The basis of the design of earth and rockfill dams is focused on ensuring the stability of the structure under a set of conditions expected to occur during its life.Combined mechanical and hydraulic conditions must be...The basis of the design of earth and rockfill dams is focused on ensuring the stability of the structure under a set of conditions expected to occur during its life.Combined mechanical and hydraulic conditions must be considered since pore pressures develop during construction,after impoundment and in drawdown.Other instability phenomena caused by transient flow and internal erosion must be considered.The prediction of the hydromechanical behavior of traditional and non-traditional materials used in the construction of dams is therefore fundamental.The materials used for dam’s construction cover a wide range from clayey materials to rockfill.In a broad sense they are compacted materials and therefore unsaturated materials.A summary of the current level of knowledge on the behavior of traditional materials used in the construction of dams is presented in the paper.Regular compacted materials(with a significant clay fraction),rockfill and compacted soft rocks are studied with more detail.The latter are non-traditional materials.They are analysed because their use,as well as the use of mixtures of soil and rock,is becoming more necessary for sustainability reasons.展开更多
As a result of climate change and increasing engineering activities, soil-related disasters such as slope failures and sandstorms have become more frequent worldwide. These disasters have caused not only loss of life,...As a result of climate change and increasing engineering activities, soil-related disasters such as slope failures and sandstorms have become more frequent worldwide. These disasters have caused not only loss of life, but also have led to serious economic losses as well as ecological and environmental damage. To sustain mankind, a new discipline, eco-geotechnics, has rapidly become established and developed in recent years. It integrates scientific knowledge from soil mechanics, rock mechanics,ecology, biology, and atmospheric science to develop cross-disciplinary theories and carry out experiments to tackle grand world challenges such as the effects of climate change. Through the development of eco-geotechnics, various eco-friendly technologies have been developed to mitigate sandstorms and to improve the performance of earthen structures such as embankments, slopes and landfill covers. This state-of-the-art review introduces and discusses the important advances in the field of eco-geotechnics,covering theoretical developments, laboratory testing, centrifuge modelling, field monitoring and engineering applications.Finally, the research gaps and future needs of eco-geotechnics are highlighted and discussed.展开更多
文摘The basis of the design of earth and rockfill dams is focused on ensuring the stability of the structure under a set of conditions expected to occur during its life.Combined mechanical and hydraulic conditions must be considered since pore pressures develop during construction,after impoundment and in drawdown.Other instability phenomena caused by transient flow and internal erosion must be considered.The prediction of the hydromechanical behavior of traditional and non-traditional materials used in the construction of dams is therefore fundamental.The materials used for dam’s construction cover a wide range from clayey materials to rockfill.In a broad sense they are compacted materials and therefore unsaturated materials.A summary of the current level of knowledge on the behavior of traditional materials used in the construction of dams is presented in the paper.Regular compacted materials(with a significant clay fraction),rockfill and compacted soft rocks are studied with more detail.The latter are non-traditional materials.They are analysed because their use,as well as the use of mixtures of soil and rock,is becoming more necessary for sustainability reasons.
基金supported by the National Natural Science Foundation of China (Grant No. U20A20320)the Environment and Conservation Fund (Grant No. ECWW19EG01)+2 种基金the Research Grants Council of the Hong Kong Special Administrative Region, China (Grant Nos. Ao E/E-603/18, 16209522, 16210420, 16207819, 16212218)the support by the Fundamental Research Funds for the Central Universities (Grant No. 3221002220A1)the State Key Laboratory of Subtropical Building Science in South China University of Technology (Grant No. 2022ZC01)。
文摘As a result of climate change and increasing engineering activities, soil-related disasters such as slope failures and sandstorms have become more frequent worldwide. These disasters have caused not only loss of life, but also have led to serious economic losses as well as ecological and environmental damage. To sustain mankind, a new discipline, eco-geotechnics, has rapidly become established and developed in recent years. It integrates scientific knowledge from soil mechanics, rock mechanics,ecology, biology, and atmospheric science to develop cross-disciplinary theories and carry out experiments to tackle grand world challenges such as the effects of climate change. Through the development of eco-geotechnics, various eco-friendly technologies have been developed to mitigate sandstorms and to improve the performance of earthen structures such as embankments, slopes and landfill covers. This state-of-the-art review introduces and discusses the important advances in the field of eco-geotechnics,covering theoretical developments, laboratory testing, centrifuge modelling, field monitoring and engineering applications.Finally, the research gaps and future needs of eco-geotechnics are highlighted and discussed.