半干旱区降水和水土保持措施强度-径流演变规律研究

doi:10.12118/j.issn.1000-6060.2020.06.03

干旱区地理 ›› 2020, Vol. 43 ›› Issue (6): 1426-1434.doi: 10.12118/j.issn.1000-6060.2020.06.03

半干旱区降水和水土保持措施强度-径流演变规律研究

胡彦婷 ¹，张富¹，罗珠珠^2,3，靳峰 ⁴，周蕊 ⁵，赵秀兰 ¹，包炳琛 ¹

1 甘肃农业大学林学院，甘肃兰州 730070； 2 甘肃省干旱生境作物学国家重点实验室/甘肃农业大学，甘肃兰州 730070； 3 甘肃农业大学资源与环境学院，甘肃兰州 730070； 4 甘肃省水利厅，甘肃兰州 730000； 5 甘肃省水土保持科学研究所，甘肃兰州 730000

收稿日期:2019-10-19 修回日期:2020-01-13 出版日期:2020-11-25 发布日期:2020-11-25
通讯作者: 张富（1961-），男，博士，研究员，主要从事半干旱区不同尺度土壤侵蚀研究.
作者简介:胡彦婷（1991-），女，甘肃天水人，博士，主要从事半干旱区水文研究. E-mail:hyt10170909@163.com
基金资助:
甘肃农业大学科技创新基金项目（GSAU-XKJS-2018-105）

Precipitation and soil and water conservation measures intensity-runoff evolution law in semi-arid areas

HU Yan-ting¹, ZHANG Fu¹, LUO Zhu-zhu^2,3, JIN Feng⁴, ZHOU Rui⁵, ZHAO Xiu-lan¹, BAO Bing-chen¹

1 College of Forestry, Gansu Agricultural University, Lanzhou 730070, Gansu, China; 2 Gansu Key Laboratory of Aridland Crop Science/ Gansu Agricultural University, Lanzhou 730070, Gansu, China; 3 College of Resources and Environmental Sciences, Gansu Agricultural University, Lanzhou 730070, Gansu, China; 4 Gansu Provincial Department of Water Resources, Lanzhou 730000, Gansu, China; 5 College of Forestry, Gansu Agricultural University, Lanzhou 730000, Gansu, China

Received:2019-10-19 Revised:2020-01-13 Online:2020-11-25 Published:2020-11-25

摘要/Abstract

摘要： 为研究不同时期及水土保持措施条件下，降水量、水土保持措施强度与径流的演变规律，运用泰森多边形法、Morlet 小波分析法、回归分析法，构建多元功效函数，进行甘肃省定西市安定区近 60 a 年降水量、措施强度与径流演变研究。结果表明：1957—2016 年年径流量呈递减趋势，达极显著水平（P＜0.001）；在 22 ~ 24 a、8 a、4 a 时间尺度上，年降水量和径流具有明显的震荡周期，平均周期为 15 a、5 a、3 a 左右。梯田、造林、种草及封育等水土保持措施强度逐年递增，分别达 36.14 hm²?km^-2、25.26 hm²?km^-2、11.56 hm²?km^-2 和 3.22 hm²?km^-2。随周期（3 a、5 a、15 a）的变长，同等降水量对产流量影响有所增大；同等水土保持措施强度对产流量影响有所减小；降水量和措施强度组合解释了径流模数总方差的 57.46% ~ 85.80%；降水量对径流模数的影响约低于 40%，措施强度的影响约高于 60%，说明措施强度对径流的影响较降水量更大。近 60 a 径流量的减少，主要是由于水土保持措施的递增引起。

关键词: 演变规律, 降水量, 水土保持措施强度, 径流, 半干旱区

Abstract: The evolution law and cause analysis of runoff in a climate change, principally the quantitative analysis of the impact of precipitation and soil and water conservation measures on runoff, are still hot issues in the current hydrology and water resources research. An improved understanding of the effect of rainfall and soil and water conserving practices on runoff is obligatory to manage runoff under a changing climate. The current study aims specifically to the evolution of precipitation, measures, and runoff under different periods and soil and water conservation measures. Here, the average precipitation using the Tyson polygon method was determined. The periodicity of precipitation and runoff was analyzed using the Morlet wavelet analysis. Moreover, in order to analyze the relationship between different periods of precipitation, a runoff regression analysis was performed in a controlled area. Through the construction of multivariate function, precipitation was determined, intensity was measured, and runoff evolution was predicted in Anding District, Dingxi City, Gansu Province, China in the past 60 a. The results depicted that (1) the annual runoff exhibits a decreasing trend from 1957 to 2016. The runoff decline reached a very significant level (P<0.001) except with the annual precipitation. On the time scale of 22- 24 a, 8 a, and 4 a, the annual precipitation and runoff have obvious oscillation periods and the average period is about 15 a, 5 a, and 3 a. In the first 10 a, the runoff responded strongly to the change of precipitation and the trend was highly synergistic, indicating that this period had a better correlation. In the last 50 a, the response of the runoff to the change of precipitation is attenuated rapidly, and the trend is synergistic alienation, illustrating that the runoff change of the study area after 1986 is greatly affected by other factors, especially after 2000. (2) With the advancement of soil and water conservation work, the intensity of soil and water conservation measures such as terraces, artificial afforestation, artificial grass planting, and enclosure gradually increase to 36.14 hm² ?km^{- 2}, 25.26 hm² ?km^{- 2}, 11.56 hm² ?km^{- 2}, and 3.22 hm² ?km^{- 2}, respectively. With the implementation of soil and water conservation measures, such as conversion of cropland to forest and grassland and terracing of sloping fields, the non-controlled area is gradually transformed into the controlled area. (3) With the increase of the period (3 a, 5 a, 15 a), the effect of the same precipitation on the runoff generation increases, and the impact of the same intensity of measures on the runoff generation decreases. The combination of precipitation and measured intensity explained 57.46%- 85.80% of the total variance of runoff modulus. The influence of precipitation on runoff modulus was about less than 40% and the impact of measure intensity was about 60% higher. This shows that the impact of the intensity of measures on runoff exceeds the driving force of the precipitation factor. Under the condition of no-significant changes in precipitation in the past 60 a from 1957 to 2016, the continuous decrease in runoff is due to the increase in the intensity of soil and water conservation measures. This study provides support for scientific and rational adjustment of land use structure, deployment of soil and water conservation measures, and construction of ecological environment.

Key words: evolution law, precipitation, soil and water conservation measures intensity, runoff, semi-arid area

胡彦婷, 张富, 罗珠珠, 靳峰, 周蕊, 赵秀兰, 包炳琛 . 半干旱区降水和水土保持措施强度-径流演变规律研究[J]. 干旱区地理, 2020, 43(6): 1426-1434.

HU Yan-ting, ZHANG Fu, LUO Zhu-zhu, JIN Feng, ZHOU Rui, ZHAO Xiu-lan, BAO Bing-chen. Precipitation and soil and water conservation measures intensity-runoff evolution law in semi-arid areas[J]. Arid Land Geography, 2020, 43(6): 1426-1434.

参考文献 32

[1]	ZHU L Q, ZHU W B. Research on effects of land use/cover change on soil erosion[J]. Advanced Materials Research, 2012, 433- 440: 1038-1043.
[2]	LATOCHA A, SZYMANOWSKI M, JEZIORSKA J, et al. Effects of land abandonment and climate change on soil erosion: An exam⁃
[12]	刘剑宇, 张强, 陈喜, 等. 气候变化和人类活动对中国地表水文过程影响定量研究[J]. 地理学报, 2016, 71(11): 5-15. [LIU Ji⁃ anyu, ZHANG Qiang, CHEN Xi, et al. Quantitative evaluations of human- and climate- induced impacts on hydrological processes of China[J]. Acta Geographica Sinica, 2016, 71(11): 5-15. ]
[13]	MAHMOODI N, KIESEL J, WAGNER P D, et al. Integrating wa⁃ ter use systems and soil and water conservation measures into a hy⁃ drological model of an Iranian Wadi system[J]. Journal of Arid Land, 2020, 12(4): 545-560.
[14]	PIAOS L, FRIEDLINGSTEINP, CIAIS P, et al. Changes in climate and land use have a larger direct impact than rising CO2 on global river runoff trends[J]. Proceedings of the National Academy of Sci⁃ ences of the United States of America, 2007, 104(39): 15242- 15247.
[15]	夏库热·塔依尔, 海米提·依米提, 麦麦提吐尔逊·艾则孜, 等. 基于小波分析的开都河径流变化周期研究[J]. 水土保持研究, 2014, 21(1): 142-146, 151. [TAHIR Shakure, YIMIT Hamid, EZIZ Mamattursun, et al. Research on period of annual runoff in Kaidu River based on wavelet analysis[J]. Research of Soil and Water Conservation, 2014, 21(1): 142-146, 151. ]
[16]	刘纪根, 任洪玉, 牛俊, 等. 紫色土区小流域侵蚀产沙对水土保持措施的响应[J]. 水土保持研究, 2018, 25(2): 29-33. [LIU Ji⁃ gen, REN Hongyu, NIU Jun, et al. Response of erosion and sedi⁃ ment yield to soil and water conservation measures in small water⁃ shed in Purple Soil Region[J]. Research of Soil and Water Conser⁃ vation, 2018, 25(2): 29-33. ]
[17]	张富, 赵传燕, 邓居礼, 等. 祖厉河流域降水径流泥沙变化特征研究 [J]. 干旱区地理, 2018, 41(1): 74- 82. [ZHANG Fu, ZHAO Chuanyan, DENG Juli, et al. Change characteristics of the precipi⁃ tation, runoff and sediment discharge in Zulihe River Basin[J]. Ar⁃ id Land Geography, 2018, 41(1): 74-82. ]
[18]	ZHANG F, XING Z S, ZHAO C Y, et al. Characterizing long-term soil and water erosion and their interactions with various conserva⁃ tion practices in the semi-arid Zulihe Basin, Dingxi, Gansu, China [J]. Ecological Engineering, 2017, 106: 458-470.
[19]	邓国卫, 王敏. 都江堰特大暴雨过程中 GIS 的多种面雨量计算方法对比 [J]. 高原山地气象研究, 2018, 38(1): 81- 86, 95. [DENG Guowei, WANG Min. Comparison of surface rainfall calcu⁃ lation methods for GIS during the heavy rain process in Dujiangyan [J]. Plateau and Mountain Meteorology Research, 2018, 38(1): 81- 86, 95. ]
[20]	祁春阳, 戴欢, 赵晓燕, 等. 基于虚拟力和泰森多边形的分布式覆盖算法 [J]. 计算机工程与设计, 2018, 39(3): 606- 611. [QI Chunyang, DAI Huan, ZHAO Xiaoyan, et al. Distributed coverage algorithm based on virtual force and voronoi[J]. Computer Engi⁃ neering and Design, 2018, 39(3): 606- 611. ]
[21]	王文圣, 丁晶, 李跃清. 水文小波分析[M]. 北京: 化学工业出版社, 2005: 115- 141. [WANG Wensheng, DING Jing, LI Yueqing. Hydrology wavelet analysis[M]. Beijing: Chemical Industry Press, 2005: 115-141. ]
[22]	MARGRIET N. Wavelet analysis of rainfall- runoff variability iso⁃ lating climatic from anthropogenic patterns[J]. Environ Model Soft⁃ ware, 1999, 14: 283-295.
[23]	王蕊, 姚治君, 刘兆飞, 等. 雅鲁藏布江中游地区气候要素变化及径流的响应 [J]. 资源科学, 2015, 37(3): 619- 628. [WANG Rui, YAO Zhijun, LIU Zhaofei, et al. Changes in climate and run⁃ off in the middle course area of the Yarlung Zangbo River Basin [J]. Resources Science, 2015, 37(3): 619-628. ]
[24]	鞠彬, 叶文, 胡丹. 新疆额尔齐斯河流域降水量变化特征及趋势分析[J]. 水资源与水工程学报, 2015, 26(4): 115-119. [JU Bin, YE Wen, HU Dan. Variation characteristics and trend of precipita⁃ tion in Irtysh River Basin of Xinjiang[J]. Journal of Water Resourc⁃ es and Water engineering, 2015, 26(4): 115-119. ]
[25]	LU B J, LEI H M, YANG D W, et al. Separating the effects of re⁃ vegetation and sediment-trapping dams construction on runoff and its application to a semi-arid watershed of the Loess Plateau[J]. Eco⁃ logical Engineering, 2020, 158: 1-13.
[26]	王飞, 朱仲元, 张鹏, 等. SRM 融雪径流模型在锡林河流域的应用 [J]. 干旱区研究, 2019, 36(3): 575- 581. [WANG Fei, ZHU Zhongyuan, ZHANG Peng, et al. Application of a snowmelt runoff model in the Xilin River Basin[J]. Arid Zone Research, 2019, 36 (3): 575-581. ]
[27]	张宏芳, 李建科, 潘留杰, 等. 陕西暖季降水的日变化特征及南北差异[J]. 干旱区地理, 2020, 43(4): 889-898. [ZHANG Hong⁃ fang, LI Jianke, PAN Liujie, et al. Diurnal variation characteris⁃ tics and north-south differences of precipitation in warm season in Shaanxi[J]. Arid Land Geography, 2020, 43(4): 889-898. ]
[28]	孙栋元, 齐广平, 马彦麟, 等. 疏勒河干流径流变化特征研究[J]. 干旱区地理, 2020, 43(3): 557-567. [SUN Dongyuan, QI Guang⁃ ping, MA Yanlin, et al. Variation characteristics of runoff in the mainstream of Shule River[J]. Arid Land Geography, 2020, 43(3): 557-567. ]
[29]	程鹏, 孔祥伟, 罗汉, 等. 近 60 a 以来祁连山中部气候变化及其径流响应研究 [J]. 干旱区地理, 2020, 43(5): 1192- 1201. [CHENG Peng, KONG Xiangwei, LUO Han, et al. Study on cli⁃ mate change and its runoff response in the middle section of the Qilian Mountains in the past 60 years[J]. Arid Land Geography, 2020, 43(5): 1192-1201. ]
[30]	柳冬青, 张金茜, 巩杰, 等. 陇中黄土丘陵区土地利用强度-生态系统服务-人类福祉时空关系研究——以安定区为例[J]. 生态学报, 2019, 39(2): 637- 648. [LIU Dongqing, ZHANG Jinxi, GONG Jie, et al. Spatial and temporal relations among land-use in⁃ tensity, ecosystem services, and human well- being in the Long⁃ zhong Loess Hilly Region: A case study of the Anding District, Gansu Province[J]. Acta Ecologica Sinica, 2019, 39(2): 637-648. ]
[31]	秦瑞杰, 李桂芳, 李平. 降水和土地利用变化对罗玉沟流域水沙关系的影响 [J]. 水土保持学报, 2018, 32(5): 32- 37, 43. [QIN Ruijie, LI Guifang, LI Ping. Impacts of precipitation and land use change on runoff and sediment in Luoyugou watershed[J]. Journal of Soil and Water Conservation, 2018, 32(5): 32-37, 43. ]
[32]	夏露, 宋孝玉, 李怀有, 等. 砚瓦川流域水沙演变特征及其驱动因素分析 [J]. 水土保持学报, 2016, 30(1): 89- 95. [XIA Lu, SONG Xiaoyu, LI Huaiyou, et al. Evolution characteristics of runoff and sediment yield and their driving factors in Yanwachuan Basin [J]. Journal of Soil and Water Conservation, 2016, 30(1): 89-95. ]

[1]	田昊玮, 陈伏龙, 龙爱华, 刘静, 海洋. 博尔塔拉河源流区径流对气候变化的响应及预测[J]. 干旱区地理, 2023, 46(9): 1432-1442.
[2]	魏英楠, 马龙, 孙柏林, 张晶. 基于红皮云杉（Picea koraiensis）重建大兴安岭南麓历史径流量[J]. 干旱区地理, 2023, 46(8): 1269-1278.
[3]	成硕, 李艳忠, 星寅聪, 于志国, 王渊刚, 黄曼捷. 遥感降水产品对黄河源区水文干旱特征的模拟性能分析[J]. 干旱区地理, 2023, 46(7): 1063-1072.
[4]	晋子振, 秦翔, 赵求东, 李延召, 刘宇硕, 陈记祖, 王利辉, 王强. 祁连山西段老虎沟流域消融季径流变化特征研究[J]. 干旱区地理, 2023, 46(2): 178-190.
[5]	琚立, 冉敏, 杨运鹏, 王馨. 塔里木盆地西南缘表土碳同位素组成特征分析[J]. 干旱区地理, 2022, 45(6): 1805-1813.
[6]	代青措, 保广裕, 祁栋林, 李永花, 刘佳茹, 张静, 李宝华. 京藏高速青海东部地区汛期路面水膜厚度变化特征及预报模型构建[J]. 干旱区地理, 2022, 45(6): 1814-1823.
[7]	梁鹏飞,辛惠娟,李宗省,张百娟,桂娟,段然,南富森,丁增扬平,杨盛梅. 祁连山黑河径流变化特征及影响因素研究[J]. 干旱区地理, 2022, 45(5): 1460-1471.
[8]	程静,王鹏,陈红翔,韩永贵. 半干旱区生态风险时空演变及其影响因素的地理探测——以宁夏盐池县为例[J]. 干旱区地理, 2022, 45(5): 1637-1648.
[9]	成艺,武兰珍,刘峰贵,沈彦俊. 黄河上游近60 a径流量与降水量变化特征研究[J]. 干旱区地理, 2022, 45(4): 1022-1031.
[10]	韩典辰,张方敏,陈吉泉,李云鹏,卢琦,卢燕宇. 内蒙古半干旱区蒸散估算和归因分析[J]. 干旱区地理, 2022, 45(4): 1071-1081.
[11]	韩艳莉,于德永,陈克龙,杨海镇. 2000—2018年青海湖流域气温和降水量变化趋势空间分布特征[J]. 干旱区地理, 2022, 45(4): 999-1009.
[12]	刘宇,管子隆,田济扬,刘荣华,关荣浩. 近70 a泾河流域径流变化及其驱动因素研究[J]. 干旱区地理, 2022, 45(1): 17-26.
[13]	郭玉琳,赵勇,周雅蔓,黄秋霞,余贞谊,顾张杰. 新疆天山山区夏季降水日变化特征及其与海拔高度关系[J]. 干旱区地理, 2022, 45(1): 57-65.
[14]	蔡文静,陈伏龙,何朝飞,骆成彦,龙爱华. 基于时频分析的LSTM组合模型径流预测[J]. 干旱区地理, 2021, 44(6): 1696-1706.
[15]	陈硕,段伟利,李肖杨. 上游不同开发情景对阿克苏河径流变化影响分析[J]. 干旱区地理, 2021, 44(5): 1365-1372.

半干旱区降水和水土保持措施强度-径流演变规律研究

Precipitation and soil and water conservation measures intensity-runoff evolution law in semi-arid areas

PDF (PC)

赞

可视化

摘要/Abstract

引用本文

使用本文

参考文献 32

相关文章 15

Metrics

本文评价

推荐阅读 0