收藏设为首页 广告服务联系我们在线留言
高级检索

干旱区地理 >

2020 , Vol. 43 >Issue 2: 380 - 387

DOI: https://doi.org/10.12118/j.issn.1000-6060.2020.02.11

气候与水文

无定河下游全新世古洪水研究

展开

  • 商洛学院城乡规划与建筑工程学院,陕西 商洛 726000 

    2 陕西师范大学地理科学与旅游学院,陕西 西安 710119

李晓刚(1983-),男,山西吕梁人,副教授,博士,研究方向为水文地貌学.E-mail:sxlixiaogang@163.com

收稿日期: 2019-02-05

  修回日期: 2019-06-03

  网络出版日期: 2020-03-25

基金资助

国家自然科学基金目(41701090);陕西省创新能力支撑计划项目(2019KJXX-026);商洛学院科研项目(18SKY002)资助

收起

Palaeoflood events in the lower reaches of the Wudinghe River

Expand

  • College of UrbanRural Planning and Architectural Engineering Development and Management Engineering Science

    Shangluo UniversityShangluo 726000ShaanxiChina; 

    College of Geography Science and TourismShaanxi Normal UniversityXi’an 710119,ShaanxiChina

Received date: 2019-02-05

  Revised date: 2019-06-03

  Online published: 2020-03-25

Fold

摘要

对无定河流域野外考察,在其下游苏家圪坨(SJGT)地点发现夹有古洪水滞流沉积物(SWD)的全新世剖面。古洪水SWD厚度30 cm,具有平行微薄层理特征,且直接覆盖在东汉文化层之上。室内分析结果表明古洪水SWD有着与2012年洪水SWD相似的沉积学特征,以粗粉沙为主,分选良好,磁化率和烧失量较小,说明它记录了一次无定河下游的大洪水事件。文化层光释光(OSL)测年结果显示该次古洪水事件发生在1 900~1 700 a BP。古洪水洪峰水位和洪峰流量分别为765.9 m10 530 m3·s-1。同时利用2012年洪水洪痕水位验证,在同一断面用相同参数恢复洪峰流量为1 030 m3·s-1,实测洪峰流量为1 000 m3·s-1,误差为3.09%,说明古洪水洪峰流量恢复结果合理可靠。研究结果延长了无定河下游洪水数据序列,对水资源、水能源的开发利用提供了科学依据。

关键词: 古洪水水文学; 滞流沉积物; 全新世; 无定河

本文引用格式

李晓刚, 黄春长, 庞奖励 .

无定河下游全新世古洪水研究[J]. 干旱区地理, 2020 , 43(2) : 380 -387 . DOI: 10.12118/j.issn.1000-6060.2020.02.11

Abstract

In recent years,palaeoflood has been widely studied in the middle reaches of the Yellow River and its tributaries.However,Wudinghe River,Shaanxi Province,China,which is the largest tributary between Hekou and Longmen section of the Yellow River,has not been reported in these studies.A Holocene profile with palaeoflood slack water sediments was found at the Sujiagetuo (SJGT) site in the lower reaches of the Wudinghe River basin through detailed field investigation.The lower reaches of the Wuding River are bedrock canyon sections,which are suitable for palaeoflood hydrology research.The upper and lower boundaries of the palaeoflood SWD  are clear with other layers and the thickness of SWD is 30 cm .The palaeoflood SWD,characterized by thin bedding,directly covers the Eastern Han cultural layer.Experimental results show that coarse silt is the main grain size composition of the palaeoflood SWD and 2012 flood SWD and accounted for 59.58% of the palaeoflood SWD and 46.52% of 2012 flood SWD.The standard deviation (σ) and separation coefficient (S0) of palaeoflood SWD are smaller,i.e.,1.51 and 0.79,respectively,which are close to the standard deviation of 2012 flood SWD (0.33 and 0.65 respectively).The smaller values of deviation (σ) and separation coefficient show an effective sampling and sampling pretreatment procedure,indicating that they are well sorted during the sedimentation process.The magnetic susceptibility of the palaeoflood SWD and 2012 flood SWD are extremely low (37.8×10-8 m3·kg-1 and 28.3×10-8m3·kg-1),indicating that they are both fresh sediments and are hardly affected by weathering and soil formation.Palaeoflood SWD and 2012 flood SWD are also characterized by low ignition loss and high calcium carbonate content.These experimental data indicate that the sedimentological characteristics of the palaeoflood SWD and that of the flood SWD in 2012 are similar,which indicates that it recorded a large flood event in the lower reaches of Wudinghe River.OSL dating of the cultural layer shows that the palaeoflood event occurred in 1 900-1 700 a BP.According to the 22% bulk sediment of the Baijiachuan Hydrological Station in the Wudinghe River,the slack water flow depth method of palaeoflood SWD is used to restore the palaeoflood stage to 765.9 m.Based on the hydraulic parameters such as the gradient of 0.002 5 and roughness coefficient of 0.035,the peak discharge of palaeoflood was reconstructed to be 10 530 m3·s-1 by the slope-area method.Using flood mark water level in 2012,the calculated value of peak discharge is 1 030 m3·s-1 at the same section and parameters,and the error between the calculated peak discharge and the measured value is 3.09%,which shows that it is reasonable and reliable to restore the peak discharge of palaeoflood using the slopearea method in the lower reaches of the Wudinghe River.Results extend the flood data series of the lower reaches of the Wudinghe River and provide a scientific basis for the development and utilization of water resources and energy resources.

Key words:

palaeoflood hydrology; slackwater deposits; Holocene; Wudinghe River

参考文献

[1]黄健民,徐之华.气候变化与自然灾害[M].北京:气象出版社,2005:46-47.[HUANG Jianmin,XU Zhihua.Climate change and natural disasters[M].Beijing:Meteorological Press,2005:46-47.] [2]KNOX J C.Large increase in flood magnitude in response to modest changes in climate[J].Nature,1993,361:430-432. [3]BENITO G,THORNDYCRAFT V R.Palaeoflood hydrology and its role in applied hydrological sciences[J].Journal of Hydrology,2005,313:3-15.] [4]BAKER V R.Palaeoflood hydrology:Origin,progress,prospects[J].Geomorphology,2008,101:1-13.] [5]BENITO G,LANG M,BARRIENDOS M,et al.Use of systematic palaeoflood and historical data for the improvement of flood risk estimation:Review of scientific methods[J].Natural Hazards,2004,31:623-643. [6]BAKER V R.Palaeoflood hydrology and extraordinary flood events[J].Journal of Hydrology,1987,96:79-99. [7]BENITO G,ALFONSO Sopena,YOLANDA Sanchez-Moya,et al.Palaeoflood record of the Tagus River (Central Spain) during the Late Pleistocene and Holocene[J].Quaternary Science Review,2003,22:1737-1756. [8]SHEFFER N A,RICO M,ENZEL Y,et al.The palaeoflood record of the Gardon River,France:A comparison with the extreme 2002 flood event[J].Geomorphology,2008,98:71-83. [9]朱诚,郑朝贵,马春梅,等.长江三峡库区中坝遗址地层古洪水沉积判别研究[J].科学通报,2005,50(20):2240-2250.[ZHU Cheng,ZHENG Chaogui,MA Chunmei,et al.The indentify study of palaeoflood slackwater deposits in ruins layer of Yangtze River middle dam[J].Chinese Science Bulletin,2005,50(20):2240-2250.] [10]杨晓燕,夏正楷,崔之久.黄河上游全新世特大洪水及其沉积特征[J].第四纪研究,2005,25(1):80-85.[YANG Xiaoyan,XIA Zhengkai,CUI Zhijiu.Holocene extreme floods and its sedmentary characteristic in the upper reaches of the Yellow River[J].Quaternary Science,2005,25(1):80-85.] [11]黄春长,庞奖励,查小春,等.黄河流域关中盆地史前大洪水研究——以周原漆水河谷地为例[J].中国科学(地球科学),2011,41(11):1658-1669.[HUANG Chunchang,PANG Jiangli,ZHA Xiaochun,et al.Prehistorical floods in the Guanzhong Basin in the Yellow River drainage area:A case study along the Qishuihe River Valley over the Zhouyuan loess tableland[J].Science Sinica Terrae,2011,41(11):1658-1669.] [12]李晓刚,黄春长,庞奖励.丹江上游全新世早期古洪水滞流沉积物粒度特征研究[J].干旱区地理,2014,37(4):646-655.[LI Xiaogang,HUANG Chunchang,PANG Jiangli.Grain-size characteristics of the early Holocene flood slackwater deposits in the upper reaches of the Danjiang River[J].Arid Land Geography,2014,37(4):646-655.] [13]LIU Tao,HUANG Chunchang,PANG Jiangli,et al.Extraordinary hydro-climatic events during 1800-1600 yr BP in the JinShaan Gorges along the middle Yellow River,China[J].Palaeogeography,Palaeoclimatology,Palaeoecology,2014,410:143-152. [14]石彬楠,黄春长,庞奖励,等.渭河上游天水东段全新世古洪水水文学恢复研究[J].干旱区地理,2016,39(3):573-581.[SHI Binnan,HUANG Chunchang,PANG Jiangli,et al.Hydrological reconstructions of the Holocene palaeoflood in the Tianshui east reach of the upper Weihe River[J].Arid Land Geography,2016,39(3):573-581.] [15]刘雯瑾,黄春长,庞奖励,等.黄河马头关段全新世古洪水水文恢复及气候背景研究[J].干旱区地理,2017,40(1):85-93.[LIU Wenjin,HUANG Chunchang,PANG Jiangli,et al.Holocene palaeoflood and climatic changes at the Matouguan reach of the Yellow River[J].Arid Land Geography,2017,40(1):85-93.] [16]GUO Yongqiang,HUANG Chunchang,PANG Jiangli,et al.Reconstruction palaeoflood hydrology using slackwater flow depth method in the Yanhe River Valley,middle Yellow River Basin,China [J].Journal of Hydrology,2017,544,156-171. [17]王兆夺,黄春长,查小春,等.淮河上游卢庄段全新世古洪水水文恢复研究[J].干旱区地理,2018,41(2):325-333.[WANG Zhaoduo,HUANG Chunchang,ZHA Xiaochun,et al.Palaeoflood sedimentological and hydrological study of the Luzhuang section in the upper reaches of Huaihe River[J].Arid Land Geography,2018,41(2):325-333.] [18][JP2]刘科,查小春,黄春长,等.秦岭南北河流不同尺度特大洪水对比研究[J].干旱区地理,2015,38(3):494-501.[LIU Ke,ZHA Xiaochun,HUANG Chunchang,et al.A comparative study of floods of main rivers on both sides of Qinling Mountains in different timescale[J].Arid Land Geography,2015,38(3):494-501.] [19]卢寿德,卢广毓,巩琳.无定河流域2017年“7·26”暴雨洪水特征分析[J].人民黄河,2018,40(12):25-27.[LU Shoude,LU Guangyu,GONG Lin.Analysis of the characteristics of July 26,2017 rainstorm and flood in Wuding River Basin[J].Yellow River,2018,40(12):25-27.] [20]邱玉茜.无定河中游干支流设计洪峰流量频率分析[J].陕西水利,2012,(3):13-15.[QIU Yuqian.Frequency analysis of designed peak discharge in the main and branch of the middle reaches of Wuding River[J].Shaanxi Water Resources,2012,(3):13-15.] [21]姬保雄.米脂县无定河大桥防洪工程处洪水分析[J].陕西水利,2019,(3):63-65.[JI Baoxiong.Flood analysis of flood control works of Wuding River bridge in Mizhi County[J].Shaanxi Water Resources,2019,(3):63-65.] [22]吕智荣.无定河流域考古调查简报[J].史前研究,1988,(00):218-232.[LV Zhirong.Brief report on archaeological investigation in Wuding River Basin[J].Prehistoric Studies,1988,(00):218-232.] [23]徐建华,李晓宇,陈建军,等.黄河中游河口镇至龙门区间水利水保工程对暴雨洪水泥沙影响研究[M].郑州:黄河水利出版社,2009:1-340.[XU Jianhua,LI Xiaoyu,CHEN Jianjun,et al. Effects of engineering on storm rains and floods in the middle reaches of the Yellow River—the Hekou to Longmen part[M].Zhengzhou:Yellow River Conservancy Press,2009:1-340.] [24]史辅成,易元俊,慕平.黄河历史洪水调查、考证和研究[M].郑州:黄河水利出版社,2002:81-123.[SHI Fucheng,YI Yuan jun,MU Ping.Investigation,research and study on the Yellow Historical Flood[M].Zhengzhou:Yellow River Water Conservancy Press,2002:81-123.] [25]HUANG Chunchang,PANG Jiangli,ZHA Xiaochun,et al.Extraordinary hydroclimatic events during the period AD 200300 recorded by slackwater deposits in the upper Hanjiang River Valley,China[J].Palaeogeography,Palaeoclimatology,Palaeoecology,2013,374:274-283. [26]张丕远,葛全胜,张时煌,等.2000年来我国旱涝气候演化的阶段性和突变[J].第四纪研究,1997,17(1):12-20.[ZHANG Peiyuan,GE Quansheng,ZHANG Shihuang,et al.The modes and abrupt changes of climate in China during recent 2000 years[J].Quaternary Science,1997,17(1):12-20.] [27]HUANG Chunchang,JIA Yaofeng,PANG Jiangli,et al.Holocene colluviation and its implications for tracing humaninduced soil erosion and redeposition on the piedmont loess lands of the Qinling Mountains,northern China[J].Geoderma,2006,136:838-851. [28]詹道江,谢悦波.古洪水研究[M].北京:中国水利水电出版社,2001:1-83.[ ZHAN Daojiang,XIE Yuebo.Palaeoflood study[M].Beijing:China Water Power Press,2001:1-83.] [29]武汉水利电力学院水力学教研室编.水力学[M].北京:高等教育出版社,1986:335-336.[Wuhan College of Water Resource and Hydropower.Hydraulics[M].Beijing:Higher Education Press,1986:335-336.] [30]BAKER V R.Paleoflood hydrology in a global context[J].Catena,2006,66:161-168.
Options
文章导航

/