Analysis on influencing factors of runoff evolution in typical watershed of the upper Huaihe River: Illustrated by the case of the Bailianya basin
YANG Chuanqing1, CHEN Hang1, GU Zheyan1, WANG Wei2, JU Jing1, CHEN Lidong1, ZHU Huagang1
1. Jiangsu Surveying and Design Institute of Water Resources Co. Ltd., 225127, Yangzhou, Jiangsu, China; 2. Nanjing Hydraulic Research Institute, 210029, Nanjing, China
Abstract:[Background] For last 30 years, the global temperature rose with the influence of the precipitation spatial distribution pattern. Economic and social development, the spatial and temporal of the runoff varied significantly, and its evolution also showed a strong randomness at the same time. The Bailianya river basin is located in Dabie mountain, which is the watershed between Yangtze River basin and Huaihe River basin. The study on the characteristics of runoff change in the Bailianya river basin and its relationship with environmental factors may provide decision-making basis for regional flood control and disaster reduction, industrial and agricultural production and rational utilization of soil and water resources.[Methods] The variation characteristics of the runoff of Bailianya basin and its correlation with major environmental factors from 1970 to 2009 was detected through the Mann-Kendall test, Yamamoto method of signal-to-noise ratio and the cross wavelet transform analysis. The relationship between time series of environmental factors and runoff in different frequency domain was revealed using cross wavelet analysis. The response of runoff to the change of underlying surface elements was also clarified based on the analysis of remote sensing images in 3 stages. The coupled oscillations of runoff time series, precipitation and air temperature in Bailianya river basin were investigated from the frequency domain, which reflected the correlation between runoff and climatic factors on different time scales.[Results] 1) The distribution of runoff was uneven during the year and mainly concentrated in June and July. The 2 abrupt changes of runoff occurred in 1983 and 2004-2005. Runoff demonstrated a small cycle of 0.5-3 year(s). 2) There was strong correlation between runoff and precipitation at a cycle of 1-2 year(s) in 1986-1996 and at a cycle of 2.5-4 year(s) in 1998-2002. Runoff responded to precipitation fast with most high energy time-frequency domain characterized by phase relationship. 3) Interactions between the runoff and the temperature were mainly concentrated in a cycle of 1-3.8 year(s) in 1988-2000. The phase of temperature was prior to that of the runoff. Runoff responded to temperature with a time lag. The change of underlying surface elements strongly changed the nature of the surface of the basin, and had certain influence on the hydrological cycle at different time and space scales, causing the change of runoff and confluence conditions in the basin, and thus changing the hydrological process of the basin. Forest and farmland were the main underlying factors that caused runoff change in Bailianya basin, and had obvious influence on runoff change. With the increase of forest area and the decrease of farmland area, runoff showed a decreasing trend.[Conclusions] With the change of climate variation and underlying surface condition, the runoff of Bailianya river basin varies significantly in the interannual period and within a year, showing different correlation characteristics with different environmental factors. Precipitation in Bailianya river basin is the direct factor of the runoff change. The response of the runoff to air temperature is of time delay. Compared with forest, farmland is weak in rainfall interception and infiltration, and the conversion of farmland to forest will lead to the relative reduction of runoff.
杨传清, 陈杭, 顾哲衍, 王蔚, 鞠靖, 陈立冬, 朱华刚. 淮河上游典型流域径流演变过程影响因素分析——以白莲崖流域为例[J]. 中国水土保持科学, 2020, 18(1): 110-116.
YANG Chuanqing, CHEN Hang, GU Zheyan, WANG Wei, JU Jing, CHEN Lidong, ZHU Huagang. Analysis on influencing factors of runoff evolution in typical watershed of the upper Huaihe River: Illustrated by the case of the Bailianya basin. SSWC, 2020, 18(1): 110-116.
姚治君,管彦平,高迎春. 潮白河径流分布规律及人类活动对径流的影响分析[J]. 地理科学进展, 2003, 22(6):599. YAO Zhijun, GUAN Yanping, GAO Yingchun. Analysis of distribution regulation of annual runoff and affection to annual runoff by human activity in the Chaobaihe River[J]. Progress in Geography, 2003, 22(6):599.
[2]
ZHOU Haiying, ZHANG Xiaolei, XU Hailiang, et al. Influences of climate change and human activities on Tarim River runoffs in China over the past half century[J]. Environ Earth Sci, 2012, 67(1):231.
[3]
XIA J. Screening for climate change adaptation:water problem, impact and challenges in China[J]. Int J Hydropower Dams, 2010, 17(2):78.
[4]
HAO X M, CHEN Y N, LI W H. Impact of anthropogenic activities on the hydrologic characters of the mainstream of the Tarim River in Xinjiang during the past 50 years[J]. Environ Geol, 2009, 57(2):435.
[5]
王兆礼,陈晓宏,杨涛. 近50年东江流域径流变化及影响因素分析[J]. 自然资源学报, 2010, 25(8):1365. WANG Zhaoli, CHEN Xiaohong, YANG Tao. Runoff ofvariation and its impacting factors in the Dongjiang River Basin during 1956-2005[J]. Journal of Natural Resources, 2010, 25(8):1365.
[6]
蒋晓辉,刘昌明,黄强. 黄河上中游天然径流多时间尺度变化及动因分析[J]. 自然资源学报, 2003, 18(2):142. JIANG Xiaohui, LIU Changming, HUANG Qiang. Multple time scales analysis and cause of runoff changes of the upper and middle reaches of the Yellow River[J]. Journal of Natural Resources, 2003, 18(2):142.
[7]
董林垚,陈建耀,付丛生,等. 西江流域径流与气象要素多时间尺度关联性研究[J]. 地理科学, 2013, 33(2):209. DONG Linyao, CHEN Jianyao, FU Congsheng, et al. Recognition on therelationship between runoff and regional meteorological factors of the Xijiang River in multi-time scales[J]. Scientia Geographica Sinica, 2013, 33(2):209.
[8]
孙卫国,程炳岩,李荣. 黄河源区径流量与区域气候变化的多时间尺度相关[J]. 地理学报, 2009, 64(1):117. SUN Weiguo, CHENG Bingyan, LI Rong. Multitime Scale correlations between runoff and regional climate variations in the source region of the Yellow River[J]. Acta Geographica Sinica, 2009, 64(1):117.
[9]
叶芝菡,谢云,刘宝元. 日平均气温的两种计算方法比较[J]. 北京师范大学学报(自然科学版), 2002, 38(3):421. YE Zhihan, XIE Yun, LIU Baoyuan. A comparison of mean daily temperature calculated by two methods[J]. Journal of Beijing Normal University(Natural Sciences), 2002, 38(3):421.
[10]
张涵丹,卫伟,薛萐. 基于R/S分析和Mann-Kendall检验的定西市气温降水变化特征[J]. 水土保持研究,2015,22(6):183. ZHANG Handan, WEI Wei,XUE Sha. Analysis on the variation of temperature and precipitation in Dingxi based on R/S and Mann-Kendall test[J]. Research of Soil and Water Conservation,2015,22(6):183.
[11]
刘贤赵,李嘉竹,宿庆,等. 基于集中度与集中期的径流年内分配研究[J]. 地理科学, 2007, 27(6):791. LIU Xianzhao, LI Jiazhu, SU Qing, et al. Interannual runoff distribution based on degree and time of concentration for rivers[J]. Scientia Geographica Sinica, 2007, 27(6):791.
[12]
GRINSTED A, MOORE J C, JEVREJEVA S. Application of the cross wavelet transform and wavelet coherence to geophysical time series[J]. Nonlinear Processes in Geophysics, 2004,(11):561.
[13]
于文善,胡亚魁. 建国以来淮河流域水患灾害及其治理[J]. 党史研究与教学, 2005(6):58. YU Wenshan, HU Yakui.Flood disaster and its management in Huaihe River basin since the founding of the People's Republic of China[J]. Party History Research and Teaching, 2005(6):58.
[14]
王振龙,陈玺,郝振纯,等. 淮河干流径流量长期变化趋势及周期分析[J]. 水文, 2011, 31(6):79. WANG Zhenlong, CHEN Xi, HAO Zhenchun, et al. Long-tern changing trends and periodic analysis of runoff at Lutazi station on Huaihe River[J]. Journal of China Hydrology, 2011, 31(6):79.
[15]
莫非. 霍山县志[M]. 合肥:黄山书社,1993:231. MO Fei. Huoshan county annals[M]. Hefei:Mount Huang Press, 1993:231.
2020, Vol. 18 
