@article{eprints1339,
           pages = {346--355},
           title = {Geotechnical Innovations for Seismic-Resistant Urban Infrastructure},
          number = {3s},
           month = {September},
          volume = {14},
       publisher = {Scienceline Publication, Ltd},
          author = {Ali Akbar Firoozi and Ali Asghar Firoozi},
            year = {2024},
         journal = {Journal of Civil Engineering and Urbanism},
        abstract = {As urban areas continue to expand into seismically active regions, the imperative for developing earthquake-resistant infrastructure has never been greater. This paper presents a comprehensive examination of innovative geotechnical engineering solutions aimed at enhancing the resilience of urban infrastructure against seismic threats. It explores cutting-edge approaches including advanced base isolation techniques, soil liquefaction mitigation strategies, and the incorporation of shape memory alloys (SMAs) in foundation systems. Through detailed case studies, such as the Tokyo Skytree, Christchurch's soil stabilization projects, and the San Francisco Bay Bridge retrofit, the effectiveness, adaptability, and sustainability of these solutions are demonstrated. The paper conducts a comparative analysis of these technologies based on cost, implementation feasibility, and seismic mitigation effectiveness, and assesses their sustainability in the context of urban development. Despite facing challenges such as high initial costs and the need for specialized expertise, the potential of these technologies to significantly improve the safety and sustainability of urban environments is clear. The study concludes with a call for continued innovation, interdisciplinary collaboration, and proactive policymaking to foster the widespread adoption of these critical advancements. This research not only contributes to the academic field but also provides practical insights for engineers, urban planners, and policymakers striving to build more resilient cities in the face of increasing seismic risks.},
        keywords = {Earthquake-Resistant Design, Geotechnical Engineering, Urban Resilience, Soil Liquefaction, Base Isolation Techniques, Shape Memory Alloys},
             url = {http://eprints.science-line.com/id/eprint/1339/}
}