CO2 Impact on Steel Slag Materials | #CarbonCapture

Introduction

Steel slag, a by-product generated during steel manufacturing, poses significant environmental challenges due to its disposal issues. However, it also presents an opportunity for carbon utilization through carbonation curing. By exposing steel slag to carbon dioxide, its properties can be enhanced while simultaneously reducing CO2 emissions. This study explores how varying CO2 concentrations influence the curing process, focusing on the carbon uptake, mechanical strength, and microstructural transformations of compact steel slag. The investigation aims to optimize the use of industrial flue gas as a sustainable means of CO2 sequestration and material strengthening.

Experimental Design and CO2 Concentration Range

The research examined a broad spectrum of CO2 concentrations, ranging from 0.04% (representing ambient atmospheric levels) to 27% (simulating industrial flue gas conditions). Compact steel slag samples were subjected to these environments for carbonation curing. The experimental setup allowed observation of how differing CO2 levels influence carbonation kinetics and hydration processes. Through controlled exposure and precise measurement, the study assessed both chemical and physical responses within the material. This range provided a realistic perspective on the potential use of actual industrial emissions for efficient steel slag treatment and carbon capture.

CO2 Uptake and Carbon Sequestration Efficiency

Results revealed that even at a relatively low CO2 concentration of 4%, steel slag demonstrated substantial carbon absorption, achieving a CO2 uptake of 7.3%. This outcome highlights the material’s inherent ability to act as an effective carbon sink. As CO2 concentration increased, the rate and extent of carbon sequestration also improved proportionally. The study confirms that carbonation curing is not only an environmentally beneficial process but also a practical approach for industrial-scale carbon capture, utilizing waste by-products from steel production to mitigate greenhouse gas emissions effectively.

Mechanical Strength Development

Mechanical testing showed a significant improvement in the compressive strength of compact steel slag following carbonation curing. Under 4% CO2 concentration, the material achieved a strength of 42.03 MPa after 72 hours of curing. Higher CO2 concentrations further enhanced this strength, suggesting a direct relationship between carbon uptake and material densification. The increased formation of calcium carbonate compounds within the matrix contributed to pore refinement and improved bonding between particles. This enhancement demonstrates that carbonation not only supports environmental sustainability but also leads to the production of durable and high-performance construction materials.

Microstructural Transformations

Microstructure analysis revealed distinct crystal morphology changes as CO2 concentration increased. Initially, the calcium carbonate formed primarily as aragonite, but at higher CO2 levels, it transitioned into the thermodynamically stable calcite form. This transformation indicated improved material stability and densification due to enhanced carbonation. The change from aragonite to calcite crystal structures provided evidence of effective CO2 interaction with steel slag components. These microstructural modifications directly influenced mechanical performance and durability, proving that higher CO2 environments facilitate the development of stronger and more compact materials.

Role of Carbonation and Hydration Mechanisms

Both carbonation and hydration reactions contributed to the overall consolidation of steel slag during curing. At lower CO2 concentrations, hydration dominated, leading to the formation of calcium silicate hydrates that bind particles together. As CO2 levels increased, carbonation became the primary mechanism, forming dense calcium carbonate matrices that improved strength and stability. This interaction between hydration and carbonation created a synergistic effect, optimizing the material’s performance. Understanding the balance between these two processes is essential for tailoring curing conditions to maximize both carbon capture and mechanical enhancement.

Conclusion

The study demonstrates that carbonation curing of steel slag under varying CO2 concentrations offers a dual advantage—effective carbon sequestration and improved material properties. Even low CO2 environments significantly enhance performance, while higher concentrations promote greater strength and structural stability. The transition from aragonite to calcite and the balance between hydration and carbonation highlight the process’s scientific and industrial potential. Utilizing industrial flue gas directly for curing opens promising avenues for sustainable construction materials and carbon management, transforming steelmaking waste into a valuable resource for environmental and engineering applications.

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#CO2,#SteelSlag,#CarbonCapture,#Sustainability,#GreenBuilding,#MaterialsScience,#ClimateAction,#Carbonation,#EcoMaterials,#FlueGas,

Bridge Health Monitoring #SHM

 

Introduction
Bridges play a pivotal role in ensuring national mobility and supporting economic activity, making their structural health a critical concern. Structural health monitoring (SHM) systems are essential for maintaining bridge safety and durability. However, sensor faults, environmental noise, and transmission issues can compromise the quality of SHM data. To mitigate these challenges, anomaly detection methods are widely employed. Despite their popularity, there is no comprehensive evaluation comparing these techniques. This review addresses that gap by systematically analyzing recent research in SHM anomaly detection.

Motivation and Research Gap
Existing reviews on bridge SHM anomaly detection are limited in scope and often fail to synthesize comparative insights. Most studies overlook real-time performance and multivariate data analysis, which are crucial for practical deployment. Moreover, previous work rarely provides a structured framework to classify detection methods comprehensively. These limitations highlight the need for a systematic review that evaluates different approaches across multiple dimensions. Understanding these gaps motivates the development of a more thorough taxonomy and evaluation methodology.

Methodology
This systematic literature review (SLR) analyzes 36 peer-reviewed studies published between 2020 and 2025, selected from eight reputable databases. Studies were evaluated using a four-dimensional taxonomy, including real-time capability, multivariate support, analysis domain, and detection method. Detection methods were further categorized into distance-based, predictive, and image-processing approaches. The review also assessed five key performance dimensions: robustness, scalability, real-world feasibility, interpretability, and data dependency. This methodology ensures a holistic comparison of contemporary anomaly detection techniques.

Taxonomy of Detection Methods
The review introduces a novel four-dimensional taxonomy to organize anomaly detection methods. Distance-based methods rely on similarity measures but are sensitive to environmental and dimensional variations. Predictive models balance performance with interpretability, making them practical in certain contexts. Image-processing techniques dominate the field, achieving high accuracy but requiring significant computational resources. Each category is evaluated in terms of real-time application and support for multivariate analysis. This taxonomy helps researchers identify suitable approaches for different SHM scenarios.

Comparative Evaluation
A detailed comparative evaluation revealed distinct strengths and weaknesses among methods. Image-processing methods are most frequently applied (22 studies) but face scalability challenges. Predictive models provide a balanced trade-off between interpretability and accuracy. Distance-based methods are less common due to sensitivity issues. Only 11 studies demonstrate real-time anomaly detection capabilities, while multivariate analysis remains underutilized. Time-domain signal processing dominates, whereas frequency and time-frequency methods are rarely applied, despite their potential advantages.

Challenges and Future Directions
Current SHM anomaly detection approaches face challenges in scalability, robustness, interpretability, and practical deployment. Existing models often lack adaptability and fail to handle multi-modal or uncertain data efficiently. Future research should focus on developing adaptive, interpretable frameworks suitable for real-world monitoring. Standardized evaluation protocols and cross-environment testing are necessary to validate performance. Combining predictive, distance-based, and image-processing strategies may enhance accuracy and reliability. The field needs innovation to ensure SHM systems remain practical and effective.

Conclusion
This review systematically examined recent studies in bridge SHM anomaly detection, highlighting trends, strengths, and gaps. Image-processing methods dominate but require computational optimization. Predictive and distance-based approaches offer trade-offs between accuracy and interpretability. Real-time and multivariate analysis remain underexplored. Future work should focus on adaptive, scalable, and interpretable models with multi-modal capabilities. Implementing such frameworks will enhance bridge safety and ensure reliable monitoring across diverse environments.

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#BridgeMonitoring, #StructuralHealth, #SHM, #CivilEngineering, #AnomalyDetection, #SmartInfrastructure, #BridgeSafety, #StructuralIntegrity, #EngineeringResearch, #InfrastructureHealth,

Fatigue Performance of Reinforced Concrete T-Girders under Cyclic Loading #CivilEngineering

 

Introduction

The retraction of the article “Fatigue Performance of Reinforced Concrete T-Girders under Cyclic Loading” highlights the importance of data reliability in experimental research. The decision was made following the discovery of a faulty loading instrument used during the study, which affected the accuracy of the results. Such issues emphasize the critical role of precise equipment calibration and validation in civil engineering research, ensuring that outcomes are trustworthy and reflective of actual structural behavior under loading conditions.

Fatigue Behavior of Reinforced Concrete T-Girders

Fatigue performance studies of reinforced concrete T-girders are vital for understanding how repeated cyclic loading affects structural durability. These girders are commonly used in bridges and heavy load-bearing structures, where long-term performance under stress is crucial. Accurate experimental data allow engineers to predict service life, design safer structures, and optimize reinforcement strategies. However, faulty instruments compromise the validity of findings, potentially leading to unsafe applications if design standards are influenced by unreliable results.

Importance of Experimental Accuracy in Structural Engineering

In structural engineering, experimental precision directly influences design guidelines, safety codes, and performance predictions. Small measurement errors can magnify in fatigue studies, where cyclic loading spans millions of cycles. The retraction underscores how equipment faults, if unnoticed, distort stress-strain relationships, crack development patterns, and load-bearing predictions. Researchers must maintain strict calibration protocols, apply redundancy in measurements, and validate experimental results against theoretical models or simulations to preserve scientific integrity and structural safety.

Role of Instrumentation in Fatigue Testing

Instrumentation plays a pivotal role in fatigue testing by capturing load responses, displacement, strain, and stress ranges over time. In this case, the faulty loading machine introduced significant deviations that went beyond acceptable tolerance levels. Such inaccuracies not only distort the data but can also mask or exaggerate structural behaviors. Ensuring proper maintenance, calibration, and certification of instruments is therefore fundamental in civil engineering research, particularly for fatigue and durability studies where precision is paramount.

Data Reliability and Abnormal Trends

The authors observed an abnormal trend in Figure 10(b), where the rebar stress range of specimen F-4 decreased unexpectedly after 80% of its fatigue life. This anomaly raised questions about data reliability, eventually traced back to equipment malfunction. Detecting abnormal patterns is crucial in research, as it allows early identification of errors or inconsistencies. Cross-validation with multiple data sources, careful statistical checks, and repeat testing can help mitigate such risks and improve overall study robustness.

Ethical Responsibility in Research Publication

The decision of the authors to contact the journal and acknowledge the instrument fault reflects strong ethical responsibility. In research, integrity is more valuable than results, as publications directly influence future work, professional practices, and public safety. By retracting the article, the authors ensured that potentially misleading findings are not used in engineering applications. Such accountability sets a positive example for the academic community, reinforcing the principle that transparency is essential in scientific advancement.

Conclusion

The retraction of this study illustrates the challenges and responsibilities inherent in civil engineering research. While fatigue performance remains a critical area of investigation, the accuracy of results is inseparable from reliable instrumentation and data validation. This case emphasizes that the credibility of structural research depends not only on experimental design but also on ethical conduct and rigorous verification. Future investigations must integrate stricter checks to ensure safe, valid, and reproducible knowledge for engineering practice.

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#Fatigue, #Concrete, #RC, #TGirders, #Cyclic, #Loading, #Structural, #Performance, #Strength, #Durability, #Flexural, #Civil, #Engineering, #Bridge, #Design, #Research, #Construction, #Testing, #Load, #Behavior, #Failure, #Analysis, #Experiment, #Reinforced, #Material, #FatigueTest, #StructuralHealth, #LoadCycle, #Infrastructure, #Sustainability,

Steel Slag in Rubber Asphalt Mix #RoadPerformance

Introduction

The incorporation of steel slag in asphalt mixtures has gained significant attention due to its potential to improve road performance and promote sustainable pavement solutions. This research focuses on evaluating the effect of steel slag coarse aggregate (SSCA) as a partial or complete replacement for natural aggregates, investigating its influence on road performance and determining optimal blending ratios for improved durability and cost-effectiveness.

Influence of Steel Slag Content and Gradation

The content and gradation of steel slag play a crucial role in determining the mechanical and structural performance of asphalt mixtures. The study analyzed the substitution of natural aggregates with SSCA in varying proportions (0%, 25%, 50%, 75%, and 100%), aiming to understand its impact on mixture stability, strength, and durability. Proper gradation ensures better aggregate interlocking, leading to improved load-bearing capacity and long-term road performance.

Experimental Methodology and Testing Procedures

To evaluate the effect of SSCA substitution, asphalt mixtures were subjected to several performance tests. These included expansion rate analysis, rutting resistance, immersion Marshall stability, low-temperature crack resistance, and freeze-thaw splitting tests. These comprehensive evaluations helped in understanding the mechanical behavior of the mixtures under various environmental and loading conditions, ensuring reliable performance insights.

Results and Performance Evaluation

The findings revealed that incorporating SSCA improved several key properties, including oil-stone ratio, dynamic stability, residual stability after immersion, flexural tensile strength, and fatigue life. However, an increase in SSCA content also led to a reduction in Marshall flow values and a slight risk of mixture expansion. The research concluded that a 100% SSCA content provides optimal high-temperature stability and water resistance, while a 50% substitution delivers the best fatigue performance.

Optimal Substitution Ratios and Application Potential

Considering various performance aspects, the study recommended different optimal blending ratios: 100% SSCA for high-temperature stability and water resistance, and 50% SSCA for enhanced fatigue life. The findings highlight the potential of SSCA as a sustainable alternative to natural aggregates, offering significant benefits in pavement durability, environmental conservation, and resource recycling.

Economic Feasibility and Field Test Analysis

A field test conducted using asphalt mixtures containing 100% 9.5–16 mm SSCA demonstrated excellent performance in real-world conditions. Additionally, an economic cost analysis revealed that using SSCA could reduce construction costs by approximately 7.9%. This emphasizes the practical viability and economic advantages of implementing steel slag in large-scale pavement engineering projects.

Conclusion

The research confirms that the incorporation of steel slag coarse aggregate significantly enhances asphalt mixture performance while reducing construction costs. With optimal blending ratios identified, SSCA presents a promising alternative for sustainable pavement engineering. Its technical benefits, environmental advantages, and economic value make it an ideal material for future road construction projects, promoting recycling and reducing reliance on natural aggregates.

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#RoadPerformance, #SteelSlag, #RubberAsphalt, #ARAC13, #PavementEngineering, #SustainableRoads, #AsphaltMixtures, #CivilEngineering, #RoadConstruction, #EcoFriendlyRoads, #PavementDesign, #DurablePavement, #RecycledMaterials, #HighPerformanceRoads, #GreenInfrastructure, #SlagUtilization, #RubberizedAsphalt, #InfrastructureInnovation, #RuttingResistance, #SmartRoads, #sciencefather, #ResearchAwards, #SustainablePavement, #MaterialInnovation, #AsphaltTechnology,

Steel Pipeline Failure Prevention

 Introduction

The reliability and durability of steel pipeline infrastructure are increasingly threatened by complex degradation mechanisms. As these systems operate under demanding conditions, understanding the root causes of material deterioration becomes crucial for safety and performance. This study investigates the primary factors leading to pipeline failures, focusing on selective corrosion and erosion. By integrating macroscopic analysis, corrosion testing, microscopic examination, tensile strength testing, and finite element method (FEM) modeling, the research aims to uncover the mechanisms behind structural weaknesses. The findings provide insights into both localized and system-wide damage, offering a foundation for developing preventive maintenance and design strategies.

Selective Corrosion in Heat-Affected Zones
Selective corrosion, particularly in the heat-affected zones (HAZs) of longitudinal welds, emerged as the primary degradation mechanism affecting steel pipelines. The study revealed significant pit formations, with depths reaching up to 6 mm, severely compromising material strength. These localized defects result from electrochemical differences between the weld and the surrounding metal, creating areas more susceptible to corrosion. Over time, these pits propagate, weakening the structural integrity and creating points of vulnerability. By identifying this pattern, targeted maintenance can focus on high-risk weld areas, enhancing inspection efficiency and reducing the probability of unexpected failures in critical sections of the pipeline network.

Erosion and Its Compounding Effect
Erosion, often caused by high-velocity fluid flow and particulate matter, was found to significantly accelerate the corrosion process in steel pipelines. This mechanical wear not only removes protective surface layers but also exposes fresh metal to aggressive environmental conditions, intensifying selective corrosion. The study highlights that high-stress regions are particularly vulnerable, as erosion creates micro-grooves and roughness, allowing corrosive agents to penetrate more easily. When erosion and selective corrosion act together, degradation rates increase sharply, shortening the service life of pipelines. Recognizing this synergistic effect underscores the need for erosion control measures in environments with abrasive or turbulent fluid conditions.

Mechanical Strength Reduction
Testing revealed that selective corrosion and erosion contribute to a substantial reduction in tensile strength, with losses reaching up to 30% in severely affected sections. This weakening results from localized material removal and microstructural changes, which undermine the load-bearing capacity of pipelines. In high-pressure environments, such strength reductions pose significant risks, potentially leading to catastrophic failures. The study’s mechanical testing confirmed the direct correlation between pit depth and tensile strength degradation. This emphasizes the need for consistent mechanical property monitoring in pipelines, enabling operators to detect early-stage deterioration before it escalates into a failure scenario with costly consequences.

FEM Analysis and Failure Prediction
Finite Element Method (FEM) modeling played a critical role in predicting pipeline behavior under different degradation scenarios. The analysis demonstrated that material loss exceeding 8 mm in weld areas subjected to 16 bar operating pressure could induce critical stress levels, raising the likelihood of structural failure. FEM simulations provided visual and quantitative assessments of stress concentrations, enabling predictive maintenance planning. By integrating FEM with real-time monitoring data, operators can identify high-risk areas well before they reach dangerous thresholds. This proactive approach allows for targeted repairs and operational adjustments, minimizing downtime and extending the service life of pipelines.

Conclusion
This study underscores the urgent need for a proactive and integrated approach to managing steel pipeline degradation. Selective corrosion in weld heat-affected zones and erosion in high-stress areas represent major threats to structural integrity, leading to significant mechanical strength reductions and elevated failure risks. The combination of macroscopic and microscopic examinations, mechanical testing, and FEM modeling provides a comprehensive understanding of these mechanisms. Practical solutions include adopting corrosion-resistant materials like duplex steels and implementing continuous, non-destructive monitoring systems linked with FEM-based predictive tools. By applying these strategies, pipeline operators can enhance safety, reliability, and long-term operational efficiency.

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#PipelineSafety, #SteelPipelines, #FailureAnalysis, #DegradationMechanisms, #CorrosionControl, #InfrastructureSafety, #PipelineEngineering, #PreventiveStrategies, #PipelineMaintenance, #OilAndGasPipelines, #WaterInfrastructure, #StructuralIntegrity, #MechanicalDamage, #PipelineInspection, #CorrosionPrevention, #PipelineProtection, #SafetyEngineering, #ReliabilityEngineering, #EngineeringInnovation, #InfrastructureDurability, #sciencefather, #ResearchAwards, #PipelineReliability, #AssetManagement, #CivilEngineering,

Geopolymer Concrete & Carbon Footprint: What LCA Reveals

 

1. Introduction 🌍

Concrete production significantly contributes to global carbon emissions, primarily due to the use of cement. This study explores a sustainable alternative by estimating the carbon footprint of conventional and geopolymer concrete materials. By analyzing the environmental impact of various design components, it seeks to identify effective low-carbon alternatives. The focus lies on evaluating alkali-activated materials as replacements for cement. A comprehensive methodology is employed to assess emissions and associated uncertainties.

2. Geopolymer Concrete Components and Emission Factors 🧱

The study examines major constituents of geopolymer concrete—fly ash, GGBS, sodium hydroxide, sodium silicate, and superplasticizers. Each component's carbon footprint is assessed to mirror actual production and application conditions. This detailed evaluation helps determine where emissions are most concentrated. The analysis acknowledges the complex interaction between these materials. Their production processes, especially those involving chemicals, have both advantages and drawbacks for sustainability.

3. Life Cycle Assessment with SimPro 9.4 🧮

A robust Life Cycle Assessment (LCA) is conducted using SimPro 9.4 software. This tool enables the calculation of emissions throughout the concrete's lifecycle—from raw material extraction to usage. Unlike simple emission estimates, the LCA accounts for transportation, energy input, and material processing. This systemic evaluation gives a clearer picture of environmental costs. It forms the basis for comparing geopolymer and conventional concrete impacts.

4. Uncertainty Analysis via Monte Carlo Simulation 🎲

To address the variability in environmental data, the @RISK Monte Carlo simulation is integrated into the study. This approach simulates a range of scenarios to estimate probable emission outcomes. Rather than a single fixed value, it highlights the spread and likelihood of carbon emissions. It is especially useful in understanding uncertainties related to chemical admixtures. The analysis thus ensures a more reliable and risk-informed sustainability assessment.

5. Emission Reduction Potential and Associated Risks 📉⚠️

The results show that replacing cement with alkali-activated binders can cut carbon emissions by up to 43%. However, this benefit is sensitive to the quantity and type of chemical admixtures used. Overuse of activators like sodium silicate or NaOH may offset the environmental gains. Pearson correlation values reveal strong associations between these chemicals and carbon output. Hence, caution is necessary to avoid negative outcomes while pursuing emission reductions.

6. Correlations Between Admixtures and Environmental Impact 🔗

Statistical analysis shows a high correlation between carbon footprint and sodium silicate (r = 0.80), followed by NaOH (r = 0.52) and superplasticizer (r = 0.19). These results suggest that while geopolymer technology has promise, it comes with caveats. Even small shifts in admixture proportions can significantly alter environmental outcomes. This emphasizes the need for precise formulation and process control in eco-friendly concrete design. Optimizing chemical inputs is vital for sustainability.

7. Conclusion 🌱

This study highlights that geopolymer concrete can substantially reduce emissions, but its effectiveness depends on careful material management. Life cycle assessment and uncertainty modeling together offer a comprehensive picture of environmental trade-offs. Chemical admixtures play a critical role in this balance, necessitating regulated use and innovation in cleaner production methods. Harnessing renewable energy in chemical activator production could further enhance sustainability. The findings advocate for cautious yet optimistic adoption of geopolymer technologies.

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#SustainableConcrete,#GeopolymerConcrete,#CarbonFootprint,#LifeCycleAssessment,#GreenBuilding,#LowCarbonMaterials,#EcoConcrete,#ConstructionSustainability,#CementAlternatives,#CarbonReduction,#ConcreteTechnology,#EnvironmentalImpact,#LCAStudy,#SustainableConstruction,#CleanConstruction,#GreenInfrastructure,#CircularConstruction,#ConcreteEmissions,#CarbonAnalysis,#CementFreeConcrete,#ClimateSmartMaterials,#LCAResearch,#ZeroCarbonConstruction,#GreenMaterials,#EnvironmentalEngineering

Risk Management for Bridge Networks: Sustainability & Connectivity

 

Introduction 

Bridges are critical infrastructures that often face damage from natural aging and extreme events like earthquakes. Over time, their structural integrity can degrade, increasing vulnerability and operational risks. The combined effects of seismic activity and material deterioration pose significant threats to network safety. A proactive risk management approach is essential for ensuring long-term serviceability. This study introduces a comprehensive framework to evaluate and prioritize bridge interventions.

Seismic Fragility Analysis of Bridges 

Seismic fragility analysis assesses the vulnerability of bridges under different earthquake intensities. It quantifies the probability of failure or damage based on structural parameters and seismic load scenarios. This analysis provides critical insight into which bridges are most likely to fail during seismic events. It forms the foundation of the broader risk management strategy. Accurate fragility assessments help in making data-driven decisions for retrofitting and planning.

Multi-Attribute Utility Ranking Method 

To address the complexity of prioritizing bridge projects, a multi-attribute utility method is employed. This approach combines several performance indicators—structural condition, network role, and sustainability metrics—into a single prioritization index. Unlike traditional single-factor methods, this comprehensive model accounts for broader impacts. It ensures that decisions are not skewed toward any one attribute. The result is a more balanced and holistic prioritization of bridge interventions.

Integrating Sustainability and Network Connectivity 

Sustainability and network connectivity are crucial for resilient transportation systems. The proposed framework integrates economic, environmental, and social factors alongside connectivity indicators. This inclusion ensures that decisions do not solely focus on immediate repair needs but also consider long-term regional development and mobility. Network centrality and redundancy are evaluated to maintain continuity in transport services. This leads to better planning across diverse infrastructure goals.

Risk Management Strategies: Retrofitting vs. New Construction 

Two key strategies are considered—retrofitting old bridges and constructing new ones. Retrofitting is cost-effective and quickly improves weak links, while new construction supports expanding or rerouting the network. The proposed framework guides when to apply each strategy based on condition, location, and impact. It ensures efficient resource allocation by focusing on real network needs. This dual-path approach improves resilience without unnecessary investment.

Case Study: Regional Bridge Network Validation 

The framework is applied to a regional bridge network to test its real-world effectiveness. Simulation results show that retrofitting guided by the ranking method improves all key performance indicators. Unlike single-attribute methods, it avoids imbalances like overemphasis on one metric. The framework also enhances connectivity and reduces the likelihood of total network failure. This validation demonstrates the practical value of the proposed model for policy and planning.

Conclusion 

The proposed risk management framework offers a robust, integrated method for prioritizing bridge maintenance and development. By combining seismic fragility, sustainability, and connectivity into a unified approach, it ensures balanced, long-term infrastructure resilience. Case study results confirm the model's capability to guide strategic decisions across multiple dimensions. Bridge managers can use this method for systematic, informed planning. Ultimately, it supports safer, more sustainable transport networks.

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#BridgeInfrastructure, #RiskManagement, #SustainableEngineering, #NetworkConnectivity, #InfrastructureResilience, #BridgeSafety, #TransportPlanning, #CivilEngineering, #InfrastructureRisk, #ClimateAdaptation, #StructuralEngineering, #SmartInfrastructure, #UrbanConnectivity, #BridgeNetworks, #SustainableBridges, #DisasterPreparedness, #RiskMitigation, #InfrastructureStrategy, #ResilientCities, #SystemReliability, #BridgeManagement, #LifelineInfrastructure, #TransportNetworks, #InfrastructureSustainability, #UrbanTransport