期刊文献+
任意字段
题名或关键词
题名
关键词
文摘
作者
第一作者
机构
刊名
分类号
参考文献
作者简介
基金资助
栏目信息

底栖动物扰动对河床渗透性的影响研究 被引量:8

Effects of Invertebrate Bioturbation on Vertical Hydraulic Conductivity of Streambed for a River
原文传递
导出
摘要 河床渗透性是影响地表水与地下水相互交换的重要因素,为探究底栖动物扰动对河床渗透性的影响,以渭河干流上5个研究点为例,通过对河床沉积物垂向渗透系数和沉积物粒度进行分析,再结合底栖动物的种类和密度,研究垂向渗透系数与底栖动物之间的相关性,以及底栖动物扰动对河床渗透性的影响.结果表明,沉积物成分分布以沙和砾石为主的草滩,渗透系数达到18.479 m·d-1,底栖动物的生物密度为139 ind·m-2;沉积物成分中粉沙和黏土占很大比重的眉县,渗透系数为2.807 m·d-1,底栖动物的生物密度为2 742 ind·m-2;沉积物粒度分布基本相同的眉县、咸阳、临潼和华县等4个渗透性较差研究点中底栖动物的生物密度和垂向渗透系数均差别较大,但是生物密度和垂向渗透系数呈显著相关性,其两者之间皮尔森相关系数r=0.987.不同研究点影响沉积物渗透性的主要决定因素不同,渗透性较强研究点主要为沉积物颗粒大小,渗透性较差研究点主要为底栖动物扰动;不同研究点内生物密度差别较大,不同生物种类差别也较大;底栖动物的生物扰动能够缓解细小沉积物的阻塞,以使弱渗透性河床沉积物的渗透性增强. Streambed hydraulic conductivity is a key factor influencing water exchange between surface water and groundwater. However, the streambed invertebrate bioturbation has a great effect on the hydraulic conductivity. In order to determine the impact of invertebrate bioturbation on streambed hydraulic conductivity, the investigation of invertebrate bioturbation and in-situ test of vertical hydraulic conductivity of streambcd are simultaneously conducted at five points along the main stream of the Weihe River. Firstly, correlation between the streambed vertical hydraulic conductivity and grain size distribution is analyzed. Secondly, type and density of the invertebrate and their correlation to hydraulic conductivity are determined. Finally, the effect of invertebrate bioturhation on the streambed hydraulic conductivity is illustrated. The results show that the vertical hydraulic conductivity and biological density of invertebrate are 18. 479 m.d-1 and 139 ind.m-2, respectively for the Caotan site, where sediment composition with a large amount of sand and gravel particles. For Meixian site, the sediment constitutes a large amount of silt and clay particles, in which the vertical hydraulic conductivity and biological density of invertebrate are 2. 807 m.d-1 and 2 742 ind.m-2, respectively. Besides, for the low permeability of four sites (Meixian, Xianyang, Lintong and Huaxian) , grain size particles are similar while the vertical hydraulic conductivity and biological density of invertebrate are significantly different from one site to another. However, for each site, the vertical hydraulic conductivity closely related to biological density of invertebrate, the Pearson correlation coefficient is 0. 987. It can be concluded that both grain size particles and invertebrate hioturbation influence sediment permeability. For example, higher values of streambed hydraulic conductivity from strong permeability site mainly due to the large amount of large-size particles and that from low permeability site is the main results from higher biological density of invertebrate. Large amount of grain size particles can expand pore space and the invertebrate bioturbation can destroy clogging sediment and enhance sediment permeability.
作者 任朝亮 宋进喜 杨小刚 薛健
机构地区 西北大学城市与环境学院
出处 《环境科学》 EI CAS CSCD 北大核心 2013年第11期4275-4281,共7页 Environmental Science
基金 国家自然科学基金项目(51079123 51379175) 教育部新世纪优秀人才支持计划项目(NCET-11-1045) 留学人员科技活动项目择优资助项目(2011-32)
关键词 垂向渗透系数 生物扰动 底栖动物 粒度分布 弱渗透性 渭河 vertical hydraulic conductivity bioturbation invertebrate particle size distributions low permeability Weihe River
分类号 X174 [环境科学与工程—环境科学]
  • 相关文献

参考文献24

  • 1Chen X H. Streambed hydraulic conductivity for rivers in south- central Nebraska[ J]. Journal of the American Water Resources Association, 2004, 40(3): 561-573.
  • 2宋进喜,CHEN XunHong,CHENG Cheng,WANG DeMing,王文科.美国内布拉斯加州埃尔克霍恩河河床沉积物渗透系数深度变化特征[J].科学通报,2009,54(24):3892-3899. 被引量:15
  • 3Conant B Jr, Cherry J A, Gillham R W. A PCE groundwater plume discharging to a river: Influence of the streambed and near-river zone on contaminant distributions [ J ]. Journal of Contaminant Hydrology, 2004, 73(1-4): 249-279.
  • 4Chen X H, Burach M, Cheng C. Electrical and hydraulic vertical variability in channel sediments and its effects on stream flow depletion due to groundwater extraction [ J ]. Journal of Hydrology, 2008, 352(3-4): 250-266.
  • 5Blaschke A P, Steiner K H, Schmalfuss R, et al. Clogging processes in hyporheic interstices of an impounded river, the Danube at Vienna, Austria [ J ]. International Review of Hydrobiology, 2003, 88(3-4): 397-413.
  • 6Navel S, Mermillod-Blondin F, Montuelle B, et al. Water- sediment exchanges control microbial processes associated with leaf litter degradation in the hyporheic zone: a microcosm study [J]. Microbial Ecology, 2011, 61(4) : 968-979.
  • 7Wood P J, Armitage P D. Biological effects of fine sediment in the lotic environment[ J]. Environmental Management, 1997, 21 (2) : 203-217.
  • 8Nogaro G, Mermillod-Blondin F, Franqois-Carcaillet F, et al. Invertebrate bioturbation can reduce the clogging of sediment : An experimental study using infiltration sediment columns [ J ]. Freshwater Biology, 2006, 51 ( 8 ) : 1458-1473.
  • 9Mauclaire L, Schtlrmann A, Mermillod-Blondin F. Influence of hydraulic conductivity on communities of microorganisms and invertebrates in porous media: a case study in drinking water slow sand filters [ J]. Aquatic Sciences, 2006, 68 ( 1 ) : 100-108.
  • 10Jinxi SONG,Xunhong CHEN,Cheng CHENG.Observation of bioturbation and hyporheic flux in streambeds[J].Frontiers of Environmental Science & Engineering,2010,4(3):340-348. 被引量:2

二级参考文献247

共引文献209

同被引文献132

引证文献8

二级引证文献44

环境科学
2013年 第11期

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部