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The main goal of this research is to quantitatively assess the resilience and vulnerability of geotechnical infrastructure to extreme events under a changing climate. In the first part, pertinent facts and statistics regarding California’s extreme drought and current status of its levees are presented. Weakening processes such as soil strength reduction, soil desiccation cracking, land subsidence and surface erosion, and oxidation of soil organic carbon are comprehensively evaluated to illustrate the devastating impacts that the California drought can have on earthen structures. In the second part, rainfalltriggered slope instabilities are analyzed using extreme precipitation estimates, derived using the historical stationary and a proposed future nonstationary approach. The extremes are integrated into a series of fully coupled 2D finite element simulations. The final part of this study investigates the impact of simultaneous variations in soil moisture and temperature changes in the California region on soil strength through a proposed thermo-hydro-mechanical framework.
This single-volume thoroughly summarizes advances in the past several decades and emerging challenges in fundamental research in geotechnical engineering. These fundamental research frontiers are critically reviewed and described in details in lights of four grand challenges our society faces: climate adaptation, urban sustainability, energy and material resources, and global water resources. The specific areas critically reviewed, carefully examined, and envisioned are: sensing and measurement, soil properties and their physics roots, multiscale and multiphysics processes in soil, geochemical processes for resilient and sustainable geosystems, biological processes in geotechnics, unsaturated soil mechanics, coupled flow processes in soil, thermal processes in geotechnical engineering, and rock mechanics in the 21st century.
This reference text establishes linkages between the user industries and the providers of clean technologies and sustainable materials for a rapid transformation of the small and medium-sized enterprises (SMEs). The text covers several aspects of sustainable applications including clean technologies, climate change and its effects, sustainable buildings (smart cities), sustainability in road construction, sustainable use of geosynthetic, innovative materials, and sustainable construction practices. The text will be useful for senior undergraduate students, graduate students, and researchers in the fields of civil engineering and other infrastructure-related professionals and planners. The book: Discusses clean technologies and sustainable materials in depth Covers concepts of sustainability in road construction, and water retaining structures Examines environmental policies and practices Discusses climate change and its effects in a comprehensive manner Covers sustainable buildings including smart cities As this book discusses concepts related to sustainable civil engineering practices in a single volume, it will be an ideal reference text for everyone aiming at developments of sustainable infrastructures.
This volume arises from the work of Roorkee Water Conclave 2020 and focuses on the hydrological aspects of climate change, hydrological extremes, and adaptation for water resources management. The research papers in this book are centred on themes such as climate change and water security, water resources management, and adaptation to climate change. This volume contains chapters on historical purview of the developments in water management, policy issues, latest development in sustainable water management including their practical applications, real time adverse impact on climate, and more. This volume will be useful to students, researchers as well as practitioners.
This book gives an overview of various aspects of climate change by integrating global climate models, downscaling approaches, and hydrological models. It also covers themes that help in understanding climate change in a holistic manner. The book includes worked-out examples, revision questions, exercise problems, and case studies, making it relevant for use as a textbook in graduate courses and professional development programs. The book will serve well researchers, students, as well as professionals working in the area of hydroclimatology.
Degradation and erosion of permafrost have induced irreversible damage to civil infrastructure across the Arctic. These unprecedented changes are now threatening indigenous Arctic communities, urging them to consider community-wide relocations. It is therefore important to understand the geotechnical implications of permafrost affected by the changing climate. In this dissertation, a comprehensive research framework is developed to understand the effects of permafrost degradation and permafrost coastal erosion and their potential impacts on civil infrastructure in the Arctic. This dissertation aims to facilitate a physics-informed, culturally relevant, and inclusive infrastructure planning process for the Arctic community by bridging the experience of indigenous Arctic communities and the expertise of multidisciplinary scientific communities. A community survey is first designed and conducted to understand the effects of permafrost degradation and coastal erosion on civil infrastructure. Observations were collected from residents in four Arctic coastal communities: Point Lay, Wainwright, Utqiaġvik, and Kaktovik. The types, locations, and periods of observed permafrost thaw and coastal erosion were elicited. Survey participants also reported the types of civil infrastructure being affected by permafrost degradation and coastal erosion and any damage to residential buildings. This study shows a useful approach to coproduce knowledge with Arctic residents to identify locations of permafrost thaw and coastal erosion at higher spatial resolution as well as the types of infrastructure damage of most concern to Arctic residents. Then, the state-of-practice of coastal erosion control measures in permafrost regions are synthesized. The study shows the challenges in constructing the current erosion control measures and the escalating cost of the measures over the last four decades. Emerging solutions and research gaps are also identified and discussed so that these measures may be upscaled for full-scale applications in the future. In this dissertation, the physical processes of permafrost degradation are synthesized and presented in a geotechnical context. Geophysical and geomechanical properties of permafrost that are critical for the assessment of foundation performance under permafrost degradation are identified, collected, and analyzed. While the data collected are highly scattered, regression analysis shows that most of the geomechanical and geophysical properties have strong associations with temperature. These associations highlight that the ongoing warming can greatly affect the performance of civil infrastructures in the Arctic. Finally, a three-dimensional fully coupled thermo-hydro-mechanical (THM) model is developed to simulate permafrost degradation. Physical processes such as heat conduction, phase change, thermal convection, fluid flow due to pore water pressure, elevation, and thermal gradient, and force equilibrium based on effective stress theory are considered in this model. The THM model is validated using thaw settlement results from the literature. A parametric study is also conducted to investigate the influences of various input parameters on the thermo-hydro-mechanical behaviors of permafrost with temperature.
The world’s fresh water supplies are dwindling rapidly—even wastewater is now considered an asset. By 2025, most of the world's population will be facing serious water stresses and shortages. Aquananotechnology: Global Prospects breaks new ground with its informative and innovative introduction of the application of nanotechnology to the remediation of contaminated water for drinking and industrial use. It provides a comprehensive overview, from a global perspective, of the latest research and developments in the use of nanotechnology for water purification and desalination methods. The book also covers approaches to remediation such as high surface area nanoscale media for adsorption of toxic species, UV treatment of pathogens, and regeneration of saturated media with applications in municipal water supplies, produced water from fracking, ballast water, and more. It also discusses membranes, desalination, sensing, engineered polymers, magnetic nanomaterials, electrospun nanofibers, photocatalysis, endocrine disruptors, and Al13 clusters. It explores physics-based phenomena such as subcritical water and cavitation-induced sonoluminescence, and fog harvesting. With contributions from experts in developed and developing countries, including those with severe contamination, such as China, India, and Pakistan, the book’s content spans a wide range of the subject areas that fall under the aquananotechnology banner, either squarely or tangentially. The book strongly emphasizes sorption media, with broad application to a myriad of contaminants—both geogenic and anthropogenic—keeping in mind that it is not enough for water to be potable, it must also be palatable.