Driving forces of the variations in sap flow inCotinus coggygria in Beijing
ZHANG Min1,2, QIAN Duo3, ZHANG Yong4, LI Xinhao1,2, LIU Peng1,2, ZHAO Hongxian1,2, LIU Xinyue1,2, XU Qingfeng1,2, ZHA Tianshan1,2
1. School of Soil and Water Conservation, Beijing Forestry University, 100083, Beijing, China; 2. State Key Laboratory of Efficient Production of Forest Resources, 100083, Beijing, China; 3. Beijing Vocational College of Agriculture, 102442, Beijing, China; 4. Beijing Ming Tombs Forest Farm, 102200, Beijing, China
Abstract:[Background] The water conservation function of a forest ecosystem is of great significance for sustainable development in a region. The transpiration of a plantation is an important component of forest water cycle and a key indicator reflecting the water conservation function of a forest. The measurement of sap flow can accurately estimate the process of a forest plantation. [Methods] Sap flow density of plantation species, Cotinus coggygria, was continuously measured in situ during the growing season from April to September in 2021 in Mangshan National Forest Park in Beijing using thermal diffusion method. Environmental factors including air temperature (Ta), relative humidity (RH), photosynthetically active radiation (PAR) and soil volumetric water content (VWC) were measured simultaneously. Besides, vapor pressure deficit (VPD) was calculated by substituting Ta and RH into the formula. This study examined the variations of sap flow density and environmental factors on the diurnal and seasonal scale, as well as analyzed the correlation between them via regression analysis and path analysis. [Results] The cumulative transpiration was 90 mm during the growing season. On the diurnal scale, sap flow density was mainly controlled by PAR, showing a positive correlation (R2 = 0.93), There was a time lag of 0.5 h between the peak values of sap flow density and PAR. On the seasonal scale, sap flow density was mainly regulated by VPD, and there was a threshold for this regulation at 1.5 kPa. When VPD is less than 1.5 kPa, the changes in sap flow density were directly related to VPD, showing a positive linear correlation between them (R2 = 0.94). When VPD is more than 1.5 kPa, the regulatory effect of VPD on sap flow density gradually weakened, while the regulatory effect of stomatal conductance (gs) on sap flow density increased, and gs had an exponential decline with the rise of VPD (R2 = 0.88). During the mid-growing season from June to August, sap flow density increased with the rise of Ta, VPD and PAR, but there was no significant relationship with VWC. [Conclusions] It is concluded that C. coggygri had the characteristics of lower water consumption,and its sap flow density was mainly controlled by PAR on the diurnal scale and was regulated by VPD on the seasonal scale. This species can adapt to atmospheric drought by regulating stomatal conductance. This study provides scientific basis for the species selection in developing forest plantations for soil and water conservation in Beijing.
郭勇,林超,李文君,等.海河流域水资源与水环境演变过程初探[C]. 2012中国环境科学学会学术年会论文集(第二卷).北京:中国农业大学出版社, 2012:300. GUO Yong, LIN Chao, LI Wenjun, et al. Preliminary study of the evolution of water resources and water environment in the Haihe river basin[C]. Proceedings of the 2012 Annual Symposium of the Chinese Society for Environmental Science (VolumeⅡ). Beijing:China Agricultural University Press, 2012:300.
[2]
李思静,查天山,秦树高,等.油蒿茎流动态及其环境控制因子[J].生态学杂志, 2014, 33(1):112. LI Sijing, ZHA Tianshan, QIN Shugao, et al. Temporal patterns and environmental controls of sap flow in Artemisia ordosica[J]. Chinese Journal of Ecology, 2014, 33(1):112.
[3]
李新宇,李延明,孙林,等.银杏蒸腾耗水与环境因子的关系研究[J].北京林业大学学报, 2014, 36(4):23. LI Xinyu, LI Yanming, SUN Lin, et al. Characteristics of transpiration water consumption and its relationship with environmental factors in Ginkgo biloba[J]. Journal of Beijing Forestry University, 2014, 36(4):23.
[4]
SUN Shoujia, MENG Ping, ZHANG Jinsong, et al. Partitioning oak woodland evapotranspiration in the rocky mountainous area of North China was disturbed by foreign vapor, as estimated based on non-steady-state 18O isotopic composition[J]. Agricultural and Forest Meteorology, 2014, 184:36.
[5]
任启文,毕君,李联地,等.冀北山地白桦全生长季树干液流特征[J].干旱区资源与环境, 2017, 31(11):169. REN Qiwen, BI Jun, LI Liandi, et al. Stem sap flow characteristic of Betula platyphylla during growth season in northern mountain areas of Hebei province[J]. Journal of Arid Land Resources and Environment, 2017, 31(11):169.
[6]
辛福梅,闫小莉,张长耀,等.西藏拉萨河谷区藏川杨和北京杨树干液流特征及其对环境因子的响应[J].林业科学, 2019, 55(2):22. XIN Fumei, YAN Xiaoli, ZHANG Changyao, et al. Characteristics of stem sap flow of two poplar species and their responses to environmental factors in Lhasa River Valley of Tibet[J]. Scientia Silvae Sinicae, 2019, 55(2):22.
[7]
马玉洁,李春友,武鹏飞,等.基于实测白榆蒸腾速率校正计算液流速率的Granier原始公式[J].林业科学, 2020, 56(6):179. MA Yujie, LI Chunyou, WU Pengfei, et al. Correction of Granier's original formula coefficient for calculating sap flow based on the measured transpiration rate of Ulmus pumila[J]. Scientia Silvae Sinicae, 2020, 56(6):179.
[8]
马长明,张含含,韩煜,等. Granier原始公式测算107杨树干液流通量密度的误差及校正公式[J].林业科学, 2021, 57(3):161. MA Changming, ZHANG Hanhan, HAN Yu, et al. Error and correction formula of Granier's original formula to calculate the stem sap flux density of clone 107 poplar[J]. Scientia Silvae Sinicae, 2021, 57(3):161.
[9]
郝少荣,裴志永,段广东,等.不同时间尺度下环境因子与沙柳茎流关系的差异研究[J].干旱区资源与环境, 2020, 34(3):152. HAO Shaorong, PEI Yongzhi, Duan Guangdong, et al. Relationships between environmental factors and Salix psammophila爷s sap flow at different time scales[J]. Journal of Arid Land Resources and Environment,2020, 34(3):152.
[10]
TIE Qiang, HU Hongchang, TIAN Fuqiang, et al. Environmental and physiological controls on sap flow in a subhumid mountainous catchment in North China[J]. Agricultural and Forest Meteorology, 2017, 240:46.
[11]
铁强.华北土石山区林地蒸散发机理研究[D].北京:清华大学, 2018:8. TIE Qiang. Mechanism research on the forest evapotranspiration in the Earth-Rock Mixed Mountainous Region of North China[D]. Beijing:Tsinghua University, 2018:8.
[12]
NOVICK A K, FICKLIN L D, STOY C P, et al. The increasing importance of atmospheric demand for ecosystem water and carbon fluxes[J]. Nature Climate Change, 2016, 6(11):1023.
[13]
韩春,陈宁,孙杉,等.森林生态系统水文调节功能及机制研究进展[J].生态学杂志, 2019, 38(7):2191. HAN Chun, CHEN Ning, SUN Shan, et al. A review on hydrological mediating functions and mechanisms in forest ecosystems[J]. Chinese Journal of Ecology, 2019, 38(7):2191.
[14]
JIAO Lei, LU Nan, FANG Weiwei, et al. Determining the independent impact of soil water on forest transpiration:A case study of a black locust plantation in the Loess Plateau, China[J]. Journal of Hydrology, 2019, 572:671.
[15]
孙旭,杨文慧,焦磊,等.不同时间尺度北京蟒山油松树干液流对环境因子的响应[J].生态学报, 2022, 42(10):4113. SUN Xu, YANG Wenhui, JIAO Lei, et al. Relationships between sapflux density of Pinus tabuliformis trees and environmental factors at different temporal scales in Mangshan National Forest Park of Beijing, China[J]. Scientia Silvae Sinicae, 2022,42(10):4113.
[16]
张凯,孙艳丽,隗骥超,等.北京山区大果榆树干液流的季节与昼夜环境调控[J].林业科学, 2023, 59(7):24. ZHANG Kai, SUN Yanli, KUI Jichao, et al. Control of environmental factors on the sap flow at daily and seasonal scales in Ulmus macrocarpa in Beijing, China[J]. Scientia Silvae Sinicae, 2023, 59(7):24.
[17]
贾天宇,刘廷玺,段利民,等.半干旱沙丘草甸过渡带人工杨树蒸腾耗水规律[J].生态学杂志, 2020, 39(10):3255. JIA Tianyu, LIU Tingxi, DUAN Limin, et al. Transpiration and water consumption of poplar trees in semi-arid dune meadow transition zone[J]. Chinese Journal of Ecology, 2020, 39(10):3255.
[18]
林琳,蔡国军,莫保儒,等.半干旱黄土区山毛桃树干液流变化特征及其与环境因子的相关分析[J].西北林学院学报, 2023, 38(4):18. LIN Lin, CAI Guojun, MO Baoru, et al. Characteristics of sap flow and correlation analysis with environmental factors of Prunus davidiana in semiarid loess area[J]. Journal of Northwest Forestry University, 2023, 38(4):18.
[19]
党宏忠,张劲松,赵雨森.应用热扩散技术对柠条锦鸡儿主根液流速率的研究[J].林业科学, 2010, 46(3):29. DANG Hongzhong, ZHANG Jinsong, ZHAO Yusen. Application of the thermal dissipation probe technique in studying the sap flow in taproot of Caragana korshinskii[J]. Scientia Silvae Sinicae, 2010, 46(3):29.
[20]
李海龙,李端亮.黄栌属植物研究进展[J].陕西林业科技, 2009(6):22. LI Hailong, LI Duanliang. Advances in studies on genus Cotinus (Tourn·) Mill[J]. Shaanxi Forest Science and Technology, 2009(6):22.
[21]
刘春鹏,翟明普,马长明,等.华北石质山区4种乡土树种耗水特征[J].东北林业大学学报, 2010, 38(7):29. LIU Chunpeng, ZHAI Mingpu, MA Changming, et al. Water consumption characteristics of four native tree species in the rocky mountain area of North China[J]. Journal of Northeast Forestry University, 2010, 38(7):29.
[22]
周平,李吉跃,招礼军.北方主要造林树种苗木蒸腾耗水特性研究[J].北京林业大学学报, 2002, 24(5/6):50. ZHOU Ping, LI Jiyue, ZHAO Lijun. Characteristics of seedlings water consumption by transpiration of main afforestation tree species in north China[J]. Journal of Beijing Forestry University, 2002, 24(5/6):50.
[23]
杨新兵.华北土石山区典型人工林优势树种及群落耗水规律研究[D].北京:北京林业大学, 2007:29. YANG Xinbing. Study on the rules of water consumption of dominant tree species and the community of artificial forest in Mountain Area of northern China[D]. Beijing:Beijing Forestry University, 2007:29.
[24]
王瑞辉,马履一.北京15种园林树木耗水性的比较研究[J].中南林业科技大学学报, 2009, 29(4):16. WANG Ruihui, MA L俟yi. Comparative research of water consumption from 15 garden tree species in Beijing[J]. Journal of Central South University of Forestry&Technology, 2009, 29(4):16.
[25]
何春霞,张劲松,孟平,等. 2018.太行山南麓3种常见灌木的水分利用特性[J].林业科学, 2018, 54(9):137. HE Chunxia, ZHANG Jinsong, MENG Ping, et al. Water use strategies of three native shrubs in the southern Taihang Mountain[J]. Scientia Silvae Sinicae, 2018, 54(9):137.
[26]
GRANIER A. Evaluation of transpiration in a Douglas-fir stand by means of sap flow measurements[J]. Tree Physiology, 1987, 3(4):309.
[27]
GRANIER A, BIRON P, LEMOINE D. Water balance, transpiration and canopy conductance in two beech stands[J]. Agricultural and Forest Meteorology, 2000, 100(4):291.
[28]
RICHARD P L, PATRICK F, DAVID F C, et al. Quantification of uncertainties in conifer sap flow measured with the thermal dissipation method[J]. The New phytologist, 2018, 219(4):1283.
[29]
李鑫豪,田文东,李润东,等.北京松山落叶阔叶林生态系统水热通量对环境因子的响应[J].植物生态学报,2021, 45(11):1191. LI Xinhao, TIAN Wendong, LI Rundong, et al. Responses of water vapor and heat fluxes to environmental factors in a deciduous broadleaved forest ecosystem in Beijing[J]. Chinese Journal of Plant Ecology, 2021, 45(11):1191.
[30]
REICHSTEIN M, FALGE E, BALDOCCHI D, et al. On the separation of net ecosystem exchange into assimilation and ecosystem respiration:Review and improved algorithm[J]. Global Change Biology, 2005, 11(9):1424.
[31]
CLEARWATER M J, MEINZER F C, ANDRADE J L, et al. Potential errors in measurement of nonuniform sap flow using heat dissipation probes[J]. Tree Physiology, 1999, 19(10):681.
[32]
LU Ping, URBAN L, ZHAO Ping. Granier爷s thermal dissipation probe (TDP) method for measuring sap flow in trees:Theory and practice[J]. Acta Botanica Sinica, 2004, 46(6):631.
[33]
温杰,陈云明,唐亚坤,等.黄土丘陵区油松、沙棘生长旺盛期树干液流密度特征及其影响因素[J].应用生态学报, 2017, 28(3):763. WEN Jie, CHEN Yunming, TANG Yakun, et al. Characteristics and affecting factors of sap flow density of Pinus tabuliformis and Hippophae rhamnoides in growing season in the hilly region of the Loess Plateau, China[J]. Chinese Journal of Applied Ecology, 2017, 28(3):763.
[34]
BRITO P, LORENZO R J, GONZÁLEZ-RODRÍGUEZ MÁ, et al. Canopy transpiration of a semi arid Pinus canariensis forest at a treeline ecotone in two hydrologically contrasting years[J]. Agricultural and Forest Meteorology, 2015, 201:120.
[35]
WANG Ben, ZHA Tianshan, JIA Xin, et al. Soil moisture modifies the response of soil respiration to temperature in a desert shrub ecosystem[J]. Biogeosciences, 2014, 11(2):259.
[36]
ZHA Tianshan, QIAN Duo, JIA Xin, et al. Soil moisture control of sap-flow response to biophysical factors in a desert-shrub species, Artemisia ordosica[J]. Biogeosciences, 2017,14(19):4533.
[37]
HAYAT M, ZHA Tianshan, JIA Xin, et al. A multipletemporal scale analysis of biophysical control of sap flow in Salix psammophila growing in a semiarid shrubland ecosystem of northwest China[J]. Agricultural and Forest Meteorology, 2020, 288.
[38]
BALDOCCHI D D, WILSON K B, GU Lianhong. How the environment, canopy structure and canopy physiological functioning influence carbon, water and energy fluxes of a temperate broad-leaved deciduous forest:An assessment with the biophysical model CANOAK. Tree Physiology, 2002, 22(15/16):1065.
[39]
许庭毓,牛香,王兵,等.不同土壤水分条件下杉木种源树干液流特征对气象因子的响应[J].中国水土保持科学, 2023, 21(5):99. XU Tingyu, NIU Xiang, WANG Bing, et al. Responses of sap flow characteristics under different Chinese fir provenances to meteorological factors under different soil moisture conditions[J]. Science of Soil and Water Conservation, 2023, 21(5):99.
[40]
OUYANG Zutao, CHEN Jiquan, BECKER R, et al. Disentangling the confounding effects of PAR and air temperature on net ecosystem exchange at multiple time scales[J]. Ecological Complexity, 2014, 19(9):46.
[41]
韩辉,张学利,党宏忠,等.科尔沁沙地南缘樟子松林蒸腾强度的年际变化及与降水、地下水位间的关系[J].林业科学, 2020, 56(11):31. HAN Hui, ZHANG Xueli, DANG Hongzhong, et al. Inter-annual variation of transpiration intensity of Pinus sylvestris var. mongolica stand on the southern margin of Horqin Sandy Land and its relationship with precipitation and groundwater level[J]. Scientia Silvae Sinicae, 2020, 56(11):31.
[42]
IQBAL S, ZHA Tianshan, JIA Xin, et al. Interannual variation in sap flow response in three xeric shrub species to periodic drought[J]. Agricultural and Forest Meteorology, 2021, 297(4):108276.
[43]
王慧梅,孙伟,祖元刚,等.不同环境因子对兴安落叶松树干液流的时滞效应复杂性及其综合影响[J].应用生态学报, 2011, 22(12):3109. WANG Huimei, SUN Wei, ZU Yuangang, et al. Complexity and its integrative effects of the time lags of environment factors affecting Larix gmelinii stem sap flow[J]. Chinese Journal of Applied Ecology, 2011, 22(12):3109.
[44]
MATHENY A M, BOHRER G, VOGEL C S, et al. Species-specific transpiration responses to intermediate disturbance in a northern hardwood forest[J]. Journal of Geophysical Research-Biogeosciences, 2014, 119(12):2292.
2024, Vol. 22 
