Change Characteristics of Hydrometeorological Elements in the Yarkand River Basin and Their Correlations with Hydroelectric Power Generation

doi:10.11988/ckyyb.20231085

Abstract

Abstract:

This study aims to analyze the trends and abrupt changes in hydrometeorological variables in the Yarkand River basin and their correlations with hydroelectric power generation. Various analytical methods, including the Mann-Kendall trend test and the Maximum Mutual Information Coefficient, were employed to investigate these aspects over the period from 1960 to 2017. Findings indicated that precipitation, temperature, and runoff exhibited significant increasing trends during this period, whereas evapotranspiration and wind speed showed notable decreases. Specifically, the upward trends in precipitation and runoff were more pronounced during the flood period, with rates of 0.49 mm/year and 0.86 mm/year, respectively, approximately 4.1 and 2.4 times those of the dry period. Seasonal analysis revealed significant upward trends in temperature and runoff across all seasons. Notably, significant increases in evapotranspiration were primarily observed during summer and autumn. Except from wind speed,abrupt changes in these hydrometeorological elements were detected around the 1990s, with multiple shift points observed in precipitation data. Hydropower generation was found to be directly linked to runoff, which is influenced by factors such as snowpack, air temperature, and soil temperature. As temperature rises, snow and ice melt accelerates, leading to increased runoff and consequently higher hydropower generation capacities.

Key words: Yarkand River Basin, trend analysis, maximum mutual information coefficient, climate change, hydroelectric power generation

CLC Number:

TV11

Cite this article

LIANG Shu-chao, ZHAI Bao-yu, LI Guo-qing, XU Zhi, LI Zi-an, ZHAO Yu, PENG Wang. Change Characteristics of Hydrometeorological Elements in the Yarkand River Basin and Their Correlations with Hydroelectric Power Generation[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(2): 23-28.

share this article

0
/ Save 0 / Recommend

Add to citation manager EndNote|Ris|BibTeX

URL: http://ckyyb.crsri.cn/EN/10.11988/ckyyb.20231085

http://ckyyb.crsri.cn/EN/Y2025/V42/I2/23

Figures/Tables 9

Fig.1 Geographical location of the Yarkand River Basin

Table 1 Research data and their sources

数据名称	数据类型	数据用途	时段
长历史气象数据	流域长历史降水、气温、蒸散发和温度	演变规律分析	1960— 2017年	中国气象局
CNRD 数据集	径流深	演变规律分析	1960— 2017年	国家青藏高原数据科学中心
ERA5- Land	多要素气象数据	研究水力发电量关联度	2021年7月— 2022年11月	欧洲中期天气预报中心
实测径流	坝址处径流量	研究水力发电量关联度	2021年7月— 2022年11月	实际观测

Table 1 Research data and their sources

数据名称	数据类型	数据用途	时段
长历史气象数据	流域长历史降水、气温、蒸散发和温度	演变规律分析	1960— 2017年	中国气象局
CNRD 数据集	径流深	演变规律分析	1960— 2017年	国家青藏高原数据科学中心
ERA5- Land	多要素气象数据	研究水力发电量关联度	2021年7月— 2022年11月	欧洲中期天气预报中心
实测径流	坝址处径流量	研究水力发电量关联度	2021年7月— 2022年11月	实际观测

Table 2 Details of ERA5-Land hydrometeorological elements

变量	意义	单位	变量	意义	单位
t2m	温度	K	stl1	1层土壤(0~7 cm) 温度	℃
tp	降水量	m	stl2	2层土壤(7~28 cm) 温度	℃
evp	蒸散发	m	swvl1	1层土壤(0~7 cm) 含水量	m³/m³
u10	水平风速	m/s	swvl2	2层土壤(7~28 cm) 含水量	m³/m³
v10	垂直风速	m/s	sd	积雪深度	m
sde	雪水当量	m

Table 2 Details of ERA5-Land hydrometeorological elements

变量	意义	单位	变量	意义	单位
t2m	温度	K	stl1	1层土壤(0~7 cm) 温度	℃
tp	降水量	m	stl2	2层土壤(7~28 cm) 温度	℃
evp	蒸散发	m	swvl1	1层土壤(0~7 cm) 含水量	m³/m³
u10	水平风速	m/s	swvl2	2层土壤(7~28 cm) 含水量	m³/m³
v10	垂直风速	m/s	sd	积雪深度	m
sde	雪水当量	m

Fig.2 Change trends of hydrometeorological elements in the Yarkand River Basin

Table 3 Variation trend at Maigaiti meteorological station

水文气象要素	时段	M-K slope	Sens slope	线性回归斜率	显著性	趋势
降水量	春	-1.01	-0.02	-0.06	p=0.66	下降
	夏	6.33	0.35	0.37	0.01<p<0.05	上升
	秋	4.91	0.06	0.14	0.01<p<0.05	上升
	冬	9.98	0.01	0.12	p<0.01	上升
	洪水期	5.66	0.44	0.49	0.01<p<0.05	上升
	枯水期	3.92	0.08	0.12	p=0.43	上升
气温	春	12.42	0.03	0.03	p<0.01	上升
	夏	5.89	0.01	0.01	0.01<p<0.05	上升
	秋	13.5	0.03	0.02	p<0.01	上升
	冬	9.11	0.03	0.03	0.01<p<0.05	上升
	洪水期	9.16	0.01	0.01	p<0.001	上升
	枯水期	11.89	0.03	0.03	0.01<p<0.05	上升
蒸散发	春	-5.38	-2.55	-1.61	p=0.12	下降
	夏	-7.71	-7.55	-5.36	0.01<p<0.05	下降
	秋	-5.31	-1.63	-1.17	0.01<p<0.05	下降
	冬	-1.74	-0.21	-0.12	p=0.48	下降
	洪水期	-7.44	-11.02	-7.53	0.01<p<0.05	下降
	枯水期	-2.45	-0.34	-0.19	p=0.51	下降
风速	春	-16.9	-0.01	-0.02	p<0.001	下降
	夏	-14.6	-0.02	-0.02	p<0.001	下降
	秋	-10.2	-0.07	-0.07	p<0.001	下降
	冬	-9.2	-0.02	-0.02	p<0.001	下降
	洪水期	-11.1	-0.21	-0.19	p<0.001	下降
	枯水期	-10.4	-0.70	-0.08	p<0.001	下降
径流	春	6.86	0.22	0.31	0.01<p<0.05	上升
	夏	7.41	0.43	0.42	0.01<p<0.05	上升
	秋	9.65	0.51	0.61	p<0.001	上升
	冬	10.50	0.09	0.09	p<0.001	上升
	洪水期	9.51	0.81	0.86	p<0.001	上升
	枯水期	9.01	0.32	0.35	0.01<p<0.05	上升

Table 3 Variation trend at Maigaiti meteorological station

水文气象要素	时段	M-K slope	Sens slope	线性回归斜率	显著性	趋势
降水量	春	-1.01	-0.02	-0.06	p=0.66	下降
	夏	6.33	0.35	0.37	0.01<p<0.05	上升
	秋	4.91	0.06	0.14	0.01<p<0.05	上升
	冬	9.98	0.01	0.12	p<0.01	上升
	洪水期	5.66	0.44	0.49	0.01<p<0.05	上升
	枯水期	3.92	0.08	0.12	p=0.43	上升
气温	春	12.42	0.03	0.03	p<0.01	上升
	夏	5.89	0.01	0.01	0.01<p<0.05	上升
	秋	13.5	0.03	0.02	p<0.01	上升
	冬	9.11	0.03	0.03	0.01<p<0.05	上升
	洪水期	9.16	0.01	0.01	p<0.001	上升
	枯水期	11.89	0.03	0.03	0.01<p<0.05	上升
蒸散发	春	-5.38	-2.55	-1.61	p=0.12	下降
	夏	-7.71	-7.55	-5.36	0.01<p<0.05	下降
	秋	-5.31	-1.63	-1.17	0.01<p<0.05	下降
	冬	-1.74	-0.21	-0.12	p=0.48	下降
	洪水期	-7.44	-11.02	-7.53	0.01<p<0.05	下降
	枯水期	-2.45	-0.34	-0.19	p=0.51	下降
风速	春	-16.9	-0.01	-0.02	p<0.001	下降
	夏	-14.6	-0.02	-0.02	p<0.001	下降
	秋	-10.2	-0.07	-0.07	p<0.001	下降
	冬	-9.2	-0.02	-0.02	p<0.001	下降
	洪水期	-11.1	-0.21	-0.19	p<0.001	下降
	枯水期	-10.4	-0.70	-0.08	p<0.001	下降
径流	春	6.86	0.22	0.31	0.01<p<0.05	上升
	夏	7.41	0.43	0.42	0.01<p<0.05	上升
	秋	9.65	0.51	0.61	p<0.001	上升
	冬	10.50	0.09	0.09	p<0.001	上升
	洪水期	9.51	0.81	0.86	p<0.001	上升
	枯水期	9.01	0.32	0.35	0.01<p<0.05	上升

Fig.3 Mann-Kendall test results of different hydrometeorological elements

Fig.4 Cumulative anomalies of different hydromete-orological elements

Fig.5 Maximum mutual information coefficient between runoff and hydrometeorological elements in different time periods

Fig.6 Maximum mutual information coefficient between hydropower generation and different hydrometeorological elements

Related Articles 15

[1]	XING Zhi-yun, LIU Hui-ying, LI Jia-wei. Variation Characteristics and Influencing Factors of Water and Sediment in Yangxin River Basin [J]. Journal of Changjiang River Scientific Research Institute, 2024, 41(5): 18-25.
[2]	WU Qi-liang, ZHENG Hang , LIU Yue-yi, CHEN Jin. Simulation of Landscape Ecological Risk Change in Hanjiang River Basin under SSP-RCP Scenarios [J]. Journal of Changjiang River Scientific Research Institute, 2024, 41(4): 78-88.
[3]	ZHOU Li-ming, ZHANG Yang. Thickness of Glacier and Frozen Soil in the Source Region of Changjiang River Based on GPR Detection [J]. Journal of Changjiang River Scientific Research Institute, 2024, 41(3): 1-8.
[4]	FAN Di, ZENG Si-dong, LIU Xin, YANG Lin-han, XIA Jun. Impacts of Climate Change on Hydrological Processes in Water Source Areas of the Planning Western Route of South-to-North Water Diversion Project Based on CMIP6 [J]. Journal of Changjiang River Scientific Research Institute, 2024, 41(3): 194-202.
[5]	ZHANG Xiao-ying, HE Yi, WENG Xue-xian, SHAO Yi-ting. Attribution Analysis of Runoff Variation in Duhe River Basin in the Qinling-Daba Mountains [J]. Journal of Changjiang River Scientific Research Institute, 2024, 41(2): 44-51.
[6]	LONG Yuan-nan, TANG Ying, YANG Jia-liang, MO Jun-cheng, SONG Xin-yi. Characteristics and Driving Factors of Water Level Variation in Dongting Lake During Flood Season [J]. Journal of Changjiang River Scientific Research Institute, 2024, 41(12): 15-22.
[7]	YAO Shi-ming, FAN Da-fu, LUAN Hua-long, QU Geng, HU Cheng-wei, HE Zi-can. Recent Extreme Flood and Drought Hydrological Situation in Poyang Lake and Countermeasures [J]. Journal of Changjiang River Scientific Research Institute, 2024, 41(12): 171-179.
[8]	JIANG Si-yu, ZHOU Shuai, WU Hui-ming. Influence of Multiple Uncertainties on Watershed Hydrological Simulation under Climate Change [J]. Journal of Changjiang River Scientific Research Institute, 2024, 41(11): 7-14.
[9]	LI Jing-gang, CHEN Xiao-nan, QIAO Yu, LI Tian-yi. Winter Temperature Variations in the Section of South-to-North Water Diversion Middle Route Project North of Anyang River in the Past 41 Years [J]. Journal of Changjiang River Scientific Research Institute, 2024, 41(10): 165-174.
[10]	QI Chang-xian, REN Yan, PENG Hai-yue, WEI Jia-hua, WANG Yong-qiang, LI Qiong. Extracting the Dynamic Change of Lake Area in the Three-River Headwaters Region Based on Google Earth Engine [J]. Journal of Changjiang River Scientific Research Institute, 2023, 40(7): 179-185.
[11]	ZHENG Ting-ting, CAI Hong, LIU Jia-wei. Effects of Land Use and Climate Change on Spatial Distribution of Hydrological Factors in Tongzi River Basin [J]. Journal of Changjiang River Scientific Research Institute, 2023, 40(5): 44-50.
[12]	SONG Hui-ling, CHEN Shu, AO Yuan-hong. Changing Characteristics of Blue and Green Water Resources in Hanjiang River Basin and Their Main Influencing Factors [J]. Journal of Changjiang River Scientific Research Institute, 2023, 40(4): 24-30.
[13]	HUANG Shuang-qing, TANG Chao-li, HUANG You-rui. Spatial and Temporal Distribution and Variation Trend of Available Precipitation in China [J]. Journal of Changjiang River Scientific Research Institute, 2023, 40(4): 37-43.
[14]	XIAO Xiao, QIU Xin-fa, XU Jin-qin. Characteristics of Dry and Wet Climate Change in China from 1960 to 2019 Based on TerraClimate Dataset [J]. Journal of Changjiang River Scientific Research Institute, 2023, 40(2): 27-33.
[15]	ZHOU Si-ru, XIN Zhong-bao. Spatial and Temporal Characteristics of Water Resources in Qinghai-Tibet Plateau in Recent Two Decades [J]. Journal of Changjiang River Scientific Research Institute, 2022, 39(6): 31-39.

Metrics

Viewed

Full text

115

HTML			PDF

Just accepted	Online first	Issue	Just accepted	Online first	Issue
0	0	12	0	0	103

From	Others	local

Times	54	61
Rate	47%	53%

Abstract

Just accepted	Online first	Issue

0	0	85

From	Others	local

Times	49	37
Rate	57%	43%

Comments

Abstract
Figures/Tables
Related Articles
Recommended Articles
Metrics
Comments

TOP