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Table of contents
1. CHAPTER Ⅰ: Scientific Context and Objectives
1.1. Water Regime
1.1.1. Water resources worldwide
1.1.2. Water resources and consumptions in Asia
1.1.3. Water quality in Asia (especially in China and Vietnam)
1.2. Hydrologic Cycling
1.2.1. Global hydrologic cycling
1.2.2. Hydrologic cycling at a basin scale
1.3. Sediment Fluxes
1.3.1. Land degradation and soil erosion
1.3.2. Sediment export by rivers
1.4. Fluvial Organic Carbon
1.4.1. Sources of organic carbon
1.4.2. Dissolved and particulate organic carbon exports by rivers
1.4.3. Influence factors
1.5. General Approaches and Tools
1.6. Objectives of this Study
2. CHAPTER Ⅱ: Materials and Methods Global Theme of the Materials and Method
2.1. Study Area
2.1.1. General information
2.1.2. Climatic characteristics
2.1.3. Hydrological characteristics and water resources
2.1.4. Land use and cover
2.1.5. Basin social economy and human activities
2.2. Dataset
2.2.1. Discharge and suspended sediment concentration dataset
2.2.2. Dissolved and particulate organic carbon dataset
2.3. General Introduction of the Modelling Approach
2.3.1. SWAT general introduction
2.3.2. SWAT application
2.3.3. Hydrological modelling component in SWAT
2.3.4. Sediment modelling component in SWAT
2.4. Modelling Setup for Hydrology and Suspended Sediment
2.4.1. Modelling inputs for SWAT
2.4.2. Dam implemented in SWAT
2.5. Fluvial Organic Carbon Computation
2.5.1. Dissolved organic carbon
2.5.2. Particulate organic carbon
2.6. Calibration processes
2.6.1. Discharge and Suspended Sediment Concentration calibration
2.6.2. Dissolved and particulate organic carbon parameters calibration
2.7. Simulation Performance
2.7.1. The coefficient of determination (R2)
2.7.2. The Nash–Sutcliffe efficiency (NSE)
2.7.3. The Percent bias (PBIAS)
2.7.4. Dissolved and particulate organic carbon validation
2.8. Scenarios and Output analysis
2.8.1. Scenarios implementations by SWAT
2.8.2. Identification of the influencing factors for soil erosion
2.8.3. Scenarios outputs for dissolved and particulate organic carbon
2.8.4. Analysis of the relationships between the parameters for calculating the dissolved and particulate organic carbon and the physical characteristic of each sub-basin
3. CHAPTER Ⅲ: Modelling Discharge and Suspended Sediment Concentration
3.1. Scientific Context and Objectives
3.2. Materials and Methods
3.3. Main Results and Discussions
3.4. Conclusion and Perspectives
3.5. Full Article Published in Water
4. CHAPTER Ⅳ: Assessing the Sediment Fluxes and Soil Erosion
4.1. Scientific Context and Objectives
4.2. Materials and Methods
4.3. Main Results and Discussions
4.4. Conclusion and Perspectives
4.5. Full Article Submitted to Hydrological Processes
5. CHAPTER Ⅴ: Assessing Fluvial Organic Carbon Concentration and Fluxes
5.1. Scientific Context and Objectives
5.2. Materials and Methods
5.3. Main Results and Discussions
5.4. Conclusion and Perspectives
5.5. Full Article
6. CHAPTER Ⅵ: General Discussion
6.1. Water Regime
6.1.1. Hydrological cycle and water yield
6.1.2. Impacts of dams on discharge
6.1.3. Impacts of climate variability on discharge
6.2. Suspended Sediment
6.2.1. Sediment export
6.2.2. Soil erosion
6.2.3. Impacts of climate variability on suspended sediment
6.2.4. Impacts of dams on suspended sediment
6.3. Organic Carbon
6.3.1. Dissolved organic carbon export
6.3.2. Particulate organic carbon export
6.3.3. Total organic carbon export and evolution
7. CHAPTER Ⅶ: Conclusions and Perspectives
7.1. General Conclusions
7.1.1. Water regime
7.1.2. Suspended sediment
7.1.3. Organic carbon
7.1.4. Simple relationships proposed from this study
7.2. Perspectives
Conclusions Générales et Perspectives
