Evaluation of River System Connectivity on Scales of Water Resource Zones in China

doi:10.11988/ckyyb.20240687

Abstract

Abstract:

River system connectivity (RSC) is closely related with water security issues, including water resources allocation, flood and drought management, and the protection and restoration of aquatic ecosystems. Currently, there is a lack of comprehensive studies evaluating RSC at a national level, and few comparisons were conducted among different water resource zones. To address this gap, an RSC evaluation system is established by employing hierarchical analysis and the entropy weight method. The evaluation indices reflect the quantitative, structural, and hydraulic characteristics in line with the fundamental connotation of RSC. The spatial distribution map of RSC values on different scales (first-grade and third-grade national water resource zoning) is plotted. Results indicate that RSC values decline progressively from southeastern to northwestern China, categorizing into low (0.07-0.38), medium (0.39-0.50), and high (0.51-0.78) levels. Low RSC values primarily occur in the arid inland areas of northwest China, while medium values are found in hilly regions, and high values are concentrated in the plain river networks of the middle and lower reaches of the Yangtze and Huaihe River basins. This study contributes to enhancing RSC planning and development at both regional and catchment scales.

Key words: river system connectivity, evaluation system of river system connectivity, scales of water resource zones, China, hydraulic characteristics

CLC Number:

P343

XU Zhi-cheng, TANG Xian-qi, WANG Min, LIU Shang-wu, DING Bing, YAN Xia, CHAI Zhao-hui. Evaluation of River System Connectivity on Scales of Water Resource Zones in China[J]. Journal of Yangtze River Scientific Research Institute, 2024, 41(10): 40-47.

Figures/Tables 7

Fig.1 Generalized river system structure

Table 1 Evaluation system of river system connectivity

目标层	特征层	指标层	指标计算公式	含义
水系连通性	数量特征	水系密度N_r/ (km·km^-2)	$N r = R / A$	单位面积上河流的总长度
	数量特征	水面率N_w/%	$N w = W / A$	多年平均水位下的水域面积占区域总面积的比例
	结构特征	连通环度C_r	$C r = n r - v + 1 2 v - 5$	水网实际连通环路数与最大可能连通环路数之比
	结构特征	节点连接率C_c	$C c = n r v$	区域内河段数与节点数之比
	水力特征	平均水力坡度F_p/%	$F p = 1 m r ∑ i = 1 m r h i / R i$	单位河长平均水力坡度
	水力特征	调蓄库容F_s/ (m³·km^-2)	$F s = S / A$	单位面积水库调蓄库容

Table 1 Evaluation system of river system connectivity

目标层	特征层	指标层	指标计算公式	含义
水系连通性	数量特征	水系密度N_r/ (km·km^-2)	$N r = R / A$	单位面积上河流的总长度
	数量特征	水面率N_w/%	$N w = W / A$	多年平均水位下的水域面积占区域总面积的比例
	结构特征	连通环度C_r	$C r = n r - v + 1 2 v - 5$	水网实际连通环路数与最大可能连通环路数之比
	结构特征	节点连接率C_c	$C c = n r v$	区域内河段数与节点数之比
	水力特征	平均水力坡度F_p/%	$F p = 1 m r ∑ i = 1 m r h i / R i$	单位河长平均水力坡度
	水力特征	调蓄库容F_s/ (m³·km^-2)	$F s = S / A$	单位面积水库调蓄库容

Fig.2 Map of the first-grade and third-grade water resources zoning in China

Fig.3 Spatial distribution of national river systems and their nodes, surfaces and slopes

Table 2 Statistics of RSC characteristics

特征或目标	特征值
特征或目标	极小值	下四分位数	中位数	均值	上四分位数	极大值
数量特征	0	0.26	0.36	0.41	0.52	1
结构特征	0.11	0.46	0.56	0.56	0.67	1
水力特征	0	0.12	0.27	0.31	0.48	1
连通性	0.07	0.35	0.44	0.43	0.52	0.78

Fig.4 Spatial distribution of RSC and its quantitative, structural and hydraulic characteristics in the third-grade water resources zone

Fig.5 Spatial distribution of RSC and its quantitative, structural and hydraulic characteristics in the first-grade water resources zone

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