北京城市公园人工林生态系统水分利用效率的季节变化

doi:10.11707/j.1001-7488.LYKX20210758

摘要/Abstract

摘要：

目的: 干旱、半干旱环境中人工林生态系统碳吸收与水分损失之间的平衡关系尚不明确，阐明森林生态系统水分利用效率（WUE）应对环境因子的响应机制有助于量化城市人工林碳、水通量的平衡关系。方法: 应用涡度协方差技术，结合微气象观测系统，获取北京奥林匹克森林公园内油松人工林生态系统碳、水通量和环境因子数据，运用统计和模拟方法，分析人工林碳、水通量在季节尺度的平衡关系以及在干旱、半干旱环境条件下碳吸收与水分损失之间的平衡关系。结果: 研究期2012—2014年降水少，均发生季节性土壤干旱情况，年降水量低于过去60年均值，且逐年降低，2014年降水总量仅271 mm。WUE年均值为2.2~2.9 g?kg^?1 ，2012年最小（2.2 g?kg^?1）、2013年最大（2.9 g?kg^?1）。生长季WUE主要受植被指数（NDVI）、净辐射（R_n）、气温（T_a）、土壤水分含量（SWC）和饱和水汽压差（VPD）的影响。在季节尺度，调控WUE的主要环境因子有所不同，春季NDVI的影响最大（P<0.05），可解释春季WUE变异的48%；夏季R_n和T_a的影响较强（P<0.05），可分别解释夏季WUE变异的52%和57%；秋季SWC和VPD的影响较强（P<0.05），可分别解释秋季WUE变异的44%和54%。在生长季，WUE和T_a呈线性负相关（P<0.01），WUE与VPD和R_n呈非线性负相关（对数曲线关系），WUE与SWC呈线性正相关（P<0.01）；然而在极端干旱月份，如2014年5、6和8月，WUE与SWC呈负相关（P<0.01），WUE降至最低。2012和2013年7月均出现连续无雨的干旱期，WUE达最低值3.7 g?kg^?1。相较而言，在生长季的连续降水期，随着SWC增加，WUE达最大值10.3 g?kg^?1。结论: 干旱、半干旱环境中人工林生态系统碳、水通量是相互耦合的，季节性干旱和炎热降低碳吸收量和水分损失量，导致WUE降低。生长季的干旱期，在T_a较高的环境下，随着SWC降低，WUE降至最低。在生长季不同气温条件影响下，人工林可利用的土壤有效水与干旱特性（干旱强度和持续时间）相结合共同影响生态系统碳、水通量的季节变化，从而导致人工林WUE应对干旱事件的年际响应差异。

关键词: 生态系统水分利用效率, 碳、水通量, 干旱, 人工林

Abstract:

Objective: The balance relationship between carbon absorption and water loss of plantation ecosystems under the arid and semi-arid environment conditions is poorly understood. The understanding of response mechanism of forest ecosystem water use efficiency (WUE) to environmental factors is useful for quantifying carbon and water balance of urban artificial forests. Method: Eddy covariance technology combined with micrometeorological sensors were used to monitor ecosystem carbon and water fluxes and environmental factors of Pinus tabuliformis plantation of Beijing Olympic Forest Park for years 2012—2014, and statistical and simulation methods were used to analyze balance relationship between carbon and water fluxes in plantation ecosystems at the seasonal scale. Result: All 3 years were dry years with little precipitation during the study period, resulting in seasonal soil drought. Annual precipitation values were all lower than the average of the past 60 years and decreased year by year, with total precipitation in year 2014 being only 271 mm. Annual WUE value were 2.2?2.9 g?kg^?1, with the lowest value being 2.2 g?kg^?1 in 2012 and the highest value being 2.9 g?kg^?1 in 2013. During the growing season, WUE was mainly influenced by vegetation index (NDVI), net radiation (R_n), temperature (T_a), soil moisture content (SWC), and saturated vapor pressure difference (VPD). Main environmental factors of seasonal WUE were changing as the following patterns. In spring, NDVI had the greatest impact on seasonal WUE, which explained 48% of spring variations in WUE (P<0.05); in summer, the influence of R_n and T_a had the greatest impacts on seasonal WUE, which explained 52% and 57% of summer variations in WUE, respectively (P<0.05); and in autumn, the influence of SWC and VPD had the greatest impacts on seasonal WUE, which explained 44% and 54% of autumn variations in WUE, respectively (P<0.05). During the growing season, WUE and T_a showed a linear negative correlation (P<0.01); WUE showed a non-linear negative correlation (i.e., logarithmic curve relationship) with VPD and R_n; and WUE showed a linear positive correlation with SWC (P<0.01). However, in extremely dry months, such as May, June, and August of the year 2014, WUE was negatively correlated with SWC (P<0.01), and WUE dropped to its lowest point. In July of years 2012 and 2013, there were consecutive dry periods without rain, and WUE values reached its lowest value of 3.7 g?kg^?1; while WUE values reached its maximum value of 10.3 g?kg^?1, as SWC being increasing, during the continuous precipitation period of the growing season. Conclusion: Carbon and water fluxes of plantation ecosystems under the arid and semi-arid environment conditions have coupled; and seasonal drought and heat have reduced carbon absorption and water loss, and thus, leading to a decrease in WUE. During the dry season of the growing season, in environmental conditions with high T_a, as SWC being decreasing, WUE value has dropped to its lowest level. The combination of available soil water and drought characteristics (i.e., drought intensity and duration) of plantation has affected the seasonal variations of ecosystem carbon and water fluxes, thereby affected the interannual response differences of plantation WUE to drought events, under different temperature conditions during the growing season.

Key words: ecosystem water use efficiency, carbon and water fluxes, drought, plantation

中图分类号:

S716
P414

谢静,张峰,周泽圆,于海群,韩艺,杨春欣,蒋薇,刘进祖,刘博恩,刘鹤. 北京城市公园人工林生态系统水分利用效率的季节变化[J]. 林业科学, 2024, 60(9): 12-17.

Jing Xie,Feng Zhang,Zeyuan Zhou,Haiqun Yu,Yi Han,Chunxin Yang,Wei Jiang,Jinzu Liu,Boen Liu,He Liu. Seasonal Variations in Water Use Efficiency of Plantation Ecosystem in an Urban Park of Beijing[J]. Scientia Silvae Sinicae, 2024, 60(9): 12-17.

图/表 4

参考文献 0

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年份 Year	WUE/(g?kg^?1)	P/mm	T_a/℃	SWC (%)
2012	2.2	738	12.9	15.5
2013	2.9	476	13.4	15.0
2014	2.6	271	15.0	12.4

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