投稿中心

审稿中心

编辑中心

期刊出版

网站地图

友情链接

引用本文:吴晓东,王国祥,魏宏农,李振国,杭子清.模拟水位上升对黑藻生长的影响.湖泊科学,2012,24(3):384-390. DOI:10.18307/2012.0309
WU Xiaodong,WANG Guoxiang,WEI Hongnong,LI Zhenguo,HANG Ziqing.Growth responses of Hydrilla verticillata to increasing water levels. J. Lake Sci.2012,24(3):384-390. DOI:10.18307/2012.0309
【打印本页】   【HTML】   【下载PDF全文】   查看/发表评论  【EndNote】   【RefMan】   【BibTex】
←前一篇|后一篇→ 过刊浏览    高级检索
本文已被:浏览 8157次   下载 3825 本文二维码信息
码上扫一扫!
分享到: 微信 更多
模拟水位上升对黑藻生长的影响
吴晓东1, 王国祥1, 魏宏农1, 李振国1,2, 杭子清1
1.南京师范大学地理科学学院江苏省环境演变与生态建设重点实验室, 南京 210046;2.湖南科技大学建筑与城乡规划学院, 湘潭 411201
摘要:
为研究不同水位上升速度对黑藻生长的影响,本研究采用吊盆悬挂方式模拟不同水位上升速度,将栽种黑藻的吊盆以不同的速度(10、30、50和70 cm/5 d)往下降,分别记为T1、T2、T3、T4实验组.实验共进行80 d.结果表明:不同水位上升速度对黑藻株高影响极显著,各组株高排序为T3组 > T2组 > T1组 > T4组.T2、T3组株高与稳定组差异不显著;T3组株高生长速率达3.7 cm/d;而T4组在实验第49 d完全死亡.水位上升对黑藻分枝数影响显著,分枝数随水位上升速度增大呈递减趋势,且明显少于稳定组.不同水位上升组茎节数、叶片数和节间距均差异显著.随着水位上升速度增加,黑藻茎节数先增后减,叶片数变少,而节间距不断延长;与稳定组相比,茎节数和叶片数减少,而节间距显著延长.水位上升速率增加,黑藻生物量呈递减趋势且差异极显著,水位上升降低了黑藻生物量.黑藻有较强的应对水位上升的能力,其通过改变植株形态,以最大限度地获取光照;但在适应水位上升过程中消耗了一部分光合作用形成的物质,从而使生物量下降.黑藻对水位上升有一定的耐受范围.当水位上升达到70 cm/5 d时,黑藻因无法适应低光照胁迫而死亡.
关键词:  黑藻  水位  生长  植株形态
DOI:10.18307/2012.0309
分类号:
基金项目:国家自然科学基金项目(40873057)资助
Growth responses of Hydrilla verticillata to increasing water levels
WU Xiaodong1, WANG Guoxiang1, WEI Hongnong1, LI Zhenguo1,2, HANG Ziqing1
1.College of Geographical Science, Nanjing Normal University, Jiangsu Key Laboratory of Environmental Change and Ecological Construction, Nanjing 210046, P. R. China;2.School of Architecture and Urban Planning, Hunan University of Science and Technology, Xiangtan 411201, P. R. China
Abstract:
Growth responses of Hydrilla verticillata to increasing water levels were examined in this experiment. The plants were cultured in pots, which were submersed in water and dropped downward the lake bottom at different speeds. The results show that different rising rates of water level had significant influence on the stem lengths, which were 50 cm/5 d > 30 cm/5 d > 10 cm/5 d > 70 cm/5 d. However, no obvious differences in the stem length were found between the groups of 10, 30 cm/5 d and control groups. At the group of 50 cm/5 d, the growth rate in stem length rose at 3.7 cm/d; however, the group of 70 cm/5 d died at the 49th day. Besides, the rising of water level also significantly affects the number of branches of H. verticillata. Comparing to the control groups, went up, the node number of H. verticillata declined with the rising water level rates. Obvious differences were found in the number of nodes, leaves and length between different water level rising rates groups. With the water level rising rate increased, the number of nodes followed the trend of increasing first and then declined; numbers of leaves became fewer and the node spacing extended. Compared with the control group, the numbers of nodes and leaves are less, and the node spacing enlarged. With increasing of the rising rates of water level, its biomass declined and the differences were extremely significant. These indicated that, to get as much sunlight as possible, H. verticillata changes the plant morphology and reduces the biomass to adapt to the rising water. However, owing to the inability to accommodate itself to the stresses caused by the lack of sunlight, it would die under the water rising to 70 cm/5 d.
Key words:  Hydrilla verticillata  water level  growth  plant morphology
分享按钮