Analysis on the Variation of Hydro-Meteorological Variables in the Yongding River Mountain Area Driven by Multiple Factors
Abstract
:1. Introduction
2. Materials
2.1. Diagnosis Methods for the Variability of Hydrological Elements
2.2. Water Balance Model for River Basins
2.3. Traditional Runoff Restoration Method
2.4. The Transfer Matrix of Land Use Types
2.5. Slope Analysis Method
3. Study Area and Data
3.1. Study Area
3.2. Data
- (1)
- Meteorological data: the daily surface observation data (monthly precipitation, maximum/minimum temperature, relative humidity, average wind speed, sunshine) at 14 meteorological stations (Beijing, Huailai, Zhangjiakou, Zhangbei, Jining, Yuxian, Yangquan, Datong, Youyu, Wutaishan, Youyu, Wuzhai, Hequ, and Yuanping) in the study area from 1956 to 2016, as shown in Figure 1 (http://cdc.cma.gov.cn/home.do/, accessed on 5 August 2020).
- (2)
- Areal precipitation data: the areal precipitation data in the YRMA from 1956 to 2016 based on the precipitation data of the meteorological stations shown in Figure 1, obtained by the Thiessen polygon method.
- (3)
- Potential evapotranspiration data: the potential evapotranspiration at each station is calculated by the Penman–Monteith [37] formula based on the meteorological data of meteorological stations, and the averaged surface potential evapotranspiration in the study area is obtained by the Thiessen polygons method.
- (4)
- Observed runoff data: according to the Hydrological Data of Haihe River Basin of Annual Hydrological Report of China [38], the observed runoff of Cetian, Xiangshuibao, Guanting hydrological stations from 1956 to 2016 are selected.
- (5)
- Water resources exploitation and utilization data: according to the water resource communiques of Shanxi, Beijing, Hebei and evaluation of water resources (http://slt.shanxi.gov.cn/zncs/szyc/szygb/; http://slt.hebei.gov.cn/dynamic/search.jsp; http://swj.beijing.gov.cn/zwgk/szygb/, accessed on 20 October 2020) and Evaluation of water resources in Haihe River Basin [26], the exploitation and utilization data of water resources in YRMA are selected, including the total amount of water supply and consumption, the consumption of different water users and the water supply from surface and underground.
- (6)
- Land use data: the remotely sensed data of land use in the YRB in 1980 and 2015 are obtained, mainly including crop land, forest land, grassland, water area, land for industrial, construction land, as well as unused land, with the data resolution of 1 km. The land use data are based on Landsat TM/ETM remotely sensed image in 1980 and 2015, interpreted by ArcGIS platform. (https://www.resdc.cn/data.aspx?DATAID=184/, accessed on 8 November 2020).
- (7)
- Vegetation data: the monthly normalized vegetation index (NDVI) data from 1982 to 2016 are obtained. The monthly NDVI data from 1982 to 2015 is from the Global Inventor Modeling and Mapping Studies (GIMMS) NDVI data set, with a resolution of 8 km and a temporal resolution of 15 days (https://ecocast.arc.nasa.gov/data/pub/gimms/3g.v1/, accessed on 14 November 2020). The monthly NDVI values were obtained by using the maximum value composite (MVC) method [39]. The monthly NDVI data in 2016 is from the website of resources and environment science and data center, which is based on the SPOT/VEGETATION, MODIS and other satellite remotely sensed images, with a resolution of 1 km and a temporal resolution of one month (https://www.resdc.cn/DOI/doi.aspx?DOIid=50, accessed on 14 November 2020)). It could be used after unifying the resolution of GIMMS NDVI and MODIS NDVI data [40].
- (8)
- GRACE data: The GRACE data from April of 2002 to December of 2016 in the YRMA are used to study the long-term spatiotemporal changes of terrestrial water storage anomaly (TWSA) [41]. The TWSA data is released by the University of Texas with a spatial resolution of 0.25° (http://www2.csr.utexas.edu/grace/RL06_mascons.html/, accessed on 20 December 2020). Among them, 33 months of data are missing, which are interpolated by the cubic spline interpolation method [42]. According to the topographic map of the basin, the area weighted average is carried out, and the monthly average land water storage change of the basin is obtained.
4. Results and Discussion
4.1. Changes of the Annual Runoff and other Hydrological Elements
4.2. Variations of Hydro-Meteorological Relationships in the Basin
4.3. Driving Factors for the Change of Hydro-Meteorological Relationship
4.3.1. Intra-Annual Temporal Distribution of Precipitation
4.3.2. Changes of Vegetation Cover
4.3.3. Groundwater Exploitation
5. Conclusions
- (1)
- From 1956 to 2016, the annual natural runoff of the Guanting hydrological station located in the main stream, Cetian hydrological station and Xiangshuibao hydrological station located in the tributary of Yongding River mountain area all had significant decreasing trends and abrupt changes. The abrupt change points were in 1983, 1983 and 1982, respectively. Compared with the reference period, the annual average precipitation in the basins of the three hydrological stations during the variation period decreased by less than 10%, the annual average potential evapotranspiration decreased slightly, but the annual average natural runoff decreased sharply, and the relative reduction was more than 40%.
- (2)
- The variation of the hydrological elements in the Yongding River mountain area from 1956 to 2016 presented a sharp decrease in the natural runoff and change of the relationship between the hydro-meteorological variables since 1980s. With the precipitation–runoff relationship becoming weaker, the WBP-DP based on the Budyko hypothesis and storage–discharge equation cannot adapt to the significant changes of the coupled water–energy balance in the basin and cannot effectively describe the complex relationship of hydro-meteorological variables on an annual scale.
- (3)
- Compared with 1956–1982, the intra-annual temporal distribution of precipitation in the Yongding River mountain area underwent important changes during 1983–2016. In the main runoff generation period from July to August, the precipitation amount dropped significantly, the concentration of precipitation distribution decreased significantly, and the number of effective precipitation days decreased significantly. This is one of the important reasons for the decrease in the natural runoff and the change of hydrological responses.
- (4)
- From 1980 to 2015, the overall land use pattern in the Yongding River mountain area did not change much, but the NDVI had a significant increasing trend, and there was a significant negative correlation between the NDVI and the annual natural runoff. The evapotranspiration increased and the consumption of underground water storage caused by the increase in the vegetation cover was likely to be another important reason for the substantial reduction of the natural runoff since the 1980s.
- (5)
- Due to the long-term and large-scale exploitation of the groundwater in the Yongding River mountain area, the thickness of vadose zone may increase by several times or even tens of times compared with that before the 1980s. The groundwater level in the basin has drastically dropped and the land water storage has been continuously consumed. It has changed the mechanism of runoff production and the relationship between groundwater recharge and discharge, and also has a significant impact on the runoff decreasing and the adjustment of the hydro-meteorological relationship in the YRB.
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Hydrological Stations | Cetian | Xiangshuibao | Guanting | ||
---|---|---|---|---|---|
Diagnostic Process | |||||
Preliminary diagnosis | Hurst index | 0.982 | 1.000 | 0.975 | |
Overall variation | Strong | Strong | Strong | ||
Detailed diagnosis | abrupt | Slide F-test | 2010(+) | 2014(+) | 2000(+) |
Slide T-test | 1982(+) | 1983(+) | 1983(+) | ||
L-H test | 1982(0) | 1983(0) | 1983(0) | ||
Ordered clustering test | 1982(0) | 1983(0) | 1983(0) | ||
R/S test | 1982(0) | 1986(0) | 1983(0) | ||
Optimal segmentation | 1982(+) | 1983(+) | 1998(+) | ||
trend | Pearson correlation test | (+) | (+) | (+) | |
Spearman correlation test | (+) | (+) | (+) | ||
Kendall correlation test | (+) | (+) | (+) | ||
Compre -hensive diagnosis | abrupt | Abrupt change point | 1982 | 1983 | 1983 |
Comprehensive significance | 2(+) | 2(+) | 1(+) | ||
trend | Trend Comprehensive significance | decline 3(+) | decline 3(+) | decline 3(+) | |
Conclusion | The natural runoff of all hydrological stations showed significant decreasing trend and abrupt changes |
Basins | Period | P/mm | EP/mm | EP/P | R1/mm | R2/mm |
---|---|---|---|---|---|---|
Cetian Reservoir | 1956–1982 | 422.9 | 1012.8 | 2.39 | 37.8 | 25.1 |
1983–2016 | 384.6 | 988.3 | 2.57 | 22.5 | 3.7 | |
Xiangshuibao Reservoir | 1956–1982 | 427.0 | 1033.1 | 2.42 | 51.0 | 34.9 |
1983–2016 | 389.0 | 971.5 | 2.50 | 21.9 | 10.2 | |
Guanting Reservoir | 1956–1982 | 432.2 | 1004.4 | 2.32 | 43.4 | 28.5 |
1983–2016 | 395.5 | 962.9 | 2.43 | 21.2 | 6.0 |
Hydrological Station | 1956–1982 | 1983–2016 | ||||
---|---|---|---|---|---|---|
Average | Variation Coefficient | Kurtosis Coefficient | Average | Variation Coefficient | Kurtosis Coefficient | |
Cetian | 4.4 | 2.5 | 53.4 | 2.8 | 2.5 | 24.6 |
Xiangshuibao | 4.2 | 2.5 | 75.3 | 2.8 | 2.0 | 21.4 |
Guanting | 4.3 | 2.3 | 73.3 | 2.9 | 1.9 | 18.3 |
2010 | Cultivated Land | Woodland | Grassland | Water Area | Construction Land | Unused Land | Total | P2010 |
---|---|---|---|---|---|---|---|---|
1980 | ||||||||
cultivated land | 13139.1 | 2093.1 | 4160.8 | 373.1 | 1111.5 | 142.5 | 21,020.1 | 47.3% |
woodland | 822.7 | 4560.1 | 1347.2 | 39.5 | 55.3 | 16.5 | 6841.2 | 15.4% |
grassland | 4078.7 | 2378.6 | 7184.8 | 137.6 | 328.1 | 47.9 | 14,155.6 | 31.9% |
water area | 612.3 | 100.1 | 224.3 | 117.8 | 71.7 | 21.5 | 1147.6 | 2.6% |
construction land | 453.7 | 49.1 | 137.0 | 12.3 | 140.9 | 4.7 | 797.6 | 1.8% |
unused land | 303.6 | 24.6 | 44.7 | 28.7 | 17.0 | 37.0 | 455.7 | 1.0% |
total | 19,410.0 | 9205.6 | 13,098.9 | 708.9 | 1724.5 | 270.0 | 44,417.9 | 100.0% |
P1980 | 43.7% | 20.7% | 29.5% | 1.6% | 3.9% | 0.6% | 100% | - |
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Niu, K.; Hu, Q.; Wang, Y.; Yang, H.; Liang, C.; Wang, L.; Li, L.; Li, X.; Du, Y.; Li, C. Analysis on the Variation of Hydro-Meteorological Variables in the Yongding River Mountain Area Driven by Multiple Factors. Remote Sens. 2021, 13, 3199. https://doi.org/10.3390/rs13163199
Niu K, Hu Q, Wang Y, Yang H, Liang C, Wang L, Li L, Li X, Du Y, Li C. Analysis on the Variation of Hydro-Meteorological Variables in the Yongding River Mountain Area Driven by Multiple Factors. Remote Sensing. 2021; 13(16):3199. https://doi.org/10.3390/rs13163199
Chicago/Turabian StyleNiu, Kaijie, Qingfang Hu, Yintang Wang, Hanbo Yang, Chuan Liang, Leizhi Wang, Lingjie Li, Xiting Li, Yong Du, and Chengxi Li. 2021. "Analysis on the Variation of Hydro-Meteorological Variables in the Yongding River Mountain Area Driven by Multiple Factors" Remote Sensing 13, no. 16: 3199. https://doi.org/10.3390/rs13163199
APA StyleNiu, K., Hu, Q., Wang, Y., Yang, H., Liang, C., Wang, L., Li, L., Li, X., Du, Y., & Li, C. (2021). Analysis on the Variation of Hydro-Meteorological Variables in the Yongding River Mountain Area Driven by Multiple Factors. Remote Sensing, 13(16), 3199. https://doi.org/10.3390/rs13163199