基于液流径向变化的樟子松蒸腾耗水量估算及影响因素
- 1沈阳农业大学林学院, 沈阳 110866
2辽宁辽河平原森林生态系统国家定位观测研究站, 辽宁昌图 112500
3辽宁省林业发展服务中心, 沈阳 110036
4大连大学生命健康学院, 辽宁大连 116622
收稿日期: 2023-05-04
录用日期: 2024-06-20
网络出版日期: 2024-06-24
基金资助
中国科学院战略性先导科技专项(XDA23070103);国家林业和草原局林草科技创新平台运行补助项目(2020132029);国家林业和草原局林草科技创新平台运行补助项目(2021132053)
Transpiration estimates in Pinus sylvestris var. mongolica plantation based on the radial pattern of sap flow and its influencing factors
- TONG Yu-Qiang ,
- WU Meng-Ge ,
- WANG Ling ,
- ZHAO Shi ,
- HAN Xu ,
- ZHANG Tong ,
- LIU Jing ,
- QIN Sheng-Jin ,
- DONG Ying-Hao ,
- WEI Ya-Wei ,
- ZHOU Yong-Bin
- 1College of Forestry, Shenyang Agricultural University, Shenyang 110866, China
2Research Station of Liaohe-River Plain Forest Ecosystem, Chinese Forest Ecosystem Research Network, Changtu, Liaoning 112500, China
3Liaoning Forestry Development Service Center, Shenyang 110036, China
4College of Life and Health, Dalian University, Dalian, Liaoning 116622, China
Received date: 2023-05-04
Accepted date: 2024-06-20
Online published: 2024-06-24
Supported by
Strategic Priority Research Program of the Chinese Academy of Sciences(XDA23070103);National Forestry and Grassland Administration Project of Forestry and Grassland Science and Technology Innovation Platform Operation Subsidy(2020132029);National Forestry and Grassland Administration Project of Forestry and Grassland Science and Technology Innovation Platform Operation Subsidy(2021132053)
摘要
樟子松(Pinus sylvestris var. mongolica)是辽西北半干旱区主要的人工林造林树种, 准确估算其蒸腾耗水量对樟子松人工林的科学管理具有重要意义。该研究采用基于多点(不同规格) TDP探针研究30年生樟子松树干液流的径向变化特征及其对树木蒸腾耗水量的影响。结果表明: 樟子松树干液流在径向上存在较大的差异且随着季节的变化径向模式也会发生变化。在8月, 樟子松树干液流呈现明显的单峰径向模式, 在距最外侧边材15 mm处达到峰值, 而在10月, 樟子松径向模式表现出较大的差异, 从边材的外侧到心材逐渐下降。基于液流径向变化, 估算出30年生樟子松在8月和10月日蒸腾量分别在25.32-27.45和14.05-16.49 kg之间, 其中, 边材外侧0-20 mm的蒸腾量占据了整株蒸腾量的绝大部分。通过单点估算樟子松整株蒸腾量会产生较大误差, 误差最高可达133.22%。樟子松各深度(5、15、25 mm)的液流通量密度之间存在显著的关联性, 每个深度的液流通量密度与基于边材面积加权平均的液流通量密度之间的线性方程拟合度较好, 通过转换方程可以达到使用单点来估算整株蒸腾量的目的。光合有效辐射对樟子松各深度的液流影响最大, 但不同深度的液流对气象因素的响应程度不同, 因此不能以单深度的液流通量密度受气象因素的影响程度来预估气象因素对整株蒸腾耗水量的影响。
本文引用格式
童郁强 , 吴梦鸽 , 王玲 , 赵实 , 韩叙 , 张彤 , 刘静 , 秦胜金 , 董英豪 , 魏亚伟 , 周永斌 . 基于液流径向变化的樟子松蒸腾耗水量估算及影响因素[J]. 植物生态学报, 2024 , 48(9) : 1118 -1127 . DOI: 10.17521/cjpe.2023.0121
Abstract
Aims Pinus sylvestris var. mongolica is one of the key afforestation species in the semi-arid region of western Liaoning Province. Precise estimation of its transpiration is crucial for the scientific management of these plantations.
Methods This study utilized multi-point TDP probes with different probe sizes to examine the radial pattern of sap flow in 30-year-old P. sylvestris var. mongolica on sandy terrain, and to explain the factors affecting transpiration.
Important findings Results revealed significant differences in the radial pattern of sap flow within the plantation, which also varied across seasons. In August, the sap flow exhibited a distinct unimodal radial pattern, peaking at 15 mm depth from sapwood. However, in October, the radial pattern showed a significant difference, presenting a gradual decline from the outer sapwood towards the heartwood. Based on radial sap flow changes, the daily transpiration of 30-year-old P. sylvestris var. mongolica in August and October was estimated to be between 25.32-27.45 and 14.05-16.49 kg, respectively. The transpiration from the outer 0-20 mm of the sapwood accounted for a substantial majority of the whole tree’s transpiration. Estimation of the entire P. sylvestris var. mongolica transpiration based on a single point could lead to significant errors, with the highest error reaching up to 133.22%. There was a notable correlation between sap flux densities at different depths (5, 15, 25 mm) out of sapwood, and a satisfactory linear fit was observed between sap flux density at various depths and weighted mean sap flux density on a sapwood area basis. Thus, a single-point estimation of individual tree transpiration can be achieved using conversion equations. The most significant effect on sap flow at different depths in P. sylvestris var. mongolica was from photosynthetically active radiation. However, the response degree of sap flow at different depths to meteorological factors were different, implying that meteorological influences on whole-tree transpiration cannot be predicted based on the impacts at a single depth.
参考文献
| [1] | Alvarado-Barrientos MS, Hernández-Santana V, Asbjornsen H (2013). Variability of the radial profile of sap velocity in Pinus patula from contrasting stands within the seasonal cloud forest zone of Veracruz, Mexico. Agricultural and Forest Meteorology, 168, 108-119. |
| [2] | Asbjornsen H, Goldsmith GR, Alvarado-Barrientos MS, Rebel K, van Osch FP, Rietkerk M, Chen J, Gotsch S, Tobón C, Geissert DR, Gómez-Tagle A, Vache K, Dawson TE (2011). Ecohydrological advances and applications in plant-water relations research: a review. Journal of Plant Ecology, 4, 3-22. |
| [3] | Berdanier AB, Miniat CF, Clark JS (2016). Predictive models for radial sap flux variation in coniferous, diffuse-porous and ring-porous temperate trees. Tree Physiology, 36, 932-941. |
| [4] | Bodo AV, Arain MA (2021). Radial variations in xylem sap flux in a temperate red pine plantation forest. Ecological Processes, 10, 24. DOI: 10.1186/s13717-021-00295-4. |
| [5] | Cao GX, Wang YN, Guo Z, Ji M, Wang YH, Xu LH (2020). Responses of transpiration to variation in evaporative demands and soil water in a larch plantation at the south side of Liupan Mountains, China. Chinese Journal of Applied Ecology, 31, 3376-3384. |
| [曹恭祥, 王云霓, 郭中, 季蒙, 王彦辉, 徐丽宏 (2020). 六盘山南侧华北落叶松人工林蒸腾对土壤水分和潜在蒸散的响应. 应用生态学报, 31, 3376-3384.] | |
| [6] | Chang XX, Zhao WZ, He ZB (2014). Radial pattern of sap flow and response to microclimate and soil moisture in Qinghai spruce (Picea crassifolia) in the upper Heihe River Basin of arid northwestern China. Agricultural and Forest Meteorology, 187, 14-21. |
| [7] | Chen B, Chen LX, Liu QQ, Liu PS, Zhang ZQ (2015). Transpiration of Pinus sylvestris var. mongolica and its response to urban environmental factors in semi-arid area. Acta Ecologica Sinica, 35, 5076-5084. |
| 陈彪, 陈立欣, 刘清泉, 刘平生, 张志强 (2015). 半干旱地区城市环境下樟子松蒸腾特征及其对环境因子的响应. 生态学报, 35, 5076-5084.] | |
| [8] | Dang HZ, Feng JC, Han H (2020). Characteristics of azimuthal variation of sap flux density in Pinus sylvestris var. mongolica grown in sandy land. Scientia Silvae Sinicae, 56(1), 29-37. |
| 党宏忠, 冯金超, 韩辉 (2020). 沙地樟子松边材液流速率的方位差异特征. 林业科学, 56(1), 29-37.] | |
| [9] | Dang HZ, Han H, Chen S, Li MY (2021). A fragile soil moisture environment exacerbates the climate change- related impacts on the water use by Mongolian Scots pine (Pinus sylvestris var. mongolica) in northern China: long-term observations. Agricultural Water Management, 251, 106857. DOI: 10.1016/j.agwat.2021.106857. |
| [10] | Dang HZ, Que XE, Feng JC, Wang MM, Zhang JX (2019). Response of sap flow rate of apple trees to environmental factors in Loess Platea of Western Shanxi Province, China. Chinese Journal of Applied Ecology, 30, 823-831. |
| 党宏忠, 却晓娥, 冯金超, 王檬檬, 张金鑫 (2019). 晋西黄土区苹果树边材液流速率对环境驱动的响应. 应用生态学报, 30, 823-831.] | |
| [11] | Dang HZ, Zha TS, Zhang JS, Li W, Liu SZ (2014). Radial profile of sap flow velocity in mature Xinjiang poplar (Populus alba L. var. pyramidalis) in Northwest China. Journal of Arid Land, 6, 612-627. |
| [12] | Du MG, Wang SJ, Fan J, Ge HY (2022). Low sap flow of Picea crassifolia and its influencing factors in Qilian Mountains, China. Chinese Journal of Applied Ecology, 33, 931-938. |
| [杜梦鸽, 王善举, 樊军, 葛红元 (2022). 祁连山青海云杉低液流特征及其影响因素. 应用生态学报, 33, 931-938.] | |
| [13] | Eliades M, Bruggeman A, Djuma H, Lubczynski MW (2018). Tree water dynamics in a semi-arid, Pinus brutia forest. Water, 10, 1039. DOI: 10.3390/w10081039. |
| [14] | Fan J, Guyot A, Ostergaard KT, Lockington DA (2018). Effects of earlywood and latewood on sap flux density-based transpiration estimates in conifers. Agricultural and Forest Meteorology, 249, 267-274. |
| [15] | Ford CR, Hubbard RM, Kloeppel BD, Vose JM (2007). A comparison of sap flux-based evapotranspiration estimates with catchment-scale water balance. Agricultural and Forest Meteorology, 145, 176-185. |
| [16] | Ford CR, McGuire MA, Mitchell RJ, Teskey RO (2004). Assessing variation in the radial profile of sap flux density in Pinus species and its effect on daily water use. Tree Physiology, 24, 241-249. |
| [17] | Granier A (1987). Evaluation of transpiration in a Douglas-fir stand by means of sap flow measurements. Tree Physiology, 3, 309-320. |
| [18] | Granier A, Huc R, Barigah ST (1996). Transpiration of natural rain forest and its dependence on climatic factors. Agricultural and Forest Meteorology, 78, 19-29. |
| [19] | Hatton TJ, Catchpole EA, Vertessy RA (1990). Integration of sap flow velocity to estimate plant water use. Tree Physiology, 6, 201-209. |
| [20] | Hayat M, Zha T, Jia X, Iqbal S, Qian D, Bourque CPA, Khan A, Tian Y, Bai Y, Liu P, Yang R (2020). A multiple- temporal scale analysis of biophysical control of sap flow in Salix psammophila growing in a semiarid shrubland ecosystem of Northwest China. Agricultural and Forest Meteorology, 288-289, 107985. DOI: 10.1016/j.agrformet.2020.107985. |
| [21] | Hernandez-Santana V, Fernández JE, Rodriguez-Dominguez CM, Romero R, Diaz-Espejo A (2016). The dynamics of radial sap flux density reflects changes in stomatal conductance in response to soil and air water deficit. Agricultural and Forest Meteorology, 218- 219, 92-101. |
| [22] | Korakaki E, Fotelli MN (2021). Sap flow in aleppo pine in greece in relation to sapwood radial gradient, temporal and climatic variability. Forests, 12, 2. DOI: 10.3390/f12010002. |
| [23] | Kume T, Otsuki K, Du S, Yamanaka N, Wang Y, Liu G (2012). Spatial variation in sap flow velocity in semiarid region trees: its impact on stand-scale transpiration estimates. Hydrological Process, 26, 1161-1168. |
| [24] | Link RM, Fuchs S, Arias Aguilar DA, Leuschner C, Castillo Ugalde MC, Valverde Otarola JCV, Schuldt B (2020). Tree height predicts the shape of radial sap flow profiles of Costa-Rican tropical dry forest tree species. Agricultural and Forest Meteorology, 287, 107913. DOI: 10.1016/j.agrformet.2020.107913. |
| [25] | Nadezhdina N, ?ermák J, Ceulemans RJ (2002). Radial patterns of sap flow in woody stems of dominant and understory species: scaling errors associated with positioning of sensors. Tree Physiology, 22, 907-918. |
| [26] | Oren R, Phillips N, Ewers BE, Pataki DE, Megonigal JP (1999). Sap-flux-scaled transpiration responses to light, vapor pressure deficit, and leaf area reduction in a flooded Taxodium distichum forest. Tree Physiology, 19, 337-347. |
| [27] | Qin HP, Liu ZB, Guo JB, Wang YH, Yu SP, Wang L (2021). Effects of environment and canopy structure on stem sap flow in a Larix principis-rupprechtii plantation. Chinese Journal of Applied Ecology, 32, 1681-1689. |
| [秦颢萍, 刘泽彬, 郭建斌, 王彦辉, 于松平, 王蕾 (2021). 环境和冠层结构对华北落叶松林树干液流的影响. 应用生态学报, 32, 1681-1689.] | |
| [28] | Schneider T, Teixeira J, Bretherton C, Brient F, Pressel KG, Sch?r C, Siebesma AP (2017). Climate goals and computing the future of clouds. Nature Climate Change, 7, 3-5. |
| [29] | Shinohara Y, Iida S, Oda T, Katayama A, Tsuruta K, Sato T, Tanaka N, Su M, Laplace S, Kijidani Y, Kume T (2022). Are calibrations of sap flow measurements based on thermal dissipation needed for each sample in Japanese cedar and cypress trees. Trees, 36, 1219-1229. |
| [30] | Urban J, Rubtsov AV, Urban AV, Shashkin AV, Benkova VE (2019). Canopy transpiration of a Larix sibirica and Pinus sylvestris forest in Central Siberia. Agricultural and Forest Meteorology, 271, 64-72. |
| [31] | Wei Z, Yoshimura K, Wang L, Miralles DG, Jasechko S, Lee X (2017). Revisiting the contribution of transpiration to global terrestrial evapotranspiration. Geophysical Research Letters, 44, 2792-2801. |
| [32] | William H, Schlesinger SJ (2014). Transpiration in the global water cycle. Agricultural and Forest Meteorology, 189- 190, 115-117. |
| [33] | Wilson KB, Hanson PJ, Mulholland PJ, Baldocchi DD, Wullschleger SD (2001). A comparison of methods for determining forest evapotranspiration and its components: sap-flow, soil water budget, eddy covariance and catchment water balance. Agricultural and Forest Meteorology, 2, 153-168. |
| [34] | Xu F, Yang FT, Wang HM, Dai XQ (2012). Review of advances in radial patterns of stem sap flow. Chinese Journal of Plant Ecology, 36, 1004-1014. |
| [徐飞, 杨风亭, 王辉民, 戴晓琴 (2012). 树干液流径向分布格局研究进展. 植物生态学报, 36, 1004-1014.] | |
| [35] | Zhang J, He Q, Shi W, Otsuki K, Yamanaka N, Du S (2015). Radial variations in xylem sap flow and their effect on whole-tree water use estimates. Hydrological Process, 29, 4993-5002. |
| [36] | Zhang L, Sun PS, Liu SR (2009). A review on water use responses of tree/forest stand to environmental changes by using sap flow techniques. Acta Ecologica Sinica, 29, 5600-5610. |
| [张雷, 孙鹏森, 刘世荣 (2009). 树干液流对环境变化响应研究进展. 生态学报, 29, 5600-5610.] | |
| [37] | Zhao CY, Si JH, Feng Q, Yu TF, Li W (2015). Stem sap flow research: progress and prospect. Journal of Northwest Forestry University, 30(5), 98-105. |
| [赵春彦, 司建华, 冯起, 鱼腾飞, 李炜 (2015). 树干液流研究进展与展望. 西北林学院学报, 30(5), 98-105.] | |
| [38] | Zhao FF, Ma X, Di N, Wang Y, Liu Y, Li GD, Jia LM, Xi BY (2020). Azimuthal variation in nighttime sap flow and its mainly influence factors of Populus tomentosa. Chinese Journal of Plant Ecology, 44, 864-874. |
| [赵飞飞, 马煦, 邸楠, 王烨, 刘洋, 李广德, 贾黎明, 席本野 (2020). 毛白杨茎干不同方位夜间液流变化规律及其主要影响因子. 植物生态学报, 44, 864-874.] |