Debris Flow: Mechanics, Prediction and Countermeasures (2nd Revised edition)
By: Tamotsu Takahashi (author)Hardback
1 - 2 weeks availability
This is the 2nd edition of one of the most comprehensive accounts of debris flow, describing both theoretical and applied aspects. In the first part, the fundamental mechanical characteristics are discussed, including flow characteristics, type classification, mechanics, occurrence and development, fully developed flow, and deposition processes. The second part sheds light on the application of the theories presented in computer-simulated reproductions of real disasters. Special attention is paid to debris flow controlling structures, design effectiveness and performance, soft countermeasure problems, such as the identification of debris flow prone ravines and the prediction of occurrence by means of precipitation threshold. This new edition has been wholly revised and updated, and now includes a new chapter on sediment runoff models that include debris flow processes and new sections concerning landslides. The qualitative and fundamental character of this text makes it an excellent textbook for graduate-level courses and it is recommended reading for professionals in engineering, geosciences and water resources who are working on the mechanics and countermeasures of debris flow.
The original, Japanese version of this book was awarded the 'Publishing Culture Prize' by the Japanese Society of Civil Engineers (2004). Tamotsu Takahashi is Professor Emeritus at the University of Kyoto. In addition to his academic positions, he is the Director of the Association for Disaster Prevention Research in Kyoto. Professor Takahashi began his career in flood dynamics research, and increasingly focused on debris flow and flood hazards. He has been honoured with several awards from the Japan Society of Civil Engineers and the Japan Society of Erosion Control Engineering. An earlier book entitled 'Debris Flow', by Tamotsu Takahashi, in the book series of the International Association of Hydraulic Engineering and Research, was published by Balkema Publishers, now a part of the Taylor & Francis Group.
Tamotsu Takahashi (Kyoto, 1939) graduated as a Master in Civil Engineering at Kyoto University in 1965. From 1965 to 1967, he then worked as a research assistant at the Disaster Prevention Research Institute (DPRI) of the same university and, after a year in the Civil Engineering Department as a lecturer, he returned in 1968 to the DPRI as an associate professor. With his research on flood flow dynamics in river channels, he obtained the doctoral degree in 1972. After this, he worked as a post-doctoral fellow at Lincoln College, New Zealand, where he investigated miscellaneous problems that were associated with braided rivers. Upon returning to DPRI in Japan, he put importance on the study of sediment runoff problems that were involved with debris flow and bed load on very steep slope channels. Consequently, in 1982, he was awarded a full professorship for a newly founded research section on the investigation of anti-flood hazards systems. He then added slightly more themes to his portfolio and extended his research to the water flooding and sediment problems in urban areas. From 1992 he moved to the research section on the investigation of sedimentation problems. After his retirement in 2003, he continued working on debris flow and sediment runoff problems as a professor emeritus at Kyoto University. From 1995 to 1997 he served as the director of DPRI and during this appointment, he has reorganized the entire DPRI and has thoroughly promoted the scientific investigation of the Great Hanshin Earthquake which took place in Kobe in 1995 as the director of DPRI and the head of the Japanese Group for the Study of Natural Disaster Science. He is now working for the foundation 'Association for Disaster Prevention Research' as the chief director. Professor Takahashi has authored numerous papers and held many invited keynote lectures. He also received several awards for his outstanding work from the Japan Society of Civil Engineers and from the Japan Society of Erosion Control Engineering. His successful book 'Debris Flow', published in 1991 by A.A. Balkema Publishers in the IAHR monograph series was the first systematic approach to the subject and is still frequently referred to. The original Japanese language version of this current new and extended edition was received very well and the author was awarded the Publishing Culture Prize from the Japan Society of Civil Engineers in 2004 for it. He was also awarded the Akagi Prize in 2008 for his outstanding contributions to the prevention and mitigation of debris flow disasters.
Preface Preface to the first English edition Preface to the second English edition About the author 1 What is debris flow? 1.1 Various sediment moving phenomena 1.2 Definition of debris flow 1.3 Classification and characteristics of debris flows 1.3.1 Stony-type debris flow 1.3.2 Turbulent-muddy-type debris flow 1.3.3 Viscous debris flow 1.4 The significance of the mechanical classification of debris flows 1.5 Classifications based on other view points 2 Models for mechanics of flow 2.1 Models for solids and fluid mixture as the multi-phase flow 2.2 Single-phase continuum models 2.2.1 Visco-plastic fluid model 2.2.2 Dilatant fluid model 2.3 Two-phase continuum models (mixture theory) 2.3.1 Stress equilibrium equations 2.3.2 Coulomb mixture theory (Quasi-static debris flow) 2.4 Theory for subaerial rapid granular flows 2.4.1 Particle collision stress 2.4.2 Kinetic stress 2.4.3 Skeletal stresses 2.4.4 Constitutive relations 2.4.5 Application of the theory to dry granular flow 2.4.6 Comparison with other constitutive relations for inertial range 2.5 Mechanical classification of debris flows revisited based on the theory for granular flows 2.6 The mechanism of inertial debris flows 2.6.1 The supplementary explanation of mature stony debris flow 2.6.2 Immature debris flow 2.6.3 Turbulent-muddy debris flow 2.7 Generalized theory for inertial debris flows 2.7.1 Theoretical considerations 2.7.2 Verification by experimental data 2.7.3 Approximate solutions for solids concentration and resistance to flow 2.8 Newtonian fluid model for viscous debris flow 2.8.1 Theoretical considerations 2.8.2 Verification by experiments 2.9 Equilibrium sediment discharge in inertial debris flows 3 Initiation, development and declination of debris flow 3.1 Initiation and development of debris flow due to gully bed erosion 3.1.1 The formation of incipient debris flow by the effects of surface water runoff 3.1.2 The development and decline of stony debris flow on sediment bed 3.1.3 Verification of the theory by experiments 3.2 Landslide-induced debris flow 3.2.1 Mechanism of shallow landslides induced by severe rainfall 3.2.2 Debris avalanche 3.2.3 Model for the transformation into debris flow 3.2.4 Mathematical model for the one-dimensional motion of a deformable earth block with the liquefied layer 3.2.5 Numerical simulation of earth block and debris flow motions across a three-dimensional terrain 3.3 Debris flow and flood flow induced by the collapse of a natural dam 3.3.1 Formative conditions and shapes of a natural dam 3.3.2 Life span of a natural dam 3.3.3 Failure in entire channel width and the resulting debris flow 3.3.4 Prediction of debris flow/flood flow induced by the overflow in partial width 4 Characteristics of fully-developed debris flow 4.1 Translation of debris flow surge and the shape of the snout 4.1.1 The case of stony-type debris flow 4.1.2 The case of viscous-type debris flow 4.2 Boulder accumulation at the forefront of stony debris flow 4.2.1 Various concepts for the mechanism 4.2.2 The theory of Takahashi (1980) 4.3 Ability to transport large boulders 4.4 The causes of intermittency 4.5 Debris flow around a bend 4.6 Routing of debris flow in the transferring reach 4.6.1 Kinematic wave method 4.6.2 Dynamic wave method 5 Processes and geomorphology of deposition 5.1 One-dimensional stoppage/depositing processes of stony debris flow 5.1.1 The arrival distance at the sudden change in channel slope 5.1.2 Topography of deposit formed at a sudden slope change 5.1.3 Numerical simulation of depositing process 5.2 One-dimensional depositing process of turbulent muddy debris flow 5.3 Formation of a debris flow fan 5.3.1 Description of the experimental results for stony debris flow and empirical presentations of the feature of a debris flow fan 5.3.2 Numerical simulation of fan formation process and its verification 5.3.3 Numerical simulation of fan formation by turbulent debris flow 5.4 Particle size distribution in the fan formed by stony debris flow 5.4.1 General situations found in the field and experimental data 5.4.2 Mathematical model for the particle size distributions 5.5 Erosion and deformation of a debris flow fan 5.5.1 Experiments for the process of erosion 5.5.2 Model and its verification for the fan comprised of uniform material 5.5.3 Model and its verification for the fan comprised of heterogeneous material 6 Sediment runoff models that include debris flow processes 6.1 The viewpoints for the process-based modeling of sediment runoff 6.1.1 What kinds of phenomena are considered? 6.1.2 Which of the two is to be predicted: average runoff in a period, or runoff at every moment? 6.2 A distributed sediment runoff model for a devastated mountain watershed: SERMOW 6.2.1 The constitution of SERMOW 6.2.2 Variation of grain size beneath the surface of the riverbed 6.2.3 Growth and recession of the talus 6.3 Investigation of actual situations of sediment runoff phenomena in the Takase dam basin 6.3.1 Characteristics of the Takase dam basin 6.3.2 Erosion of bare-land slope and riverbed variation in a medium time span analyzed by digital photogrammetry 6.3.3 Measurements of bare-land erosion in the Takase River basin 6.4 Application of SERMOW to the Takase dam basin 6.4.1 Modeling of the watershed 6.4.2 Implementation of the first calculation 6.4.3 Improvement of the model by the second calculation 6.5 SERMOW ver.2 6.5.1 The constitution of SERMOW ver.2 6.5.2 Application of SERMOW ver.2 model to the Nigorisawa-Fudosawa watershed 7 Debris flow disasters and their reproduction by computer simulations 7.1 The rainstorm disasters at Okuetsu 7.1.1 Outline of the disasters 7.1.2 The natural dam formation and the damage done by backwater 7.1.3 Processes of destruction of the natural dam and the damage downstream 7.2 Horadani debris flow disasters 7.2.1 Outline of the disaster 7.2.2 Hydrograph estimation of the debris flow 7.2.3 Reproduction of debris flow depositing area on the fan 7.3 Collapse of the tailing dams at Stava, northern Italy 7.3.1 Outline of the disasters 7.3.2 Reproduction of the debris flow in the Stava River and its verification 7.4 Disasters caused by the eruption of the Nevado del Ruiz volcano 7.4.1 Outline of the disasters 7.4.2 Reproduction of the phenomena 7.5 Sediment disasters in Venezuela 7.5.1 Outline of the disasters 7.5.2 Reproduction of debris flow hydrograph and others in the Camuri Grande River 7.5.3 Reproduction of sediment flooding on the Camuri Grande fan 7.6 Debris flow disasters at Atsumari, Hougawachi of Minamata City 7.6.1 Outline of the disasters 7.6.2 Reproduction of the processes of debris flow 8 Countermeasures for debris flow disasters 8.1 Methods to prevent debris flow generation 8.1.1 Hillside works 8.1.2 Drainage works 8.1.3 Groundsill and bed girdle 8.2 Debris flow control by closed-type check dam 8.2.1 Sediment depositing process behind check (sabo) dam 8.2.2 Erosion process of the deposit behind the sabo dam 8.2.3 Effects of sediment control by sabo dam on downstream 8.3 Debris flow control by open-type sabo dams 8.3.1 Kinds and sediment checking mechanisms of open-type sabo dams 8.3.2 Blocking model of grid-type dam 8.3.3 Model for debris flow controlling by a grid-type sabo dam 8.3.4 Determination of the optimum spacing and the optimum position to install 8.4 Making debris flow harmless by channel works and training walls 8.4.1 Design of countermeasures on the fan of the Camuri Grande River 8.4.2 Management of debris flow by a training dike 8.5 Design debris flows for the countermeasure planning 8.5.1 Method based on the previous data 8.5.2 Prediction of total sediment runoff by field investigation 8.5.3 Theoretical prediction of debris flow scale 8.6 Debris flow prone ravines and hazardous area 8.6.1 Debris flow prone ravine 8.6.2 Hazardous zone by debris flow 8.7 Prediction of debris flow occurrence by rainfall References Notations Index
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- ID: 9781138000070
2nd Revised edition
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