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[1]夏银华,章新平,戴军杰,等.亚热带季风区樟树树干液流对降水的响应[J].水土保持研究,2021,28(06):144-152.
　XIA Yinhua,ZHANG Xinping,DAI Junjie,et al.Response of Stem Sap Flow of Cinnamomum Camphora to Precipitation Under Different Environments in the Subtropical Monsoon Region[J].Research of Soil and Water Conservation,2021,28(06):144-152.

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亚热带季风区樟树树干液流对降水的响应

《水土保持研究》[ISSN:1005-3409/CN:61-1272/P] 卷: 28 期数: 2021年06期页码: 144-152 栏目: 出版日期: 2021-10-10

Title:: Response of Stem Sap Flow of Cinnamomum Camphora to Precipitation Under Different Environments in the Subtropical Monsoon Region

文章编号:: 1005-3409(2021)06-0144-09

作者:: 夏银华¹，章新平^1,2，戴军杰¹，王锐¹，罗紫东¹; (1.湖南师范大学地理科学学院，长沙 410081; 2.湖南师范大学地理空间大数据挖掘与应用湖南省重点实验室，长沙 410081)

Author(s):: XIA Yinhua¹，ZHANG Xinping^1,2，DAI Junjie¹，WANG Rui¹，LUO Zidong¹; (1.College of Geographical Sciences，Hunan Normal University，Changsha 410081，China; 2.Key Laboratory of Geospatial Big Data Mining and Applicaion，Hunan Normal University，Changsha 410081，China)

关键词:: 树干液流; 热扩散式探针技术; 降水; 土壤含水量; 蒸腾变量

Keywords:: stem sap flow; thermal dissipation probe; precipitation; soil moisture content; variable transpiration

分类号:: S715.4

文献标志码:: A

摘要:: 为探究樟树(Cinnamomum camphora)树干液流对降水的响应，利用热扩散式探针技术(TDP)于2019年6月—2020年5月在长沙地区连续观测了樟树树干液流，且同步测定了土壤含水量和气象因子，分析了樟树树干液流在不同天气条件下的日变化特征、不同量级降水条件下的特征以及不同土壤水分条件下对环境因子的响应。结果表明:(1)樟树树干液流随天气的变化而变化，晴天高于雨天。晴天液流日变化呈倒“U”型单峰曲线，雨天液流随降水的分布呈单峰、多峰曲线或一直处于较低值。晴天气象因子对液流的解释程度比雨天高。(2)液流对不同降水量的响应不同，0～5 mm降水前后液流差异性不显著; 大于5 mm降水后液流较降水前显著提高，但液流增幅与降水量之间没有明显的规律。5～10 mm，10～25 mm，25～50 mm和大于50 mm降水后液流增幅分别为13.2%，47.3%，20.6%和5.5%。(3)液流在少雨的土壤水分相对亏缺时期(RDP)较多雨的土壤水分相对充足时期(RSP)低，两个时期的液流与气象因子呈二次函数关系。不同土壤水分条件下液流与蒸腾变量的关系可以采用指数饱和函数进行拟合。RDP时期樟树的蒸腾作用受到抑制，降水后RSP时期土壤水分条件改善，樟树对太阳辐射、温度、饱和水汽压差和相对湿度的敏感性增加，导水能力增强。研究发现，树干液流对降水的响应因降水量的不同表现出较大的差异性，存在一定的降水阈值使降水后液流上升。降水可以通过引起气象因子的改变以及土壤水分的改善从而使樟树树干液流的水平提高。

Abstract:: In order to explore rainfall effects on sap flow of Cinnamomum camphora，thermal dissipation probe(TDP)was used to measure the stem sap flow of sample trees in Changsha from June 2019 to May 2020. Moreover the soil moisture content and meteorological factors were observed simultaneously. This study analyzed the diurnal variation characteristics of the stem sap flow under different weather conditions and its response to precipitation in different intensities. What's more，the response of sap flow to environmental factors under different soil moisture conditions had also been investigated. The results show that:(1)the sap flow changed with the weather，and it was higher on sunny days than on rainy days; daily variations of sap flow exhibited invented ‘U' mono-peak patterns during sunny days and showed single-peak or multi-peak curves or were always at a low level with the distribution of precipitation during rainy days; weather factors on sunny days could explain sap flow better than on rainy days;(2)precipitation with different intensities exerted different impacts on sap flow; sap flow was little change after 0～5 mm precipitation，whereas the sap flow increased significantly while the precipitation was more than 5 mm; however，there was no obvious regularity between the increase of sap flow and precipitation intensity; the sap flow after precipitation with 5～10 mm，10～25 mm，25～50 mm and greater than 50 mm increased by 13.2%，47.3%，20.6% and 5.5%，respectively;(3)the sap flow in the relative deficient period of soil moisture(RDP)and lack of rain was lower than that in the relative sufficient period of soil moisture(RSP)and plenty of precipitation; the sap flow in the two periods showed a quadratic function relation with meteorological factors; the relationship between liquid flow and variable transpiration under different soil water conditions could be fitted by the exponential saturation function; it was found that the transpiration of C. camphora was inhibited in RDP，and the sensitivity of transpiration reacting to solar radiation，temperature，saturated vapor pressure difference and relative humidity improved in RSP; moreover，the conductivity of the stem was enhanced too. In this study，the response of the stem sap flow to precipitation showed great difference due to the different precipitation，and there was a certain precipitation threshold that made the sap flow rise after precipitation. Precipitation can increase the sap flow level of C. camphora by changing meteorological factors and improving soil moisture.

参考文献/References:

[1] 苟晓霞，叶茂，汪亮亮，等.塔里木河上游河岸胡杨径向生长对温度的敏感性[J].干旱区研究，2018，35(4):899-904.
[2] 王文杰，孙伟，邱岭，等.不同时间尺度下兴安落叶松树干液流密度与环境因子的关系[J].林业科学，2012，48(1):77-85.
[3] Bai Y，Li X，Liu S，et al. Modelling diurnal and seasonal hysteresis phenomena of canopy conductance in an oasis forest ecosystem[J]. Agricultural and Forest Meteorology，2017，246:98-110.
[4] Granier A. Evaluation of transpiration in a Douglas-fir stand by means of sap flow measurements[J]. Tree Physiology，1987，3(4):309-320.
[5] Chen Y M，Cao Y. Response of tree regeneration and understory plant species diversity to stand density in mature Pinus tabulaeformis plantations in the hilly area of the Loess Plateau，China[J]. Ecological Engineering，2014，73:238-245.
[6] 张振振，杨轲嘉，顾宇璐，等.模拟降雨格局变化对亚热带地区两树种液流特征的影响[J].植物生态学报，2019，43(11):988-998.
[7] Granier A. Evaluation of transpiration in a Douglas-fir stand by means of sap flow measurements[J]. Agricultural and Forest Mete-Orology，1996，78:19-29.
[8] 朱雅娟，杜娟，吴彩霞，等.鄂尔多斯高原沙地柏液流通量及其影响因子[J].水土保持通报，2020，40(3):88-94.
[9] 潘迪，毕华兴，次仁曲西，等.晋西黄土区典型森林植被耗水规律与环境因子关系研究[J].北京林业大学学报，2013，35(4):16-20.
[10] 卢森堡，陈云明，唐亚坤，等.黄土丘陵区混交林中油松和沙棘树干液流对降雨脉冲的响应[J].应用生态学报，2017，28(11):3469-3478.
[11] Zhao W Z，Liu B. The response of sap flow in shrubs to rainfall pulses in the desert region of China[J]. Agricultural and Forest Meteorology，2010，150(9):1297-1306.
[12] Campbell，Gaylon J M，An introduction to environmental biophysics[J]. Biologia Plantarum，1998，21:104:1-286
[13] 吴旭，陈云明，唐亚坤，等.黄土丘陵区刺槐和侧柏人工林树干液流特征及其对降水的响应[J].植物生态学报，2015，39(12):1176-1187.
[14] 张慧玲，丁亚丽，陈洪松，等.出露基岩生境典型植物树干液流对自然降水和连续干旱的响应特征[J].应用生态学报，2018，29(4):1117-1124.
[15] Luo Z D，Guan H D，Zhang X P，et al. Responses of plant water use to a severe summer drought for two subtropical tree species in the central southern China[J]. Journal of Hydrology:Regional Studies，2016，8:1-9.
[16] 戴军杰，章新平，吕殿青，等.南方红壤丘陵区樟树林土壤水分动态变化[J].水土保持研究，2019，26(4):123-131.
[17] Kozlowski T T，Pallardy S G. Physiology of woody plants[M]. Amsterdam: Elsevier，1996:107-108.
[18] Melanie Z，Catriona M O，Macinnis N，et al. The response of sap flow to pulses of rain in a temperate Australian woodland[J]. Plant and Soil，2008，305(1/2):121-130.
[19] Dingman S L. Physical Hydrolog[M]. Illinois: Waveland Press，2015:28-86.
[20] Shin'ichi I，Nakatani S，Tanaka T. Evaluation of transpiration from a natural deciduous broad-leaved forest located at a headwater catchment based on meas-urement of sap flux density[J]. Journal of the Japan Society of Hydrology & Water Resources，2006，19:7-16.
[21] Kakubari Y，Hosokawa K，et al. Estimation of stand transpiration of a beech forest based on an eco-physiological computer simulation model and superporometer[J]. Journal of the Japanese Forestry Society，1992，74(4):263-272.
[22] Oren R，Zimmermann R，Terbough J. Transpiration in upper Amazonia floodplain and upland forests in response to drought-breaking rains[J]. Ecology，1996，77(3):968-973.
[23] Du S，Wang Y L，Kume T，et al. Sap flow characteristics and climatic responses in three forest species in the semiarid Loess plateau region of China[J]. Agricultural and Forest Meteorology，2011，151(1):1-10.
[24] 贾国栋，陈立欣，李瀚之，等.北方土石山区典型树种耗水特征及环境影响因子[J].生态学报，2018，38(10):3441-3452.
[25] 罗紫东，关华德，章新平，等.亚热带樟树树干液流通量变化规律[J].热带地理，2016，36(4):658-665.
[26] 孔喆，陈胜楠，律江，等.欧美杨单株液流昼夜组成及其影响因素分析[J].林业科学，2020，56(3):8-20.
[27] 韩磊，何俊，齐拓野，等.宁夏河东沙区侧柏冠层气孔导度对环境因子的响应及其模拟[J].生态学杂志，2018，37(9):2862-2868.
[28] 岳广阳，赵哈林，张铜会，等.不同天气条件下小叶锦鸡儿茎流及耗水特性[J].应用生态学报，2007，18(10):2173-2178.
[29] 杨强，查天山，贾昕，等.花棒茎流对降雨的响应[J].应用生态学报，2016，27(3):761-768.
[30] 吕金林，何秋月，闫美杰，等.黄土丘陵区辽东栎树干液流特征对边材面积和土壤水分的响应[J].应用生态学报，2018，29(3):725-731.
[31] 王媛，魏江生，周梅，等.大兴安岭南段白桦树干液流对土壤水分的响应[J].水土保持研究，2020，27(4):128-133.

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　ZHAO Kui,DING Guo-dong,YUAN Peng-fei,et al.A Research on Stem Sap Flow Dynamics of Ulmus Pumila in Mu Us Sandy Area, Yanchi County[J].Research of Soil and Water Conservation,2008,15(06):85.
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备注/Memo

收稿日期:2020-11-10 修回日期:2020-12-30
资助项目:国家自然科学基金(41571021); 湖南省人影办自立项科研课题(201901)
第一作者:夏银华(1995—)，女，安徽六安人，硕士研究生，研究方向为亚热带生态水文。E-mail:939973367@qq.com
通信作者:章新平(1956—)，男，湖南长沙人，教授，博士，博导，主要从事气候变化及水文研究。E-mail:zxp@hunnu.edu.cn

更新日期/Last Update: 2021-10-10