Industrial-waste-based soil stabilizer and cement based on life cycle assessment

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     A comparative sustainability investigation between a novel industrial-waste-based soil stabilizer and traditional cement has been conducted using Life Cycle Assessment (LCA) methodology. The study evaluates the environmental impacts associated with each stabilizing material from cradle to grave—including raw material extraction, production processes, transportation, application, and end-of-life scenarios. Results show that the industrial-waste-based stabilizer significantly reduces greenhouse gas emissions, energy consumption, and resource depletion compared to conventional cement. This eco-innovative solution not only diverts industrial by-products from landfills but also offers a low-carbon alternative in geotechnical and construction applications. The findings underscore the potential of circular economy strategies in soil stabilization while promoting environmentally conscious infrastructure development.

#SustainableConstruction #SoilStabilization #LifeCycleAssessment #IndustrialWasteReuse #EcoFriendlyMaterials #GreenInfrastructure #LowCarbonConstruction #EnvironmentalImpact #CircularEconomy #CementAlternatives #SustainableEngineering #WasteToValue #SoilScience #GeotechnicalInnovation #EcoInnovation #ResourceEfficiency #CarbonFootprintReduction #GreenTechnology #SustainableMaterials #LCAStudy




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