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Description
This book presents a groundbreaking exploration of recent advancements that are reshaping the field of civil and environmental engineering. It explores the latest findings in eco-friendly building materials and cutting-edge construction techniques. The authors cover topics like low-carbon alternatives, recycled materials, and emerging innovations that enhance durability, efficiency, and sustainability in the built environment. This book also delves into the integration of technologies such as machine learning, bio-inspired materials, carbon capture systems, and nature-based solutions, all aimed at creating resilient and environmentally friendly infrastructure. centred on sustainability, it highlights practical applications, case studies, and innovative strategies to tackle contemporary challenges including climate change, resource scarcity, and rapid urbanization. Designed for engineers, researchers, and policymakers, the book fosters collaboration and inspires forward-thinking solutions for sustainable infrastructure development. Its core mission is to address modern challenges in civil and environmental systems while empowering professionals to navigate complex technologies and build a sustainable future.
AI-Driven Prediction and Optimization of Fresh Properties in Self-Compacting Concrete .- 3D Concrete Printing: Mixture Design, Rheology, and Structural Integration.- Self-Healing Concrete using Microbial and Chemical Agents: Advances and Limitations.- Self-Healing Properties of Calcium Sulfoaluminate Cement in Concrete: A Review.- Artificial Neural Network-Based Prediction of High Strength Self-Compacting Concrete Compressive Strength: A Machine Learning Perspective.- Ultra-High-Performance geopolymer concrete: Material science, structural applications, and mix design.- 3D-Printed versus Cast Concrete: Fresh and Hardened Properties.- Technological Evolution of 3D Concrete Printing for Next-Generation Sustainable Infrastructure.- Sustainable Pervious concrete: A review on enhancing longevity through Material Optimization and Maintenance Strategies.- Study of the response of reinforced concrete dapped end beams under varying load: a critical review.- Breaking Down Microplastics: Advances in Detection and Removal in Wastewater Treatment Plants.- Reactivity Enhancement of Coal Bottom Ash: Mechanical Activation for Sustainable Cementitious Applications.- An applicability-based review of geothermal energy piles as a sustainable infrastructure solution.- BIM and AR- Enabled Digital Twins for Sustainable Infrastructure Management.- GIS-Based Vulnerability Index Approach for Groundwater Risk Assessment: A Case Study of Jeypore, Odisha, India.- Leveraging Digital Twin Technology for Smart Construction Materials Monitoring and Management: A Framework for Emerging Economies.- Scalable Digital Twin Framework for Residential Re-Construction: Advancing Smart Asset Management for Small-Scale Projects.- Sustainability enabled conflict resolution in transportation projects through principle-based evaluation.- Remote Sensing Strategies for Hydrothermal Mineral Exploration to Support Resilient Infrastructure in the RSH, Northeast Sudan.- In-Situ Load Testing and Settlement Response of Stone Columns beneath Railway Embankments: A Case Study from WDFCCIL.
Dr. Peerzada Danish received his Ph.D. in Structural Engineering (Civil Engineering) from Vellore Institute of Technology (VIT), Vellore, with research focused on self-compacting concrete incorporating mineral admixtures as supplementary materials. He is currently a Postdoctoral Research Associate III at the Indian Institute of Science (IISc), Bengaluru, working on the development of low-carbon alternative materials for dam construction and rehabilitation under projects supported by the Ministry of Jal Shakti (MoJS, GOI), Central Water Commission, Government of India, and the World Bank. He has authored more than 20 Scopus-indexed publications, along with books and book chapters. Dr. Danish previously served as an Assistant Professor at several universities and institutes, teaching undergraduate and postgraduate courses and supervising student research. His research interests include sustainable construction materials, alkali-activated binders, and durable infrastructure systems.
Dr. Jasir Mushtaq is a Saudi Aramco Approved Environmental Engineer with over six years of professional experience in environmental management across the Gulf region and India. He holds a Ph.D. in Civil & Environmental Engineering from the National Institute of Technology Srinagar, India. His expertise includes solid waste management, environmental monitoring, carbon footprint assessment, and sustainable infrastructure development. Dr. Mushtaq has authored several international journal publications and book chapters focusing on climate change, waste management, and environmental sustainability. He is actively involved in implementing international environmental standards and promoting sustainable engineering practices.
Dr. Imen Ben Salem is an Associate Professor in the Department of Natural Sciences and Sustainability at Zayed University. Her multidisciplinary research spans carbon capture and sequestration, sustainable materials, clean-energy technologies, CFD modeling, optical diagnostics, and remote sensing, with applications in both Earth and planetary sciences. Her work supports several UN Sustainable Development Goals, including SDG 7 (Affordable and Clean Energy), SDG 9 (Industry, Innovation and Infrastructure), SDG 11 (Sustainable Cities and Communities), SDG 13 (Climate Action), and SDG 15 (Life on Land). Her recent research focuses on developing cost-effective and environmentally friendly mineralization pathways using agricultural-waste biochar to enhance CO2 capture and long-term storage. In addition, she explores sustainable construction materials, including biochar-enhanced concrete systems aimed at reducing carbon footprint while improving environmental performance. Her work combines experimental investigations with modeling approaches to assess scalable negative-emission strategies and sustainable deployment frameworks. She previously worked as a postdoctoral researcher at the Masdar Institute in collaboration with the Massachusetts Institute of Technology (MIT), studying CO2 behavior in saline aquifers using integrated experimental and CFD modeling techniques. At Zayed Universi
