Evolution Trend of Snow Cover and Simulation of Snowmelt Runoff in Upper Reaches of Lancang River

doi:10.11988/ckyyb.20231177

Abstract

Abstract:

Snowmelt water is a significant component of spring runoff in the Lancang River basin, making it crucial to understand the variation of snow cover in the upper reaches of the Lancang River and accurately simulate snowmelt runoff processes for the scientific scheduling of water resources for cascade hydropower stations. Using remotely sensed snow cover data from 2000 to 2019, we applied the Mann-Kendall trend test to analyze the spatio-temporal variations of snow cover in the upper Lancang River basin and established a snowmelt runoff model (SRM) to simulate the snowmelt runoff process in 2018 and calibrated the model parameters using the Particle Swarm Optimization (PSO) algorithm. Results indicate that 1) Snow cover in the upper reaches of the Lancang River exhibited insignificant upward trend in spring, autumn, and winter, but an insignificant decline in summer. The average annual snow cover for spring, summer, autumn, and winter was 0.16, 0.06, 0.13, and 0.17, respectively. 2) Snow cover increased in the southwest and north of the Lancang River source area across all seasons, but decreased in the southeast. The northwest region experienced the largest increase in winter, reaching 3% per year. 3) The SRM demonstrated good applicability in the upper Lancang River basin, with coefficient of determination values reaching 0.87 and 0.78 for the calibration and verification periods, respectively, from January to May. These findings provide valuable insights for simulating snowmelt runoff in alpine regions.

Key words: upper reaches of Lancang River, snow coverage, Mann-Kendall trend test, Snowmelt Runoff Model, trend analysis, snowmelt runoff simulation

CLC Number:

TV121.6

ZHANG Ju-jia, YANG Ming-xiang, WANG He-jia, ZHANG Li-min, LI Hong-gang, GUAN Zhen, DONG Ning-peng. Evolution Trend of Snow Cover and Simulation of Snowmelt Runoff in Upper Reaches of Lancang River[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(3): 42-49.

高程带	高程带海拔范围/m	面积/km²	面积占比/%
A	2 327~2 827	79	0.10
B	2 827~3 327	636	0.84
C	3 327~3 827	3 563	4.66
D	3 827~4 327	18 820	24.60
E	4 327~4 827	36 511	47.90
F	4 827~5 327	16 376	21.40
G	5 327~5 827	378	0.50

高程带	高程带海拔范围/m	面积/km²	面积占比/%
A	2 327~2 827	79	0.10
B	2 827~3 327	636	0.84
C	3 327~3 827	3 563	4.66
D	3 827~4 327	18 820	24.60
E	4 327~4 827	36 511	47.90
F	4 827~5 327	16 376	21.40
G	5 327~5 827	378	0.50

季节	统计量Z	平均积雪覆盖变化率/ (%·(10 a)^-1)	趋势
春季(3—5月份)	0.162 2	0.304	↑
夏季(6—8月份)	-0.162 0	-0.029	↓
秋季(9—11月份)	0.811 1	0.972	↑
冬季(12月—翌年2月份)	1.460 0	2.427	↑
年平均	1.784 4	1.815	↑*

季节	统计量Z	平均积雪覆盖变化率/ (%·(10 a)^-1)	趋势
春季(3—5月份)	0.162 2	0.304	↑
夏季(6—8月份)	-0.162 0	-0.029	↓
秋季(9—11月份)	0.811 1	0.972	↑
冬季(12月—翌年2月份)	1.460 0	2.427	↑
年平均	1.784 4	1.815	↑*

高程带	不同季节的平均积雪覆盖率/(%·(10 a)^-1)
	春季		夏季		秋季		冬季
	数值	趋势	数值	趋势	数值	趋势	数值	趋势
A	0.010	↑	0	↓	0	↓	0	↑
B	-0.010	↓	-0.001	↓	-0.002	↓	0	↑
C	-0.099	↓	-0.007	↓	-0.008	↓	4.3	↑
D	0.038	↑	-0.012	↓	-0.200	↓	0.2	↑
E	0.100	↑	-0.034	↓	0.085	↑	1.4	↑
F	0.400	↑	0.065	↑	3.130	↑	6.7	↑
G	2.630	↑	-0.600	↓	3.250	↑	5.8	↑

Evolution Trend of Snow Cover and Simulation of Snowmelt Runoff in Upper Reaches of Lancang River

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参数	物理意义	取值范围
度日因子a/ (cm·℃^-1·d^-1)	单位度日因子的积雪消融深度	(0,1]
融雪滞时T_s/h	融雪径流最大汇流时间	[1,5]
降雨滞时T_P/h	降雨径流最大汇流时间	[1,5]
融雪径流系数C_s	积雪转化成径流的比例系数	(0,1)
降雨径流系数C_r	降水转化成径流的比例系数	(0,1)
临界温度T_crit/℃	积雪融化的临界温度	[0,5]

分级	相对敏感度	敏感性	分级	相对敏感度	敏感性
Ⅰ	RS<0.05	低	Ⅲ	0.2≤RS<1	高
Ⅱ	0.05≤RS<0.2	中	Ⅳ	1≤RS	极高

参数	敏感度	敏感性	参数	敏感度	敏感性
度日因子a/ (cm·℃^-1·d^-1)	0.064	中	融雪径流系数C_s	0.064	中
融雪滞时T_s/h	0.009	低	降雨径流系数C_r	0.367	高
降雨滞时T_P/h	0.008	低	临界温度T_crit/℃	0.992	高

月份	时期	NSE	R²	PBIAS/%
3—5	率定期	0.85	0.85	2.51
3—5	验证期	0.70	0.75	-5.81
1—5	率定期	0.87	0.87	0.54
1—5	验证期	0.74	0.78	4.07

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