it enables more aesthetic and seamless integration into architecture. This study investigates how three common BIPV colours—anthracite, green, and terracotta—affect the performance of a BIPV ventilated façade. It [...] Read more.
The market for coloured photovoltaic modules offers a key opportunity for building-integrated photovoltaics (BIPV), as it enables more aesthetic and seamless integration into architecture. This study investigates how three common BIPV colours—anthracite, green, and terracotta—affect the performance of a BIPV ventilated façade. It presents a year-long field comparison, including thermal modelling and residual spectral loss estimation, of three screen-printed coloured BIPV strings installed on an east-facing ventilated façade, at the CIEMAT research centre in Madrid, Spain. Although anthracite modules exhibit the highest efficiency under standard test conditions (STC), green modules achieve the best performance ratio (PR) due to their lower spectral and thermal impacts. Results indicate that system design factors—such as façade orientation, module positioning and rear ventilation—significantly influence thermal and electrical performance. In particular, changes in solar spectral irradiance can have a strong impact on the performance of coloured modules, mainly due to their distinct spectral reflectance characteristics. This effect is especially relevant for reddish modules mounted on east- and west-facing façades, which, on clear days, receive sunlight with spectra shifted toward the near-infrared (NIR) region compared with midday conditions, which are closer to the standard AM1.5G solar spectrum. Prior optical characterisation, particularly spectral reflectance measurements, is therefore essential to accurately assess and predict the performance of coloured modules under real operating conditions. Full article
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35 pages, 6709 KB  
Article
Investigation into the Energy Performance of Commercial Buildings Using Envelope Thermal Transfer Value (ETTV) with Green Elements
by Azharul Karim, Mahmudul Hasan, Shahida Begum and Sabrina Fawzia
Buildings 2026, 16(10), 1875; https://doi.org/10.3390/buildings16101875 - 8 May 2026
Viewed by 285
Abstract
The reduction in energy demand in buildings through the adaptation of energy-efficient strategies is attracting significant attention from the research community. In this context green building concepts can contribute towards achieving national sustainable development goals (SDGs) and NetZero targets. Given the substantial energy [...] Read more.
The reduction in energy demand in buildings through the adaptation of energy-efficient strategies is attracting significant attention from the research community. In this context green building concepts can contribute towards achieving national sustainable development goals (SDGs) and NetZero targets. Given the substantial energy demand associated with heating and cooling in commercial and residential buildings, enhancing energy efficiency has become essential for achieving sustainable development, particularly amid ongoing global energy challenges. The Envelope Thermal Transfer Value (ETTV) model has been established as a simplified method of calculating building loads; however, its integration with green building elements remains limited, particularly in subtropical climates. Furthermore, the combined effects of living walls, green façades, and green roofs on building energy performance have not been comprehensively investigated. In this study, an extensive experimental investigation was conducted using prototype buildings under controlled conditions to evaluate the thermal performance of green elements. Modified ETTV formulations incorporating green envelope systems have been developed, and the thermodynamic effects of these green elements on the building energy performance have been analysed. The results demonstrate that integrating green elements significantly reduces thermal heat gain and cooling energy demand. Specifically, a combination of a living wall on a west facing wall and a green roof could reduce the thermal heat gain by up to 30%. Full article
(This article belongs to the Section Building Energy, Physics, Environment, and Systems)
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16 pages, 3253 KB  
Article
Enviro-Economic Assessment of Vegetation–PV Envelope Retrofits for Nearly Zero Energy Buildings in Hot-Humid Climates
by Mohanad M. Ibrahim, Micheal A. William, Iham F. Zidane, Ahmed A. Hanafy and María José Suárez-López
Sustainability 2026, 18(9), 4526; https://doi.org/10.3390/su18094526 - 4 May 2026
Viewed by 1002
Abstract
The growing demand for sustainable energy solutions in the built environment has increased interest in hybrid envelope retrofits that integrate vegetation systems with on-site photovoltaics (PVs). This study presents a comparative assessment of two integrated vegetation–PV envelope retrofit strategies for an educational building [...] Read more.
The growing demand for sustainable energy solutions in the built environment has increased interest in hybrid envelope retrofits that integrate vegetation systems with on-site photovoltaics (PVs). This study presents a comparative assessment of two integrated vegetation–PV envelope retrofit strategies for an educational building in a cooling-dominated hot-humid climate relevant to Nearly Zero Energy Building (NZEB) applications. A calibrated dynamic simulation model was developed to quantify annual net electricity savings, operational CO2 emission reductions, and cost-effectiveness using the levelized cost of saved electricity (LCOS). Two configurations were assessed: a solar green roof and a façade system combining green walls with glazing-integrated photovoltaics (GIPVs), enabling a consistent evaluation of roof-based and façade-based hybrid systems under identical conditions. Both strategies deliver comparable energy and environmental performance. The solar green roof achieves annual net electricity savings of 231.0 MWh and avoids 163.3 tCO2, while the green walls–GIPV system provides 228.3 MWh and 161.4 tCO2. However, significant differences are observed in economic performance. The LCOS of the solar green roof is approximately 0.07 $/kWh, compared with 0.28 $/kWh for the façade-integrated system. The results demonstrate that vegetation–PV hybrid retrofits can effectively support NZEB pathways in hot-humid climates, while highlighting that the solar green roof provides a more cost-effective solution under the studied conditions. The study contributes a consistent, decision-oriented comparison of integrated vegetation–PV strategies, linking energy, environmental, and economic performance within a unified modeling framework. Full article
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28 pages, 2988 KB  
Review
Nature-Based and Solar Façade Systems for a Net-Zero Built Environment: A Structured State-of-the-Art Review and Preliminary Comparative Assessment
by Maria Grazia Insinga, Federica Zagarella, Roberta Montagno, Antonella Mamì and Federica Fernandez
Buildings 2026, 16(9), 1739; https://doi.org/10.3390/buildings16091739 - 28 Apr 2026
Viewed by 634
Abstract
Green building façades are increasingly recognized as a key strategy for decarbonizing the built environment, addressing climate change, urbanization, and the urban heat island effect. This paper investigates two main façade approaches: nature-based solutions (NBS), such as green façades and living walls, and [...] Read more.
Green building façades are increasingly recognized as a key strategy for decarbonizing the built environment, addressing climate change, urbanization, and the urban heat island effect. This paper investigates two main façade approaches: nature-based solutions (NBS), such as green façades and living walls, and Building-Integrated Solar Energy Systems (BI-SES), including photovoltaic, solar thermal, and hybrid BIPV/T systems. The building envelope is framed as an active interface for both energy efficiency and on-site renewable energy generation. Through a structured state-of-the-art review, the study compares these systems in terms of energy performance, environmental benefits, costs, maintenance, lifecycle implications, and adaptability across climatic contexts. Results show that NBS provide consistent benefits in thermal regulation and cooling-load reduction, while solar façades are strongly influenced by orientation, geometry, and urban shading. To complement the qualitative analysis, a preliminary energy–environmental assessment is conducted for three façade configurations (conventional wall, green façade, and combined green–PV façade) across three Italian climates (Milan, Rome, and Palermo). Results indicate that vegetation reduces heat losses and CO2 emissions, with further improvements in integrated systems. Overall, NBS and solar façades emerge as complementary strategies whose integration can enhance building performance and support the transition towards net-zero carbon environments. Full article
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18 pages, 3788 KB  
Article
Species-Specific Particulate Matter Retention by Shade-Tolerant Plants in Modular Living Walls: SEM-Based Quantification and Trait-Guided Selection
by Caterina Dalsasso, Mattia Martin Azzella, Maria Rosaria Bruno, Antonella Campopiano, Annapaola Cannizzaro, Federica Angelosanto and Fabrizio Tucci
Appl. Sci. 2026, 16(8), 3811; https://doi.org/10.3390/app16083811 - 14 Apr 2026
Cited by 1 | Viewed by 604
Abstract
Airborne particulate matter (PM) poses a major health risk, yet species selection for vertical greening systems (VGS) is poorly quantified. We evaluated PM retention by seven commercially available shade-tolerant species grown in a modular living wall system (LWS) on a north-facing façade at [...] Read more.
Airborne particulate matter (PM) poses a major health risk, yet species selection for vertical greening systems (VGS) is poorly quantified. We evaluated PM retention by seven commercially available shade-tolerant species grown in a modular living wall system (LWS) on a north-facing façade at Sapienza University of Rome. After 3 months of in situ exposure, leaves were analyzed via SEM (1000×), collecting 210 images, 30 per species. An automated FIJI/ImageJ pipeline segmented particles, computed equivalent circular diameters, and classified them into (PM < 0.5, PM [0.5, 1), PM [1, 2.5), PM [2.5, 10), and PM ≥ 10 µm). Across species, ultrafine and fine fractions dominated deposits, with the <0.5 µm class typically comprising 60–70% of counts. Vinca minor cv. albomarginata exhibited the highest densities in ultrafine and fine classes, closely followed by Fatsia japonica; Hedera helix captured more coarse particles (2.5–10 µm and >10 µm). Heuchera sanguinea consistently displayed the lowest densities across all size classes. Performance patterns aligned with leaf surface traits: wax-coated, moderately rough or gently structured cuticles favored adhesion, whereas highly irregular microrelief did not consistently enhance retention. Methodological considerations include thresholding sensitivity, use of equivalent circular diameter for irregular particles, and an upper area filter that may undercount large aggregates. The findings identify Vinca minor cv. albomarginata and Fatsia japonica as priority species for PM mitigation in shaded VGS, with Hedera helix complementing coarse PM capture. The results provide trait-based, design-oriented guidance for living wall species selection in Mediterranean urban and indoor contexts. Full article
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20 pages, 1752 KB  
Article
Beyond the Green Façade: A Critical Analysis of Digital Participatory Budgeting for Climate Resilience and Governance in Lisbon
by Jorge Gonçalves, Sílvia Jorge and Beatrice Lorenz Fontolan
Sustainability 2026, 18(7), 3436; https://doi.org/10.3390/su18073436 - 1 Apr 2026
Viewed by 554
Abstract
This article critically analyses Lisbon’s Green Participatory Budget (GPB), launched in 2020 within the symbolic context of the city’s designation as the European Green Capital. Rather than treating the GPB as a radical democratic innovation, the study situates it as a thematic and [...] Read more.
This article critically analyses Lisbon’s Green Participatory Budget (GPB), launched in 2020 within the symbolic context of the city’s designation as the European Green Capital. Rather than treating the GPB as a radical democratic innovation, the study situates it as a thematic and digital reconfiguration of Lisbon’s long-standing participatory budgeting process, which has been active since 2008 and already incorporated environmental dimensions. Drawing on critical urban studies, political ecology, and literature on participatory governance, the analysis explores the democratic and justice implications of digital participatory climate governance. The article identifies structural limitations in the design and implementation of the GPB, including technocratic gatekeeping, digital exclusion, restricted deliberation, and the significant involvement of private sector consultancies. Beyond these internal constraints, the article argues that the most critical limitation of Lisbon’s GPB lies in its lack of continuity. Despite the mobilization of financial resources and public expectations, the GPB was not renewed after 2021, nor were its outcomes systematically evaluated or integrated into long-term governance strategies. This discontinuation compromises the potential of participatory climate governance as a learning process and raises broader questions about symbolic policy-making, institutional memory, and democratic accountability in urban climate action. The study concludes by proposing a set of redistributive and justice-oriented principles to restructure participatory mechanisms toward genuine climate democracy. Full article
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41 pages, 3140 KB  
Systematic Review
Structural Imbalance and Life-Cycle Cost Coverage in Vertical Greenery Systems: A Systematic Literature Review
by Nitchaya Phatthanaphan, Tarid Wongvorachan, Duangkamon Wutisun, Sathirat Singkham, Sippakorn Petsirasan, Chaniporn Thampanichwat, Suphat Bunyarittikit and Sanawete Sirirat
Buildings 2026, 16(7), 1353; https://doi.org/10.3390/buildings16071353 - 29 Mar 2026
Viewed by 1069
Abstract
Vertical greenery systems (VGS), including vertical gardens (VG) and green façades (GF), are increasingly promoted as nature-based solutions for sustainable urban development. Despite their environmental benefits, economic evaluation remains fragmented, particularly within a life-cycle cost (LCC) perspective. This study conducts a systematic literature [...] Read more.
Vertical greenery systems (VGS), including vertical gardens (VG) and green façades (GF), are increasingly promoted as nature-based solutions for sustainable urban development. Despite their environmental benefits, economic evaluation remains fragmented, particularly within a life-cycle cost (LCC) perspective. This study conducts a systematic literature review to examine the structural configuration of cost-related research on VGS within an LCC framework. Following the PRISMA protocol, 136 peer-reviewed articles published between 2021 and 2025 were identified through a structured search of the ScienceDirect database and retained as the analytical dataset. Bibliometric mapping, thematic classification, and co-occurrence analysis were applied to assess publication patterns, the distribution of cost components, and reporting structures. Five principal cost categories were identified: Installation and Operation, Maintenance, Consumables, Materials and Manufacturing, and Design. The results reveal a pronounced concentration on installation and maintenance costs, while design-phase economics and comprehensive LCC integration remain marginal. Most studies address only one or two cost categories, indicating structural fragmentation. In addition, heterogeneous reporting units and inconsistent contextual descriptors constrain cross-study comparability and cumulative synthesis. Collectively, the findings demonstrate that although cost research on VGS is expanding, it has not yet achieved methodological maturity within a standardized LCC framework. Advancing harmonized cost-reporting protocols and integrated life-cycle modeling is therefore essential to support robust economic evaluation and informed implementation of VGS in sustainable built environments. Full article
(This article belongs to the Section Architectural Design, Urban Science, and Real Estate)
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36 pages, 10780 KB  
Article
Seasonal and Botanical Influences on External Thermal Performance near Green Façades: CFD Simulations on a Reference Building Envelope in a Humid Temperate Climate
by Barbara Gherri, Lisa Rovetta, Sara Matoti and Alessandro Petraglia
Atmosphere 2026, 17(4), 342; https://doi.org/10.3390/atmos17040342 - 28 Mar 2026
Viewed by 1056
Abstract
Green façades are acknowledged as passive strategies that reduce heat accumulation, enhance biodiversity, improve particulate matter absorption and provide psycho-physiological benefits for users. However, evaluations of their thermal performance—accounting for seasonality, vegetation density, and leaf characteristics—remain incomplete. This study addresses this gap by [...] Read more.
Green façades are acknowledged as passive strategies that reduce heat accumulation, enhance biodiversity, improve particulate matter absorption and provide psycho-physiological benefits for users. However, evaluations of their thermal performance—accounting for seasonality, vegetation density, and leaf characteristics—remain incomplete. This study addresses this gap by assessing two green façade typologies on a sample building located in Northern Italy (Cfa climate). ENVI-met microclimate simulations compared a bare wall with vegetated façades featuring Hedera helix (evergreen) and Parthenocissus tricuspidata (deciduous) across four orientations and seasonal conditions, considering the sample building and the immediate surrounding outdoor space. Both species reduced wall-surface temperatures (T0) and improved outdoor thermal comfort perception (PET), influenced by LAI dynamics, foliage persistence, and façade orientation. Results indicate that Parthenocissus tricuspidata achieved the greatest cooling effect during hot periods due to higher LAI, with absolute T0 reductions of up to 22.1 °C on southern façades and 30.0 °C on western façades. In these orientations, PET improvements reached up to 3.0 °C (south) and 8.0 °C (west). Conversely, Hedera helix ensured stable year-round performance and performed better on northern façades during colder periods. The results stress the need for integrated design that aligns plant choice with orientation and seasonal growth to optimize thermal performance, cut cooling demands, and improve outdoor comfort. Full article
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20 pages, 1438 KB  
Article
A Context-Adapted Living Wall Model for South Africa: A Quantity Surveying Perspective
by Rolien Terblanche, Samuel Johan De Witt and Aiden Graham Pringle
Sustainability 2026, 18(6), 2978; https://doi.org/10.3390/su18062978 - 18 Mar 2026
Viewed by 305
Abstract
Living Wall Systems (LWS) are vertical vegetated building façade systems that offer environmental and social benefits; however, their adoption in South Africa, particularly within the Western Cape (WC), remains limited due to high capital and maintenance costs and the absence of regionally adapted [...] Read more.
Living Wall Systems (LWS) are vertical vegetated building façade systems that offer environmental and social benefits; however, their adoption in South Africa, particularly within the Western Cape (WC), remains limited due to high capital and maintenance costs and the absence of regionally adapted design and cost models. This study investigates the viability and design development of LWS in the WC from a Quantity Surveying (QS) perspective, with the aim of developing a context-specific system utilising indigenous plant species and assessing its economic feasibility over the building life cycle. This study employed a mixed method research approach comprising a literature review, semi-structured interviews with industry professionals, thematic analysis, cost modelling, and the preparation of a detailed Bill of Quantities (BOQ). Life cycle costing (LCC) techniques were applied to evaluate long-term cost implications. The study resulted in the development of a criteria-led, context-adapted LWS model, termed Viridis 5045, which satisfies environmental, technical, and contextual requirements for the WC. The BOQ and LCC analyses provide projected capital and operational cost benchmarks for the proposed system. This study demonstrates that the Viridis 5045 model is technically feasible and contextually appropriate for application within the WC, supporting its consideration in sustainable construction practice when evaluated beyond conventional life cycle financial indicators. Future research should focus on the monetisation of long-term benefits, greywater integration, and Whole Life Costing. Full article
(This article belongs to the Section Green Building)
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17 pages, 11516 KB  
Article
The Coupling Relationship Between Street View Element Comfort Perception and Eye Movement Metrics and Its Sustainable Research
by Haoxin Ma and Xiangbin Gao
Sustainability 2026, 18(5), 2220; https://doi.org/10.3390/su18052220 - 25 Feb 2026
Viewed by 542
Abstract
People’s perception of the comfort level of street landscape elements is influenced by the built environment, and improving the quality of street landscape environment is of great significance for promoting the sustainable development of cities. This study focuses on 12 sample streets in [...] Read more.
People’s perception of the comfort level of street landscape elements is influenced by the built environment, and improving the quality of street landscape environment is of great significance for promoting the sustainable development of cities. This study focuses on 12 sample streets in Zibo City. After obtaining panoramic images of the area through the OSM platform, the FCN framework was used for semantic segmentation. A combination of subjective and objective methods was adopted, and eye tracking indicators were collected using the D-Lab wearable eye tracker. At the same time, a questionnaire quantitative analysis was conducted to systematically investigate the impact mechanism of the combination characteristics of street elements on comfort perception preferences. Research has found that there is a significant correlation between the perceived comfort preference of street scenes and GVI, and the increase in total gaze time towards green elements also shows a significant improvement in perceived comfort preference. After entering the street interface, observers show a high degree of priority attention to street view elements such as building facades and advertising facilities. As the gaze time on the sky (a street view element) increases, people’s perceived comfort evaluation shows a downward trend. There are significant differences in the structural characteristics of different streets, and their impact on improving comfort also varies to some extent. This study links the comfort perception of street landscape elements with sustainable urban development planning. By reasonably allocating landscape elements such as green visibility, basic roads, building interfaces, and signage facilities, it provides certain reference suggestions for the sustainable development of urban street space and human-centered urban construction. Full article
(This article belongs to the Section Sustainable Urban and Rural Development)
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29 pages, 383 KB  
Article
Urban Heat Islands and Urban Planning Law in Spain: Towards Quantifiable and Enforceable Climate Standards
by María Jesús Romero Aloy and Ángel Trinidad Tornel
Land 2026, 15(2), 205; https://doi.org/10.3390/land15020205 - 23 Jan 2026
Viewed by 846
Abstract
Urban heat islands are among the most intense and unequal climate impacts in Mediterranean cities, with direct effects on health, thermal comfort, and habitability. This reality calls for the incorporation of binding and verifiable climate criteria into spatial planning and urban planning law. [...] Read more.
Urban heat islands are among the most intense and unequal climate impacts in Mediterranean cities, with direct effects on health, thermal comfort, and habitability. This reality calls for the incorporation of binding and verifiable climate criteria into spatial planning and urban planning law. This article examines the extent to which the Spanish legal framework—at national, regional, and municipal levels—incorporates measurable standards to mitigate urban heat islands and how it might evolve towards operational climate-responsive urbanism. A legal–analytical and comparative methodology is applied, based on multilevel normative content analysis and a comparison of four autonomous communities, four Spanish cities, and four international reference cases with consolidated metrics. The results show that, despite progress in recognising adaptation, territorial asymmetries persist, enforceable parameters remain scarce, and there is a prevailing reliance on strategic or voluntary instruments. In response to these gaps, the study proposes a coherent set of urban climate standards (urban vegetation, functional soil permeability, roof albedo/cool roofs, green roofs and façades, plot-scale performance indices, urban ventilation, and thermal diagnostics) and a multilevel integration model aimed at guiding legislative reforms and strengthening cities’ adaptive capacity and thermal equity. Full article
(This article belongs to the Special Issue The Impact of Urban Planning on the Urban Heat Island Effect)
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