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Search Results (341)

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27 pages, 6568 KB  
Systematic Review
The Climate Vulnerability and Performance of Semi-Outdoor Sports Stadiums: A Systematic Review
by Xiao Guo, Wenyu Zhang and Zihao Yao
Buildings 2026, 16(13), 2656; https://doi.org/10.3390/buildings16132656 - 4 Jul 2026
Viewed by 200
Abstract
Climate change poses significant challenges to urban infrastructure, particularly semi-outdoor stadiums, which are highly susceptible to climate-related hazards. The current research community has gradually recognized this issue but lacks systematic insights into the capacity and methods for stadiums to cope with climate change. [...] Read more.
Climate change poses significant challenges to urban infrastructure, particularly semi-outdoor stadiums, which are highly susceptible to climate-related hazards. The current research community has gradually recognized this issue but lacks systematic insights into the capacity and methods for stadiums to cope with climate change. This review assesses the vulnerability and climate performance of semi-outdoor stadiums and identifies adaptation strategies to enhance resilience. A systematic literature review was conducted using Web of Science and Scopus databases. Key themes included thermal comfort, wind comfort, and rain protection. Thermal comfort and CFD emerged as the most dominant research focus. This review highlighted the importance of long-term climate adaptation strategies, including the use of sustainable materials, improved ventilation, and renewable energy systems. The results also indicate a lack of research on tropical climates and that more comprehensive adaptation strategies are needed. The core contribution is a structured vulnerability framework that transforms scattered evidence into an integrated knowledge structure, identifying not only dominant themes and missing links but also cross-cutting trade-offs. These findings provide actionable insights for urban planners, architects, and policymakers aiming to enhance stadium resilience and contribute to sustainable urban development goals. Full article
(This article belongs to the Section Architectural Design, Urban Science, and Real Estate)
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18 pages, 25463 KB  
Article
Deep Drawing of Additively Manufactured Composite Architected Discs: Effect of Infill Geometry and Feature Size on Formability
by Luca Giorleo and Elisabetta Ceretti
Appl. Sci. 2026, 16(13), 6665; https://doi.org/10.3390/app16136665 - 3 Jul 2026
Viewed by 91
Abstract
Additively manufactured composite architected discs offer a potential route for producing lightweight semi-finished blanks that can subsequently be shaped by conventional forming processes. However, the relationship between infill architecture, feature size, and deep-drawing formability remains poorly understood. This study investigates the deep-drawing response [...] Read more.
Additively manufactured composite architected discs offer a potential route for producing lightweight semi-finished blanks that can subsequently be shaped by conventional forming processes. However, the relationship between infill architecture, feature size, and deep-drawing formability remains poorly understood. This study investigates the deep-drawing response of material-extruded short-fibre-reinforced polymer composite discs by combining experimental tests and finite element simulations. Four infill strategies, namely perforated body, re-entrant, square and triangular, were first compared at drawing depths of 10 and 20 mm. The perforated body and re-entrant geometries were successfully formed at 10 mm, whereas only the perforated body withstood 20 mm without macroscopic failure. A second campaign focused on perforated discs with hole diameters of 2.5, 5, 7.5 and 10 mm. All configurations were drawable at 10 mm, while the 2.5 mm case failed at 20 mm. Statistical analysis confirmed that hole diameter significantly affected both retained cup height and side-hole aspect ratio. At 20 mm, larger holes reduced local ovalization but increased elastic recovery, leading to lower retained cup height. FEM simulations were used as an interpretative first-order model. They supported the experimental trends by comparing deformation modes, tensile/compressive stress redistribution, forming energy and strain localization. The results show that the formability of architected composite blanks is governed not only by material volume or porosity but by the ability of the internal architecture to accommodate deformation through a suitable balance between local stiffness and geometric compliance. These findings provide design-oriented guidelines for the development of additively manufactured architected blanks intended for hybrid additive–forming manufacturing routes. Full article
(This article belongs to the Special Issue Additive Manufacturing of Fiber Composite Structures)
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32 pages, 1360 KB  
Review
Design for Metal Additive Manufacturing: A Review of Design Strategies and Process Constraints
by José Nascimento Nhanga, Manuel Fernando Vieira and Jose Manuel Costa
Metals 2026, 16(7), 721; https://doi.org/10.3390/met16070721 - 30 Jun 2026
Viewed by 337
Abstract
Metal additive manufacturing (AM) enables components with high geometric complexity and functional integration; however, these advantages are realized only when topology optimization (TO) aligns with AM-specific constraints. This review examines TO strategies for metal AM, with emphasis on laser powder bed fusion (LPBF) [...] Read more.
Metal additive manufacturing (AM) enables components with high geometric complexity and functional integration; however, these advantages are realized only when topology optimization (TO) aligns with AM-specific constraints. This review examines TO strategies for metal AM, with emphasis on laser powder bed fusion (LPBF) as the most established industrial route. It categorizes and assesses density-based methods, level-set approaches, and lattice or architected-material optimization, focusing on how each captures manufacturability (overhang limits, minimum feature size, surface roughness), physics (residual stress, thermal distortion), and AM-induced anisotropy. It further distinguishes algorithms that embed constraints directly into the TO loop from workflows that rely on post-optimization repair. It discusses implications for robustness and transferability across machines and alloys. Experimental and numerical evidence for titanium alloys, aluminum alloys, nickel-based superalloys, and stainless steels is synthesized to relate design decisions and processing conditions to reported gains in stiffness-to-weight ratio, strength, fatigue performance, and buy-to-fly efficiency. Persistent gaps include validation under realistic load spectra, uncertainty quantification, standardized benchmarks, microstructure-informed objectives, and sustainability metrics. Beyond synthesizing existing TO formulations and constraints, this review contributes a criteria-based decision structure linking TO method selection, constraint strategy, and process-physics coupling and identifies four inherent paradoxes defining the field’s open challenges. Full article
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28 pages, 1775 KB  
Review
A Review of Machine Learning Applications in Mechanical Metamaterial Design
by Galymzhan Turysbekov, Ulanbek Auyeskhan, Andrei Yankin, Asma Perveen and Didier Talamona
Materials 2026, 19(13), 2766; https://doi.org/10.3390/ma19132766 - 30 Jun 2026
Viewed by 297
Abstract
Mechanical metamaterials are architected materials that exhibit unusual mechanical properties arising from their internal geometry. This paper reviews recent developments in the application of machine learning for the design and analysis of these structures. It categorizes common architectures, including strut-based lattices and triply [...] Read more.
Mechanical metamaterials are architected materials that exhibit unusual mechanical properties arising from their internal geometry. This paper reviews recent developments in the application of machine learning for the design and analysis of these structures. It categorizes common architectures, including strut-based lattices and triply periodic minimal surfaces, and details the end-to-end design workflow, from dataset preparation and preprocessing to the iterative, simulation-based validation approach. The review compares a range of model architectures. These include foundational models like deep neural networks, fully connected and convolutional neural networks, graph neural networks, and generative models such as GANs and diffusion models. Applications in mechanical property prediction and inverse design are highlighted with examples using finite element simulations and generative design models. A structured design workflow and a comparative summary of recent studies are presented to guide future research and application. This review aims to support the development of ML frameworks for next-generation metamaterial design. Full article
(This article belongs to the Section Materials Simulation and Design)
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25 pages, 33252 KB  
Article
Aesthetics of Interruption: Professional Disconnection and Façade Transformation in Post-2017 Mosul Residential Design
by Amer Abdullah Alazawi, Oday Qusay Abdulqader Alchalabi, Ashraf Ibrahim Alhafody and Abdul Ghafoor Nizamani
Architecture 2026, 6(3), 103; https://doi.org/10.3390/architecture6030103 - 27 Jun 2026
Viewed by 206
Abstract
Post-conflict reconstruction research has examined façade materiality and symbolism, yet the process conditions under which aesthetic specifications are systematically overridden during construction remain neglected. This study investigates why designed architectural aesthetics fail to survive implementation in post-2017 Mosul, Iraq. A mixed-methods design combined [...] Read more.
Post-conflict reconstruction research has examined façade materiality and symbolism, yet the process conditions under which aesthetic specifications are systematically overridden during construction remain neglected. This study investigates why designed architectural aesthetics fail to survive implementation in post-2017 Mosul, Iraq. A mixed-methods design combined formal visual analysis of 12 recently completed residential façades with a structured survey of 45 practicing architects. Survey data reveal that designers are excluded from construction supervision in 76% of projects and that clients intervene in material and color selection in 70% of cases. Visual analysis identifies a sophisticated design language—orthogonal massing articulated through contrasting materials—that is rarely realized in built form. Where designers retain supervisory authority, projects most consistently achieve material–form coherence. The study advances the concept of an aesthetics of interruption (the systematic degradation of designed form–material relationships through the fragmentation of professional authority during construction). Exclusion produces four distinct pathologies: material substitution, execution degradation, language override, and ornamental hollowing. The findings demonstrate that aesthetic degradation in post-conflict reconstruction stems not from design incapacity but from broken process structures. Safeguarding architectural quality requires contractual frameworks mandating designer supervision and material-substitution protocols that protect design intent. Full article
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18 pages, 1794 KB  
Article
Fire Safety Considerations During the Design Phase of Commercial Buildings in Saudi Arabia: A Comprehensive Framework
by Ali Mohammed Al-Dossary, Mohammad A. Hassanain and Ali Al-Mudhei
Buildings 2026, 16(12), 2343; https://doi.org/10.3390/buildings16122343 - 11 Jun 2026
Viewed by 223
Abstract
This study addresses the critical importance of fire safety considerations during the design phase of commercial buildings, particularly in Saudi Arabia, where urbanization and climate-specific risks pose unique challenges. Recognizing that high-risk structures often experience fire-related incidents due to inadequate safety measures, this [...] Read more.
This study addresses the critical importance of fire safety considerations during the design phase of commercial buildings, particularly in Saudi Arabia, where urbanization and climate-specific risks pose unique challenges. Recognizing that high-risk structures often experience fire-related incidents due to inadequate safety measures, this research develops a comprehensive framework to guide design professionals in integrating effective fire safety strategies. Using a mixed-methods approach, the study combined a literature review, qualitative expert interviews, and a questionnaire survey. The final quantitative analysis was based on 86 valid survey responses, including 29 authority or regulation implementers, 28 designers, and 29 stakeholders. The survey results highlighted significant gaps in knowledge and implementation, particularly among stakeholders. Key challenges identified included cultural attitudes toward safety, lack of training, and inadequate use of fire-resistant materials. The framework proposes a structured methodology for enhancing fire safety measures across the design stages, emphasizing the importance of collaboration among architects, engineers, safety consultants, and regulatory bodies. Recommendations include regular updates to fire safety documents, fostering a culture of safety awareness, and conducting post-occupancy evaluations to assess the effectiveness of implemented measures. Ultimately, this research aims to benefit various stakeholders, including design professionals and regulatory agencies, by promoting a proactive approach to fire safety that enhances building resilience and protects lives and property in commercial environments. Full article
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26 pages, 95954 KB  
Article
Programming Failure Mode Transitions in Polyurea-Reinforced 3D-Printed ABS and PA-GF Cellular Metamaterial Composites
by Rodrigo Valle, César Garrido and Víctor Tuninetti
Polymers 2026, 18(12), 1466; https://doi.org/10.3390/polym18121466 - 11 Jun 2026
Viewed by 244
Abstract
Additively manufactured cellular architectures frequently exhibit brittle failure under impact due to layer-induced stress concentrations. Through the programming of architectural and material design, specifically combining Fused Deposition Modeling (FDM) lattice topology with hyperelastic polyurea infiltration, this study achieves active control over the macroscopic [...] Read more.
Additively manufactured cellular architectures frequently exhibit brittle failure under impact due to layer-induced stress concentrations. Through the programming of architectural and material design, specifically combining Fused Deposition Modeling (FDM) lattice topology with hyperelastic polyurea infiltration, this study achieves active control over the macroscopic transition from catastrophic structural fragmentation to stable progressive collapse. To evaluate this, auxetic and honeycomb specimens printed with ABS and glass-fiber-reinforced polyamide (PA-GF) were evaluated in unreinforced and polyurea-infiltrated states under quasi-static compression, three-point bending, and Charpy impact loading. Results show that the compressive response depends primarily on cellular topology; the pure auxetic (A-A) configuration provided the highest stiffness and energy absorption. Polyurea infiltration did not significantly alter elastic stiffness but increased post-yield stability, leading to a 96.6% elastic recovery in PA-GF A-A structures. In flexure, the base polymer governed stiffness, with ABS structures measuring 68% stiffer than PA-GF. Unreinforced ABS achieved 34% higher specific energy absorption (SEA) than PA-GF under compression, with the A-H topology maximizing SEA. Under dynamic impact, PA-GF absorbed an average of 70% more energy than ABS, and the H-A configuration recorded the highest impact resistance. The addition of polyurea shifted the failure mode from brittle fragmentation to stable elastomeric deformation, increasing absorbed impact energy by 52% for ABS and over 30% for PA-GF, preventing catastrophic structural failure. Integrating topological sequencing with elastomeric confinement provides a direct method to control energy dissipation and damage tolerance in 3D-printed cellular composites. Full article
(This article belongs to the Section Polymer Processing and Engineering)
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16 pages, 20969 KB  
Article
Promoting Circular Design in the Built Environment: Insights from the Application of Material Stock Analysis to a Case Study in Milan
by Michele Versaci, Francesco Pittau, Iacopo Pizzutilo and Gabriele Masera
Appl. Sci. 2026, 16(12), 5864; https://doi.org/10.3390/app16125864 - 10 Jun 2026
Viewed by 224
Abstract
The construction sector plays a central role in global resource depletion and waste generation, with construction and demolition activities accounting for more than one-third of total waste produced in the European Union. Despite growing interest in circular construction, one of the major barriers [...] Read more.
The construction sector plays a central role in global resource depletion and waste generation, with construction and demolition activities accounting for more than one-third of total waste produced in the European Union. Despite growing interest in circular construction, one of the major barriers to large-scale material reuse is the lack of reliable information on the type, quantity, location, and availability of secondary materials during the early stages of a project. The research addresses this gap between architectural design and planning decision-making by providing a replicable workflow for urban scale circular economy strategies. This study presents the application of a spatially explicit bottom-up Material Stock Analysis (MSA) to quantify and map the embedded materials within an urban district of Milan. The adopted methodology combines municipal GIS datasets, historical cartography, building archetype classification, and literature-derived material intensity coefficients. The result is the estimation of stock amounts disaggregated by material type and the creation of a secondary material cadaster, that allows us to visualize their distributions and generate material-specific spatial analyses and heat maps. Applied to the Porta Vittoria district in Milan, the workflow reveals that masonry accounts for over 66% of the total embedded mass, underscoring the need to factor the reuse of masonry and brick materials into the early design phases, from material selection to architectural concept. Ultimately, the study equips architects, urban planners, and policymakers with decision-support information to steer design and governance toward circular future cities. Full article
(This article belongs to the Section Materials Science and Engineering)
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20 pages, 6577 KB  
Article
Characterizing the Anisotropic Elastic Properties of Auxetic Structures by Impulse Excitation Technique Combined with Inverse Parameter Identification
by Julian Rech, Yuchen Leng, Stefan Reinholz, Christian Dresbach, Danka Katrakova-Krüger and Christoph Hartl
Materials 2026, 19(12), 2479; https://doi.org/10.3390/ma19122479 - 9 Jun 2026
Viewed by 233
Abstract
Auxetic metamaterials exhibit unique mechanical behavior due to their negative Poisson’s ratio, but reliable determination of their effective elastic properties remains challenging. In this study, an experimental–numerical approach is proposed to characterize additively manufactured polylactic acid (PLA)-based auxetic sandwich structures. Material properties were [...] Read more.
Auxetic metamaterials exhibit unique mechanical behavior due to their negative Poisson’s ratio, but reliable determination of their effective elastic properties remains challenging. In this study, an experimental–numerical approach is proposed to characterize additively manufactured polylactic acid (PLA)-based auxetic sandwich structures. Material properties were first assessed using tensile testing, melt flow rate/volume rate (MFR/MVR) measurements, Fourier-transform infrared (FTIR) spectroscopy, differential scanning calorimetry (DSC), dilatometry, and nanoindentation, revealing stable mechanical behavior, good processability, and slight increases in crystallinity induced by the printing process. Impulse excitation technique (IET) measurements provided highly reproducible resonant frequencies, demonstrating a strong dependence on core geometry and orientation. However, classical ASTM-based evaluation yielded non-physical elastic properties, highlighting its limitations for architected metamaterials. Finite element modal analyses, combined with inverse parameter identification, enabled the determination of effective elastic properties using a transversely isotropic homogenized model. This approach significantly improved the agreement between experimental and numerical results. The findings revealed pronounced anisotropy and orientation-dependent auxetic behavior, including a negative Poisson’s ratio for specific configurations. The proposed methodology provides a suitable framework for the reliable characterization and design of complex metamaterials. Full article
(This article belongs to the Section Advanced Materials Characterization)
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30 pages, 13965 KB  
Article
Measuring Building Circularity Through Materials, Processes and Impacts: An Evaluation Framework for Architecture Integrating Reused, Bio-Based and Recycled Components
by Paola Altamura, Gabriele Rossini, Gaia Garofali, Serena Baiani and Fabrizio Tucci
Appl. Sci. 2026, 16(11), 5617; https://doi.org/10.3390/app16115617 - 3 Jun 2026
Viewed by 264
Abstract
In line with circular bioeconomy goals, this research focuses on circular materials—reused, bio-based (including waste-derived ones) and recycled—as a strategic solution to simultaneously cut Embodied Carbon and material resource uptake in buildings. The research develops a methodology for early, rapid assessment of circular [...] Read more.
In line with circular bioeconomy goals, this research focuses on circular materials—reused, bio-based (including waste-derived ones) and recycled—as a strategic solution to simultaneously cut Embodied Carbon and material resource uptake in buildings. The research develops a methodology for early, rapid assessment of circular materials’ contribution to cutting climate-altering emissions and material consumption, supporting architects during the initial design stage, where strategic choices are most impactful. Multiple case studies of buildings employing 12 circular design strategies and different materials were analysed, of which 10 are presented here, mapping approaches and material mixes. In parallel, by analysing 15 existing circularity and sustainability evaluation frameworks at the building and product level, screening 80 relevant indicators and integrating specific ones, the research develops a set of eight KPIs enabling designers to assess alternative combinations of reused, bio-based and recycled building materials from the early design stage. Validated on three case studies, the KPIs proved sensitive in capturing the diversity of circular material strategies by measuring circular material origin, local materials, disassemblability, material and Embodied Carbon intensity, with the latter proving particularly effective in cross-measuring the impacts of material choices. The research thus provides operational support for rapid comparative assessments guiding design decisions during early stages, focusing on materials, processes and relative impacts. Full article
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34 pages, 9844 KB  
Article
Multiscale Analysis of Reinforced Concrete Frames with Embedded Metamaterials Under Progressive Collapse
by Xu Long, Christopher Samuneti, Percy M. Iyela, Khaja Wahaajuddin Kawkabi, Prince Manyanya Ngangura and Kunjie Fan
Materials 2026, 19(11), 2363; https://doi.org/10.3390/ma19112363 - 2 Jun 2026
Viewed by 275
Abstract
Progressive collapse represents a catastrophic failure mode for reinforced concrete (RC) structures, yet the use of architected materials to mitigate this risk remains largely unexplored. This study presents a numerical feasibility investigation of RC beam–column sub-assemblages with auxetic metamaterial inserts embedded in critical [...] Read more.
Progressive collapse represents a catastrophic failure mode for reinforced concrete (RC) structures, yet the use of architected materials to mitigate this risk remains largely unexplored. This study presents a numerical feasibility investigation of RC beam–column sub-assemblages with auxetic metamaterial inserts embedded in critical joint regions. A hierarchical multiscale framework is developed to link the effective behavior of auxetic metamaterials with structure-scale collapse response. The framework couples macroscale structural analysis with mesoscale fracture simulations through a hybrid voxel–Voronoi discretization strategy. Baseline finite element models are validated against published experimental results for conventional RC specimens, while the auxetic-enhanced configurations are evaluated numerically. Under high tensile strain, the auxetic insert expands laterally because of its negative Poisson’s ratio and generates a localized confining stress field within the surrounding concrete. The simulations suggest that this mechanism may promote crack bifurcation, redistribute localized cracking into a more distributed damage pattern, and delay compressive crushing and crack coalescence. Compared with the corresponding conventional RC configurations, the auxetic-enhanced models predict a 25% increase in load redistribution capacity and a 20% enhancement in deformation ductility. These predicted improvements require future experimental validation using physical auxetic-enhanced RC specimens. The findings provide a computational basis for exploring material-by-design strategies aimed at improving the robustness of critical RC joint regions under progressive collapse demands. Full article
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19 pages, 1503 KB  
Article
A Novel Approach for Architectural Material Selection: Introducing a New Weighted Judgment Scale Rating with Analytical Hierarchy Process
by Chung-Cho Chang, Sebastian Gunawan and Shu-Hsien Tai
Buildings 2026, 16(11), 2084; https://doi.org/10.3390/buildings16112084 - 23 May 2026
Viewed by 380
Abstract
Material selection in architectural design necessitates a multifaceted evaluation of economic, technical, esthetic, and cultural variables. Beyond fundamental requirements such as cost, structural integrity, and transparency, architects must synthesize subjective attributes, including warmth and formality, with objective constraints like multifunctionality and cultural heritage. [...] Read more.
Material selection in architectural design necessitates a multifaceted evaluation of economic, technical, esthetic, and cultural variables. Beyond fundamental requirements such as cost, structural integrity, and transparency, architects must synthesize subjective attributes, including warmth and formality, with objective constraints like multifunctionality and cultural heritage. Despite the strategic impact of material choice on project performance, empirical research systematically categorizing these governing criteria remains sparse. Furthermore, existing methodologies often overlook the psychophysical principles of human perception essential for construction material evaluation. Thus, this study identifies the fundamental factors influencing material selection and establishes a hierarchical framework to prioritize their relative significance within the design process. The research employs a weighted Analytic Hierarchy Process integrated with the Weber–Fechner law (W-AHP) to structure and quantify selection criteria. By incorporating perceptual scaling principles into the AHP framework, the methodology accounts for variations in judgment sensitivity across different evaluation scales. A hierarchical decision model was developed to categorize criteria and sub-criteria, followed by pairwise comparisons to derive priority weights. Results reveal a distinct priority hierarchy among the identified criteria and confirm that judgment sensitivity varies significantly across evaluation scales. The W-AHP method produced differentiated weightings that accurately reflect the psychological intensity of professional decision-making, offering a structured mechanism to balance functional performance with complex design intentions. This study contributes to the field of construction management by introducing the W-AHP method as a novel decision-support tool. The integration of Weber–Fechner perceptual principles enhances weight differentiation and addresses the inherent subjectivity of architectural evaluation, providing a transparent methodology to justify material procurement within a rigorous engineering management context. Full article
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15 pages, 1011 KB  
Article
A Conceptual Framework for the Implementation of Healthy Construction in Sub-Saharan Countries: Gabon as a Case Study
by Stahel Serano Bibang Bi Obam Assoumou and Li Zhu
Buildings 2026, 16(10), 1964; https://doi.org/10.3390/buildings16101964 - 15 May 2026
Viewed by 318
Abstract
Healthy building concepts are increasingly recognized as important for improving occupant health and well-being, yet empirical evidence on their understanding and implementation in sub-Saharan African contexts remains limited. This study provides an exploratory assessment of construction professionals’ awareness and self-reported application of healthy [...] Read more.
Healthy building concepts are increasingly recognized as important for improving occupant health and well-being, yet empirical evidence on their understanding and implementation in sub-Saharan African contexts remains limited. This study provides an exploratory assessment of construction professionals’ awareness and self-reported application of healthy building concepts in Gabon. Using a structured questionnaire survey of 45 construction professionals, including architects, engineers, and contractors, the study examines sources of awareness, patterns of application across project stages, and health-related dimensions prioritized in practice. The results indicate high levels of conceptual awareness within the surveyed group, but uneven and context-dependent application. Implementation is strongly concentrated at the design stage, while continuity during construction and operation remains limited. Professionals tend to prioritize tangible and measurable dimensions such as lighting, materials, air quality, and thermal comfort, whereas psychosocial and community-related aspects receive less attention. Based on these empirical patterns, the study proposes an empirically informed and context-sensitive framework structured around six strategic pillars to support the gradual integration of healthy construction practices in Gabon. Rather than offering a prescriptive model, the framework serves as an analytical reference to inform future research, professional capacity building, and policy dialog. Given the exploratory nature of the study and its reliance on self-reported data, the findings should be interpreted as indicative rather than generalizable. Full article
(This article belongs to the Section Construction Management, and Computers & Digitization)
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24 pages, 3248 KB  
Proceeding Paper
Perspective of Materials Characterisation and Performance Evaluation of Advanced Nanomaterials for Bioenergy Systems: A Systematic Review
by Mariam I. Adeoba, Harry Ngwangwa, Tracy Masebe and Thanyani Pandelani
Mater. Proc. 2026, 31(1), 26; https://doi.org/10.3390/materproc2026031026 - 12 May 2026
Viewed by 560
Abstract
Advanced nanomaterials are becoming increasingly critical for improving the efficiency, durability, and sustainability of bioenergy systems, with applications spanning biomass conversion, catalysis, and bioelectrochemical energy generation. This systematic bibliometric and thematic review analyses Scopus-indexed literature from 2020 to 2025 to elucidate global research [...] Read more.
Advanced nanomaterials are becoming increasingly critical for improving the efficiency, durability, and sustainability of bioenergy systems, with applications spanning biomass conversion, catalysis, and bioelectrochemical energy generation. This systematic bibliometric and thematic review analyses Scopus-indexed literature from 2020 to 2025 to elucidate global research trends in nanomaterial characterisation and performance evaluation for bioenergy applications. Bibliometric mapping using VOSviewer version 1.6.18 reveals a rapidly growing research landscape structured around three dominant themes: nanocatalysts for biodiesel and bioethanol production, nanostructured enhancements in bioelectrochemical and anaerobic digestion systems, and surface-engineered materials for energy conversion and storage. The review highlights the pivotal role of structural and morphological characterisation techniques including SEM, TEM, AFM, and XRD in establishing structure–property–performance relationships that underpin catalytic activity, electron transfer efficiency, and system stability. Beyond short-term catalytic and electrochemical metrics, increasing attention is given to mechanical stability, durability, and long-term operational reliability, which are shown to be critical determinants of scalability. Emerging strategies such as additive manufacturing and hybrid material systems enable the integration of nanomaterials into architected, mechanically robust structures, mitigating degradation and enhancing sustained performance. A concise conceptual framework is presented to link nanomaterial classes, characterisation challenges, targeted bioenergy applications, and scalability constraints. Despite significant progress, gaps remain in standardised characterisation protocols, durability-focused testing, and life-cycle assessment. Addressing these challenges is essential for translating laboratory-scale advances into scalable, sustainable bioenergy technologies. Full article
(This article belongs to the Proceedings of The 4th International Conference on Applied Research and Engineering)
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20 pages, 688 KB  
Article
Towards Circularity: A Qualitative Study of Circularity Adoption in Australian Architectural Practice
by Christopher Bamborough, Matthias Hank Haeusler, Michael J. Ostwald, Mohsen Kafaei, Yousef A. Y. Thaher, Daniel Oteng, Jane Burry, Mark Burry and Tim Schork
Architecture 2026, 6(2), 74; https://doi.org/10.3390/architecture6020074 - 12 May 2026
Viewed by 752
Abstract
This qualitative research investigates the adoption of Circular Economy (CE) principles in contemporary Australian architectural practice, referred to as circularity, to address climate change, resource scarcity, and increasing demands for built-environment resilience. The Australian government’s 2035 national circularity target, which aims to double [...] Read more.
This qualitative research investigates the adoption of Circular Economy (CE) principles in contemporary Australian architectural practice, referred to as circularity, to address climate change, resource scarcity, and increasing demands for built-environment resilience. The Australian government’s 2035 national circularity target, which aims to double 2024 levels, will have profound implications for architectural practice. This research examines the current and future ability of practices to adopt circularity. It addresses two specific knowledge gaps: (i) how circularity is currently being adopted by architectural practices in Australia, and (ii) what factors restrict or undermine this adoption. To address these gaps, the research draws on insights developed from focus groups and interviews (n = 33 participants) with professional Australian architectural service providers and closely related design and engineering practitioners. Qualitative data collection captured empirical evidence on the barriers, challenges, and opportunities for circularity, followed by NVivo-based Reflexive Thematic Analysis (RTA) that iteratively and inductively identified emerging themes. The findings indicate that architects’ and associated practitioners’ adoption of circularity in Australia is evident but constrained by short-term project horizons, fragmented responsibilities, limited procurement infrastructure, and uncertainty about material supply and skilled labour. The paper concludes that, despite some conceptual ambiguity and structural limitations in current practice models, adoption remains fragmented and selective and offers actions for architects and other stakeholders to address logistical infrastructure, regulatory frameworks, legal contracts, and barriers stemming from a short-term economic value mindset. Full article
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