Responses of Bed Morphology to Vegetation Growth and Flood Discharge at a Sharp River Bend
Abstract
:1. Introduction
2. Material and Methods
2.1. Computational Conditions
2.1.1. Hydrodynamic Model
2.1.2. Vegetation Model
2.1.3. Non-Equilibrium Secondary Flow Model for Sediment Transport of Bed Load
2.1.4. Sediment Transport Model
2.1.5. Slope Failure Model
2.1.6. Hydrograph Characteristic Shape
- Flood events, with the annual maximum peak, were selected from 15 years of measurement data (see Figure 4), except for the 2015, as the hydrograph for this year shows less than half of the annual averaged maximum discharge (690 m3/s) of the other years. Thus, a total of 14 hydrographs were extracted from 15 years’ data;
- Each hydrograph was normalized using each peak discharge and then trimmed at the inflection points;
- And then, the hydrograph characteristic shape was calculated by ensemble averaging with all of 14 normalized hydrographs. Before taking ensemble averaging, the start times of all hydrographs were adjusted so that the times to peaks become the same. We also assumed that the discharge at the start and the end of the hydrograph is the total averaged discharge for 15 years. As a result, the flood duration of the hydrograph characteristic shape becomes 150 h.
2.2. Verification of Simulation
2.3. Channel Pattern Quantification
2.3.1. Braiding Index
2.3.2. Bed Relief Index
3. Results and Discussion
3.1. Local Erosion and Global Erosion
3.2. Final Channel Patterns and Distribution of Vegetation Area
3.3. Change in the ABI and BRI over Time
3.4. Bar and Thalweg Dynamics under Different Levels of Flood Discharge: First Flood Event
3.5. The Effect of Vegetation Depending on the Peak Discharge: Second and Third Flood Event
3.6. Limitation of Modelling and Suggestions
4. Conclusions
- Erosion is classified as either local erosion or global erosion. Local erosion is caused by an increase in the flow velocity near an area of vegetation. This erosion may increase the number of threads in the channel as the flood event recedes. Global erosion is caused by strong secondary flow of the first kind working to erode the entire channel as the discharge reaches its peak. While local erosion increases the ABI due to the increase in thread channels, global erosion increases the BRI due to the increase in the thalweg depth. Sometimes, it was observed that global erosion swept away thread channels, resulting in a decrease in the ABI;
- Under a small peak discharge (690 m3/s), vegetation works to accelerate local erosion because the flow velocity increases near the vegetation area, which increases the change in the ABI and BRI over time. If the peak discharge is high (1381 m3/s), the strength of the secondary flow of the first kind becomes significant, thereby activating global erosion. The vegetation effect also activates local erosion, such that the change in the BRI over time is larger than for the no-growing case for the same discharge;However, if the peak flow discharge is extreme (2762 m3/s), global erosion is dominant. The thalweg readily shifts toward the outer bank and the area of point bar with vegetation expansion. Under this scenario, the larger area of vegetation limits the scale of the secondary flow by reducing the flow velocity, which activates global erosion within the unvegetated areas such as the thalweg. As a result, the change in the BRI over time decreases compared to the no-growing vegetation case. This phenomenon should be further explored with more detailed field observation and experimental data;
- In a river, the growth of vegetation is influenced by many factors, such as the duration of daylight, frequency of flood events, temperature, and soil characteristics. Therefore, the growth stage of vegetation should be simplified to allow for a focus on the interaction between the vegetation and flow discharge. Despite the potential overestimation due to this simplification, the simulated shape of the point bar was reproduced with reasonable accuracy compared to pictures (Figure 1 and Figure 11). However, the linear estimation of vegetation growth used in this study is too monotonous to yield quantitative information for practical river training works. Therefore, to ensure more accurate quantitative predictions, further model refinement is necessary by considering a more detailed river survey data and wider variety of real hydrograph, including flood seasons and drought seasons.
Acknowledgments
Author Contributions
Conflicts of Interest
References
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Parameter | Value | Model |
---|---|---|
The von Karman constant (κ) | 0.4 | Zero Equation |
Mean diameter of bed load ( | 1.49 mm | Sediment transport |
Manning roughness coefficient () | 0.016 s/m1/3 | Sediment transport |
Critical Shields number ( | 0.0374 | Sediment transport |
The number of vegetation in unit area () | 95.34 EA | Vegetation |
Coefficient of Drag force for vegetation () | 0.7 | Vegetation |
Maximum growth stage () | 0.21 | Vegetation |
Critical erosion depth of Vegetation decay (root length) | 0.8 m | Vegetation |
Angle of repose for bed material ( | 30 | Slope failure |
No. | Peak Discharge (m3/s) | Total Flood Duration (h) | Growing Vegetation | Permanent Vegetation |
---|---|---|---|---|
Run-1 | 690 | 450 | No | Yes |
Run-2 | 1381 | 450 | No | Yes |
Run-3 | 2762 | 450 | No | Yes |
Run-4 | 690 | 450 | Yes | Yes |
Run-5 | 1381 | 450 | Yes | Yes |
Run-6 | 2762 | 450 | Yes | Yes |
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Kang, T.; Kimura, I.; Shimizu, Y. Responses of Bed Morphology to Vegetation Growth and Flood Discharge at a Sharp River Bend. Water 2018, 10, 223. https://doi.org/10.3390/w10020223
Kang T, Kimura I, Shimizu Y. Responses of Bed Morphology to Vegetation Growth and Flood Discharge at a Sharp River Bend. Water. 2018; 10(2):223. https://doi.org/10.3390/w10020223
Chicago/Turabian StyleKang, Taeun, Ichiro Kimura, and Yasuyuki Shimizu. 2018. "Responses of Bed Morphology to Vegetation Growth and Flood Discharge at a Sharp River Bend" Water 10, no. 2: 223. https://doi.org/10.3390/w10020223
APA StyleKang, T., Kimura, I., & Shimizu, Y. (2018). Responses of Bed Morphology to Vegetation Growth and Flood Discharge at a Sharp River Bend. Water, 10(2), 223. https://doi.org/10.3390/w10020223