六盘山区华北落叶松林林木蒸腾对其主要影响因子的多时间尺度响应特征OA
Multi-Time Scale Response Characteristics of Tree Transpiration to Its Main Impact Factors in Larix gmelinii var.principis-rupprechtii Plantations in the Liupan Mountain Area
[目的]明确不同时间尺度林木蒸腾量对各主要影响因子的响应,精准量化小时和日尺度的林木蒸腾量,为精细化林分管理提供必要支撑.[方法]2023年生长季(5-10月),连续监测宁夏六盘山香水河小流域华北落叶松人工林树干液流变化,同步观测环境因子和林冠层叶面积指数(LAI),分析小时、日尺度和月尺度林木蒸腾量对主要影响因子的响应,建立反映多因子影响林木蒸腾量的模型,进而分析各因子对林木蒸腾量的相对贡献率.[结果]1)在日和小时尺度上,林木蒸腾量与太阳辐射(Rs)和饱和水气压差(VPD)均呈饱和指数函数关系,但在日尺度上林木蒸腾量开始减缓时对应的 Rs 和 VPD阈值约为小时尺度上 2个对应阈值的 1/3.林木日蒸腾量与土壤相对可利用水分(REW)也呈饱和指数函数关系,对 LAI的响应遵循"S"形逻辑斯蒂曲线.2)将响应函数耦合并通过实测数据率定,获得小时尺度的林木蒸腾量模型可通过气象因子较好预测小时尺度的林木蒸腾量(R2=0.80),获得日尺度的林木蒸腾量模型可通过气象因子、REW和 LAI较好预测林木日蒸腾量(R2=0.83).3)基于小时和日尺度林木蒸腾量模型的各因子蒸腾贡献率分析表明,小时尺度影响林木蒸腾量变化的主导因子在晴天为 VPD,在多云和阴天的夜间和早晨为 VPD,中午至下午为 Rs,而在雨天的夜间为 VPD、白天为 Rs;对于月尺度的林木蒸腾量变化,LAI在生长季始(5月)、末(10月)和生长旺季(7和 8月)起主导作用,气象因子在 6和 9月起主导作用,REW的相对贡献率在各月均相对较小.[结论]本研究建立的小时尺度林木蒸腾量响应 Rs 和 VPD以及日尺度林木蒸腾量响应 Rs、VPD、REW和 LAI的多因子耦合模型,能够较好预测小时和日尺度的林木蒸腾量,并进一步揭示出相同因子对林木蒸腾量的影响随时间尺度扩大并不是简单的叠加关系.本研究结果有助于深入理解林木蒸腾响应主导因子的时间尺度差异,为精细化林水管理提供理论基础,如在小尺度人工林抚育措施时,可根据目标时间尺度考虑对不同主导环境因子进行控制.
[Objective]As a key component of forest evapotranspiration,tree transpiration is primarily regulated by environmental factors such as meteorological conditions and soil moisture.However,its response patterns to these factors exhibit significant differences across temporal scales.A thorough understanding of these dynamics can provide support for the scaling-up estimation of field measurements and the precise regulation of forest-water relationships.[Method]A continuous monitoring of stem sap flow dynamics was conducted in a Larix gmelinii var.principis-rupprechtii plantation in the Xiangshuihe small watershed of the Liupan Mountains,Ningxia,during the 2023 growing season(May to October).Concurrently,environmental factors and canopy leaf area index(LAI)were observed.The responses of tree transpiration to the main influencing factors were analyzed at hourly,daily and monthly scales.A multi-factor transpiration model was established,and the relative contribution rates of each factor to tree transpiration were further quantified.[Result]1)Both daily and hourly tree transpiration rate showed a saturated exponential relationship with solar radiation(Rs)and vapor pressure deficit(VPD).However,the threshold values of Rs and VPD at which daily transpiration began to slow were approximately one-third of those at the hourly scale.Additionally,daily tree transpiration exhibited a saturated exponential relationship with relative extractable soil water(REW)and an"S"-shaped logistic curve in response to LAI.2)By coupling these response functions and calibrating them with measured data,the hourly scale transpiration model was able to predict hourly transpiration of trees by meteorological factors(R2=0.80),and the daily transpiration model was able to predict daily transpiration of trees by meteorological factors,REW and LAI(R2=0.83).3)Analysis of transpiration contribution rates from hourly and daily forest transpiration models revealed distinct patterns:On sunny days,VPD was the dominant factor affecting hourly transpiration variations.During cloudy and overcast conditions,VPD was the primary factor affecting hourly transpiration variations at night and morning,while Rs became the dominant factor affecting hourly transpiration variations from noon to afternoon.On rainy days,VPD was the main contributor at night and Rs during daytime.At the monthly scale,LAI was the dominant factor affecting transpiration changes at the beginning(May),end(October),and peak growth season(July-August)of the growing season,whereas meteorological factors took the lead in June and September.The relative contribution rate of REW remained relatively low throughout all months.[Conclusion]This study establishes a multi-factor coupling model integrating hourly tree transpiration responses(Rs and VPD)with daily transpiration responses(Rs,VPD,REW,and LAI).The model effectively predicts hourly and daily transpiration patterns,revealing that the combined effects of the same factors on transpiration do not simply add up across time scales.These findings contribute to a deeper understanding of the temporal scale differences in the response of forest transpiration to dominant factors and provide a theoretical basis for precise forest-water management.For example,in small-scale plantation tending practices,the control of different dominant environmental factors should be considered based on the target temporal scale.
蔡聆粤;刘泽彬;王云霓;王国蕊;王彦辉;于澎涛;徐丽宏;曲美学
中国林业科学研究院森林生态环境与自然保护研究所 国家林业和草原局森林生态环境重点实验室 北京 100091中国林业科学研究院森林生态环境与自然保护研究所 国家林业和草原局森林生态环境重点实验室 北京 100091内蒙古自治区林业科学研究院 沙地生物资源保护与培育国家林业和草原局重点实验室 呼和浩特 010010西安黄河环境信息工程有限公司 西安 710000中国林业科学研究院森林生态环境与自然保护研究所 国家林业和草原局森林生态环境重点实验室 北京 100091中国林业科学研究院森林生态环境与自然保护研究所 国家林业和草原局森林生态环境重点实验室 北京 100091中国林业科学研究院森林生态环境与自然保护研究所 国家林业和草原局森林生态环境重点实验室 北京 100091中国林业科学研究院森林生态环境与自然保护研究所 国家林业和草原局森林生态环境重点实验室 北京 100091
农业科技
华北落叶松林生物环境因子林木蒸腾时间尺度耦合模型
Larix gmelinii var.principis-rupprechtiibiotic environmental factorsforest transpirationtemporal scalecoupled model
《林业科学》 2026 (6)
15-26,12
国家自然科学基金项目(32171559,42477090,U20A2085)国家重点研发计划项目(2022YFF0801804).
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