引用本文: | 杨晓东, 罗艾滢, 黄玉清, 莫 凌, 徐广平, 姚月锋.漓江上游毛竹生理生态特征对不同土壤水分的响应[J].广西植物,2017,37(2):211-219.[点击复制] |
YANG Xiao-DONG, LUO Ai-Ying, HUANG Yu-Qing,
MO Ling, XU Guang-Ping, YAO Yue-Feng.Effects of soil moisture on the ecophysiology of moso bamboo (Phyllostachys edulis)in upper reaches of Lijiang River[J].Guihaia,2017,37(2):211-219.[点击复制] |
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漓江上游毛竹生理生态特征对不同土壤水分的响应 |
杨晓东1,2, 罗艾滢2, 黄玉清2*, 莫 凌2, 徐广平2, 姚月锋2
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1. 广西师范大学 生命科学学院, 广西 桂林 541004;2. 广西喀斯特植物保育与
恢复生态学重点实验室, 广西植物研究所, 广西 桂林 541004
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摘要: |
漓江上游毛竹林面积大,是我国毛竹最南端产区。该研究针对当地季节性干旱问题,通过模拟降水使土壤水分变化,共设立了5个毛竹水分处理小区(CK. 对照; A. 无降水+覆膜; B. 降水5 mm+覆膜; C. 降水10 mm+覆膜; D. 降水20 mm+覆膜),并与HM(木荷Schima superba)(自然状态)进行对比。结果表明:土壤水分变化影响了毛竹叶片水势和叶绿素的变化,叶片白天水势下降,傍晚均可恢复到凌晨水势。C处理的毛竹午间水势下降值最小,叶绿素含量也最高。本研究区位于最南端产区,毛竹的光合生产力也属偏低水平。适当的土壤水分亏缺,毛竹表现出相对的高净光合速率(Pn)、高蒸腾速率(Tr)、低水分利用效率(WUE)的特点; 过多或过少土壤水分,则为低Pn和Tr,但高WUE。毛竹叶片的Pn与气孔导度Gs呈极显著的正相关关系,说明毛竹的光合速率受气孔调节明显; Tr与午时叶水势呈负相关(符合二项式函数)关系,土壤水分问题造成的叶片水分不足同时也影响了毛竹的Tr。水分亏缺,Pn主要由气孔调节,但水分过多导致Pn的下降应该是由气孔导度的下降和叶肉细胞光合能力的下降共同作用的结果。水分过少或过多均对毛竹生理生态过程产生负效应。相对于木荷,毛竹的Pn较高,但同时也消耗更多的水分。 |
关键词: 毛竹, 土壤水分, 光合特性, 最南产区, 漓江上游 |
DOI:10.11931/guihaia.gxzw201601004 |
分类号:Q945.11 |
文章编号:1000-3142(2017)02-0211-10 |
基金项目:国家科技支撑计划项目(2012BAC16B02、01); 广西自然科学基金(2015GXNSFBA139088)[Supported by the National Key Technology R & D Program of China(2012BAC16B02,01); Natural Science Fundation of Guangxi(2015GXNSFBA139088)]。 |
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Effects of soil moisture on the ecophysiology of moso bamboo (Phyllostachys edulis)in upper reaches of Lijiang River |
YANG Xiao-DONG1,2, LUO Ai-Ying2, HUANG Yu-Qing2*,
MO Ling2, XU Guang-Ping2, YAO Yue-Feng2
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1. College of Life Sciences, Guangxi Normal University, Guilin 541004, Guangxi, China;2. Guangxi Institute of Botany,
Guangxi Zhuang Autonomous Region and Chinese Academy of Sciences, Guilin 541006, Guangxi, China
1. College of Life Sciences, Guangxi Normal University, Guilin 541004, Guangxi, China; 2. Guangxi Institute of Botany,
Guangxi Zhuang Autonomous Region and Chinese Academy of Sciences, Guilin 541006, Guangxi, China
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Abstract: |
There is a large area of moso bamboo plantation in upper reaches of Lijiang River, where it is the most southern moso bamboo plantation area in China. Seasonal drought occurs frequently in this area which may influence on ecophysiological strategy of moso bamboo. In this paper, we simulated rainfalls which might lead to soil moisture change, thereby to investigate the response of gas exchange of moso bamboo. We made five water treatments: CK. no rainfall and no plastic cover(PC); A. no rainfall but with PC; B. 5 mm rainfall with PC; C. 10 mm rainfall with PC; D. 20 mm rainfall with PC)in bamboo community, and one treatment(natural condition)with native plant Schima superba for comparison. The results showed that simulated rainfall causing soil moisture increase, which resulted in moso bamboo leaf water potential and chlorophyll change. Water potential of the sampled moso bamboo leaves decreased during day time, and could increase again to the level of predawn by the evening. Comparing to other treatments, in Treatment C, water potential decreasing value from predawn to noon was the least, while chlorophyll concentration was the highest. In this most southern area, photosynthetic productivity of our moso bamboo was low compared to other references. Under small water deficiency, moso bamboo leaf might present a high net photosynthesis rate(Pn), high transpiration(Tr)and low water use efficiency(WUE), while under saturated and prolong soil water and low soil water condition, it presented a low Pn and low Tr, but high WUE. Pn and stomatal conductance(Gs)of moso bamboo presented a closely positive correlation indicating Pn was regulated evidently by stomatal. Meanwhile, Tr and water potential at noon presented a negative correlation(binomial function)demonstrating that soil water influencing on moso bamboo leaf water concentration and transpiration. When water deficiency, Pn was regulated mainly by stomatal, but when water saturated and prolong, decreasing of Pn might be due to mutual influence by Gs decreasing and the decline of photosynthetic capacity of mesophyll cells. Therefore, sever water deficiency and over water may result in a negative effect on ecophysiology of moso bamboo. Comparing to native broad evergreen leaf species S. superba, moso bamboo has a higher Pn, and consumes much more water at the same time. |
Key words: moso bamboo, soil moisture, photosynthetic characteristics, the most southern plantation, upper reaches of Lijiang River |
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