渭河与泾河流域水沙变化规律及其差异性分析

doi:10.12118/j.issn.1000–6060.2021.02.04

Abstract

Abstract:

Based on hydrological data, water conservancy and conservation statistical data, annual average temperatures, and Landsat surface reflectance data from 1956 to 2016 in the Wei (upper Xianyang Hydrological Station on the main stream of the Wei River) and Jing (upper Zhangjiashan Hydrological Station) River Basins, northwest China, historical changes in the hydrological elements, temperature, and vegetation in the basins were analyzed. Mathematical statistical methods, such as double cumulative values, correlation curve method, cumulative anomaly method, ordered clustering method, Lee-Heghinan method, and rank sum test method, were used to determine the abrupt year of annual runoff and annual sediment load and the effect of precipitation and human activities on runoff and sediment reduction. The results show that (1) precipitation, runoff, sediment load, and sediment concentration in the Wei and Jing River Basins decreased significantly from 1956 to 2016. Specifically, annual precipitation in the Wei and Jing River Basins decreased by 1.41 mm·a^-1and 0.85 mm·a^-1, annual runoff decreased by 0.711×10⁸ m³·a^-1 and 0.217×10⁸ m³·a^-1, annual sediment load decreased by 0.037 t·a^-1 and 0.042×10⁸ t·a^-1, and annual average sediment concentration decreased by 0. 586 kg·m^-3·a^-1 and 0. 905 kg·m^-3·a^-1, respectively precipitation and runoff in the Wei River Basin was reduced about 2 to 3 times more than the Jing River Basin, and sediment load was reduced in the Jing River Basin was reduced by 1.1 to 1.5 times more than the Wei River Basin. (2) The measured annual runoff at Xianyang Station on the Wei River decreased from 60.16×10⁸ m³ in the baseline period (1956—1970) to 38.67×10⁸ m³ (1971—1994) and 22.38×10⁸ m³ (1995—2016). Additionally, during the two latter time periods, the runoff reduction effects due to human activity was 74.7% and 67.1%, respectively, and the runoff reduction effects of precipitation were 25.3% and 32.9%, respectively. The annual sediment load at Xianyang Station decreased from 1.937×10⁸ t in the baseline period (1956—1973) to 0.865×10⁸ t (1974—1994) and 0.233×10⁸ t (1995—2016). The sediment reduction effects due to human activity in the two study periods were 71.7% and 64.4%, respectively, and the sediment reduction effects due to precipitation were 28.3% and 35.6%, respectively. The measured annual runoff and the annual sediment load of the Zhangjiashan Station on the Jing River decreased from 17.43×10⁸ m³ and 2.556×10⁸ t in the baseline period (1956—1997) to 10.36×10⁸ m³ and 0.975×10⁸ t in the treatment period (1998—2016). The impact of human activity on runoff and sediment reduction was 94.2% and 72.6%, respectively, and the impact of precipitation on runoff and sediment reduction was 5.8% and 27.4%, respectively. (3) The runoff and sediment characteristics of the two river basins were quite different. The annual runoff, annual runoff depth, and runoff coefficient of the Wei River Basin were 2.0 to 2.4 times higher than those of the Jing River Basin. The annual sediment load, annual sediment transport modulus, and annual average sediment concentration in the Wei River Basin was only 1/2-1/5 of that in the Jing River Basin. The main reasons for these large differences in runoff and sediment characteristics between these two adjacent river basins are attributed to differences in climatic conditions (temperature and precipitation) between the river basins, and differences in vegetation coverage, and human activity such as soil and water conservation measures undertaken. The analysis of the differences in runoff and sediment between Wei and Jing River Basins clarifies the explanation people mistakenly believe that the phenomenon of a “distinct Jing and Wei” is because “Wei water is more turbid than Jing water”.

Key words: runoff, sediment, the reduction effect of runoff and sediment, Wei River Basin, Jing River Basin

HUANG Chenlu,YANG Qinke. Runoff and sediment variation rules and differences in Wei River and Jing River Basins[J].Arid Land Geography, 2021, 44(2): 327-336.

Figures/Tables 10

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References 18

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站名	水文要素	双累积曲线法	累积距平法					有序聚类法
			T(α/2)=1.64					T(α/2)=1.64
			统计量\|T\|	是否显著	突变点			统计量\|T\|		是否显著	突变点
渭河咸阳水文站	年径流量	1970、1994年	5.14	显著	1986年			5.43		显著	1985年
渭河咸阳水文站	年输沙量	1973、1994年	6.42	显著	1982年			7.07		显著	1973年
泾河张家山水文站	年径流量	1997年	4.86	显著	1991年			5.05		显著	1996年
泾河张家山水文站	年输沙量	1997年	4.21	显著	1997年			4.21		显著	1997年
站名	水文要素	Lee-Heghinan法				秩和检验法					最终选用突变点
		T(α/2)=1.64				U(α/2)=1.96
		统计量\|T\|	是否显著	突变点		统计量\|U\|	是否显著		突变点
渭河咸阳水文站	年径流量	5.41	显著	1970年		5.21	显著		1994年		1970、1994年
渭河咸阳水文站	年输沙量	7.07	显著	1973年		6.12	显著		1993年		1973、1994年
泾河张家山水文站	年径流量	5.08	显著	1996年		5.21	显著		1997年		1997年
泾河张家山水文站	年输沙量	4.21	显著	1997年		4.84	显著		2004年		1997年

站名	年径流量
站名	时段		实测值 /10⁸ m³	天然值 /10⁸ m³	实测值减少量/10⁸ m³	人类活动影响减少量/10⁸ m³	人类活动的减水效应/%	降水的减水效应/%
渭河咸阳水文站	基准期	1956—1970年	60.160	-	-	-	-	-
	措施期	1971—1994年	38.670	54.715	-21.490	-16.045	74.7	25.3
	措施期	1995—2016年	22.376	47.741	-37.784	-25.365	67.1	32.9
泾河张家山水文站	基准期	1956—1997年	17.427	-	-	-	-	-
泾河张家山水文站	措施期	1998—2016年	10.355	17.016	-7.072	-6.661	94.2	5.8
站名	年输沙量
站名	时段		实测值 /10⁸ t	天然值 /10⁸ t	实测值减少量/10⁸ t	人类活动影响减少量/10⁸ t	人类活动的减沙效应/%	降水的减沙效应/%
渭河咸阳水文站	基准期	1956—1973年	1.937	-	-	-	-	-
	措施期	1974—1994年	0.865	1.634	-1.072	-0.769	71.7	28.3
	措施期	1995—2016年	0.233	1.330	-1.704	-1.097	64.4	35.6
泾河张家山水文站	基准期	1956—1997年	2.556	-	-	-	-	-
泾河张家山水文站	措施期	1998—2016年	0.975	2.123	-1.581	-1.148	72.6	27.4

流域	地理特征						气候特征
流域	集水面积/km²	河长/km	海拔高程/m		植被覆盖率/%		气温/℃		年降水量/mm
渭河咸阳以上	46827	606.9	363~3495		70.62		9.4		609.2
泾河张家山以上	43216	397.1	363~2540		51.31		8.6		531.6
渭河/泾河	1.1	1.5	1.4		1.4		1.1		1.1
流域	径流特征				泥沙特征
流域	年径流量/10⁸m³	年径流深/mm		径流系数	年输沙量/10⁸t	年输沙模数/t·km^-2		年均沙量 /kg·m^-3
渭河咸阳以上	38.078	81.3		0.133	0.953	2035		25.0
泾河张家山以上	15.659	36.2		0.068	2.064	4776		132.0
渭河/泾河	2.4	2.2		2.0	0.5	0.4		0.2

Runoff and sediment variation rules and differences in Wei River and Jing River Basins

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