Evolutionary Patterns of Meandering Morphology in the Middle Reach of the Mainstream Tarim River over the Past Decade

doi:10.11988/ckyyb.20231389

Abstract

Abstract:

To reveal the formation and evolutionary patterns of typical meandering river morphology in the main stream of the Tarim River, this study used remote-sensing images and overlaying techniques to summarize the types of planform changes in the river boundaries of the middle reach of Tarim River from Wusiman to Aqike over the past decade. Moreover, integrating measured cross-sections and hydrological data, river regime analysis was employed to evaluate the stability of river cross-sections at different times. The results are as follows: 1) The planform geometric evolution of the middle reach from Wusiman to Aqike can be categorized into four single patterns (positive shift, negative shift, extension, and contraction) and four combined patterns (positive shift plus extension, positive shift plus contraction, negative shift plus extension, and negative shift plus contraction). Among them, the positive shift plus extension pattern is the most prevalent in the study reach. 2) Morphological parameters, namely the offset degree and widening degree, along with their calculation methods, were proposed to depict the main types of planform evolution in river channels. Annual discharge was found to be the primary factor influencing the offset degree, followed by the annual sediment transport and bedload discharge. Flood was identified as the key factor affecting the widening degree. 3) In recent years, the hydraulic geometric relation coefficient has increased, suggesting an enhanced longitudinal stability of the riverbed. Meanwhile, the transverse stability of the riverbed has also improved along the study reach. This research offers significant reference for flood control engineering and river channel regulation of meandering rivers in the middle reach of the Tarim River.

Key words: meandering river channel, river evolution, hydraulic geometric relation, flood protection works, river regulation, Tarim River

CLC Number:

TV147.1

ZHANG Xiao-ying, LIU Qi, XIAO Yu-lei, DAI Wen-hong, LI Lin. Evolutionary Patterns of Meandering Morphology in the Middle Reach of the Mainstream Tarim River over the Past Decade[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(4): 27-35.

Figures/Tables 15

Fig.1 Spatial location of the study area

Fig.2 Main types of evolution in meandering channels

Table 1 Numbers and proportions of the eight evolution types in each segment

演变类型	每种演变类型在各段中所占的个数(比例)
演变类型	第1段 (自然段)	第2段 (村庄段)	第3段 (堤防段)	全段
正偏	12(30.0%)	18(30.5%)	11(28.9%)	41(29.9%)
负偏	—	1(1.7%)	—	1(0.7%)
延伸	14(35.0%)	5(8.5%)	3(7.9%)	22(16.1%)
缩拢	—	1(1.7%)	—	1(0.7%)
正偏+延伸	10(25.0%)	30(50.8%)	17(44.7%)	57(41.6%)
正偏+缩拢	2(5.0%)	3(5.1%)	5(13.2%)	10(7.3%)
负偏+延伸	—	1(1.7%)	2(5.3%)	3(2.2%)
负偏+缩拢	2(5.0%)	—	—	2(1.5%)
弯道个数	40	59	38	137

Fig.3 Variation of offset degree in a typical meandering channel (13#)

Fig.4 Comparative analysis of factors influencing the offset degree of meandering channel 13#

Fig.5 Variation of offset degree along the channel

Fig.6 Typical meandering channels (103# and 104#)

Fig.7 Variations of widening degree of typical meandering channels (91#,92#,93# and 94#)

Fig.8 Variations of widening degree of meandering channels 91#,92#,93#,and 94#

Fig.9 Variation of widening degree along the channel

Fig.10 Typical meandering channel 111#

Fig.11 Typical meandering channel 67#

Fig.12 Main forms of variation in river cross-sections

Fig.13 Typical meandering channels 10#,86#,and 134#

Table 2 Stability indices of hydraulic geometric relation coefficient of the study reach

段名	河相系数		纵向稳定系数		横向稳定系数
	ζ= $B H$		φ₁= $d J$		φ₂= $Q 0.5 J 0.2 B$
	2011年	2019年	2011年	2019年	2011年	2019年
第1段 (自然段)	15.33	28.31	1.22	1.28	0.43	0.28
第2段 (村庄段)	13.28	16.08	3.37	3.36	0.56	0.51
第3段 (堤防段)	12.15	15.35	3.41	2.26	0.61	0.67

Table 2 Stability indices of hydraulic geometric relation coefficient of the study reach

段名	河相系数		纵向稳定系数		横向稳定系数
	ζ= $B H$		φ₁= $d J$		φ₂= $Q 0.5 J 0.2 B$
	2011年	2019年	2011年	2019年	2011年	2019年
第1段 (自然段)	15.33	28.31	1.22	1.28	0.43	0.28
第2段 (村庄段)	13.28	16.08	3.37	3.36	0.56	0.51
第3段 (堤防段)	12.15	15.35	3.41	2.26	0.61	0.67

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[5]	YAO Shi-ming, HU Cheng-wei, QU Geng. Research Advances in River Evolution and Ecological Regulation in the Downstream of the Three Gorges Reservior [J]. Journal of Changjiang River Scientific Research Institute, 2021, 38(10): 16-26.
[6]	DONG Yao-hua. Researches and Practices on River & Sediment and River Regulation & Flood Control of the Yangtze River [J]. Journal of Changjiang River Scientific Research Institute, 2021, 38(10): 7-15.
[7]	DONG Yao-hua. Review on Flood Control and River Regulation of the Middle and Lower Yangtze River after 2016-type Flood [J]. Journal of Changjiang River Scientific Research Institute, 2020, 37(1): 1-6.
[8]	ZHOU Wei,GAO Hui-cai,WU Teng. Application of 2-D Numerical Model of Bed Load in Rivers of Mountain Area:Regulation Project in Wangmo River as An Example [J]. Journal of Changjiang River Scientific Research Institute, 2016, 33(8): 6-17.
[9]	XU Xi-rong, GUAN Jie, ZHANG Shao-jie, CHEN Hong. River Regulation and Stability Analysis for Xinjizhou Reach of the Yangtze River [J]. Journal of Changjiang River Scientific Research Institute, 2015, 32(7): 5-8.
[10]	GE Yao, CHEN Chang-ying. Research Advances in Flow Characteristics Near SubmergedRiver Regulation Structures [J]. Journal of Changjiang River Scientific Research Institute, 2015, 32(5): 66-71.
[11]	DONG Yao hua , LUO Xue. Summary on Expert Lectures of International Exchange for Changjiang River Scientific Research Institute: 2012-2014 [J]. Journal of Changjiang River Scientific Research Institute, 2015, 32(11): 141-148.
[12]	HONG Jian, LIAO Xiao-Yong. River Regulation Projects in Ma’anshan Reach of Lower Yangtze River [J]. Journal of Changjiang River Scientific Research Institute, 2012, 29(2): 1-5.
[13]	DONG Yao-hua, ZHOU Ruo, LU Jin-you. Overview on Year 2007 Open Research Fund of Key Laboratory of River Regulation and Flood Control of MWR [J]. Journal of Changjiang River Scientific Research Institute, 2012, 29(12): 121-126.
[14]	QU Geng , ZHU Yong-hui , TANG Feng , SUN Gui-zhou. Study on Flow Characteristics of Jingjiang River [J]. Journal of Changjiang River Scientific Research Institute, 2011, 28(6): 76-81.
[15]	LIU Xiao-Bin, LIN Mu-Song, LI Zhen-Qing. Channel Evolution and Regulation of Zhenjiang-Yangzhou Reach of the Lower Yangtze River [J]. Journal of Changjiang River Scientific Research Institute, 2011, 28(11): 1-9.