轻度间伐对栓皮栎林茎干液流与林分蒸腾短期响应的影响

doi:10.11707/j.1001-7488.LYKX20250731

摘要/Abstract

摘要：

目的: 明确轻度间伐对栓皮栎林茎干液流和林分蒸腾动态的短期影响特征及其二者对环境因子的响应规律，以及对林木生长的作用，为栓皮栎林的水分管理和可持续经营提供理论依据。方法: 以豫西北太行山南麓30 年生栓皮栎林为研究对象，设置间伐和不间伐对照2种处理，采用热扩散探针法于2023年4—9月连续监测2种处理林木的液流速率，结合林木胸径、边材面积、林分密度等生物因子以及空气温度、相对湿度、太阳辐射、空气饱和水汽压差（VPD）等气象因子评估间伐对单株液流速率和林分蒸腾量的影响，并分析该影响与环境因子的关系。结果: 1）栓皮栎液流日变化曲线整体呈单峰型，除7月外，间伐未显著改变液流日动态的启动时间和峰值时刻。间伐林木液流速率在整个生长季明显高于不间伐，且该差异随季节变化呈先增大后降低的规律，表明间伐效应具有季节依赖性。2）间伐后液流速率对辐射（R²=0.52）和VPD（R²=0.42）的响应增强，表明林木液流对非生物因子驱动的敏感性呈增强趋势；辐射对液流速率变化的解释能力高于 VPD，反映研究区内栓皮栎液流变化可能更受光照变化的影响，而非主要受空气干燥程度的限制。3）液流速率与胸径无显著相关（P>0.05），表明在当前林分结构和土壤水分条件下，树木个体大小并非液流变化的主控因子。4）尽管间伐样地的林分总边材面积较不间伐样地减少约 27%，但其生长季蒸腾总量仍提高约 9%，这一变化可能与单木液流速率的升高有关。结论: 轻度间伐强度条件下，栓皮栎林分在短期内表现出液流和蒸腾增强的响应特征，对其水分利用过程具有潜在调节作用。本研究结果可为栓皮栎及其他落叶阔叶林水分调控与结构调控的协同优化提供科学依据。

关键词: 间伐, 液流, 栓皮栎, 蒸腾, 可持续经营

Abstract:

Objective: This study aims to clarify the short-term characteristics of sap flow and transpiration dynamics in Quercus variabilis stands under light thinning, as well as its impact on tree growth, so as to provide a theoretical basis for water management and sustainable management of Q. variabilis forests. Method: The 30-year-old Q. variabilis stands located on the southern foothills of the Taihang Mountains in northwestern Henan Province were subjected to two treatments of thinning and no thinning (control). From April to September 2023, sap flux density of trees under both treatments was continuously monitored using thermal dissipation probes. Tree-level biological factors (such as diameter at breast height, sapwood area, and stand density) and meteorological variables [including air temperature, relative humidity, solar radiation, and vapor pressure deficit (VPD)] were simultaneously recorded. With the above measurements, the effects of thinning on individual tree sap flux density and stand-scale transpiration were evaluated, and their relationships with environmental drivers were analyzed. Result: 1) The diurnal course of sap flux density in Q. variabilis exhibited a unimodal pattern. Except in July, thinning did not significantly alter the onset time or peak timing of the diurnal sap flux density dynamics. Sap flux density in thinned trees was consistently higher than that in unthinned trees throughout the growing season, and this difference first increased and then decreased with seasonal progression, indicating that the thinning effect was seasonally dependent. 2) After thinning, the explanatory power of radiation (R²=0.52) and VPD (R²=0.42) for sap flux density variation increased, indicating an increased sensitivity of sap flow to abiotic environmental drivers. The explanatory power of radiation on changes in for sap flux density was higher than that of VPD, suggesting that sap flux density in this region may be more strongly influenced by light-related processes rather than primarily constrained by atmospheric dryness. 3) There was no significant correlation between sap flux density and tree diameter (P>0.05), indicating that individual tree size was not the primary driver of sap flow variation under the current stand structure and soil moisture conditions. 4) Although the total sapwood area of the thinned stand was approximately 27% lower than that of the control, the seasonal total transpiration was still about 9% higher than that of the control, which may be associated with the increased sap flux density at the individual tree level. Conclusion: Under the light thinning intensity condition applied in this study, Q. variabilis stands exhibit enhanced sap flow and transpiration responses in the short term, indicating a potential regulatory effect on stand water use processes. These findings provide a scientific basis for the coordinated optimization of water regulation and structural adjustment in Q. variabilis and other deciduous broadleaf forests.

Key words: thinning, sap flux density, Quercus variabilis, transpiration, sustainable management

中图分类号:

王新建,张向阳,邓坦,李文博,王傲宇,王凯,陈昊,赵小宁. 轻度间伐对栓皮栎林茎干液流与林分蒸腾短期响应的影响[J]. 林业科学, 2026, 62(6): 132-141.

Xinjian Wang,Xiangyang Zhang,Tan Deng,Wenbo Li,Aoyu Wang,Kai Wang,Hao Chen,Xiaoning Zhao. Effects of Light Thinning on the Short-Term Response of Stem Sap Flow and Stand Transpiration in Quercus variabilis Stands[J]. Scientia Silvae Sinicae, 2026, 62(6): 132-141.

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样地类型 Plot type	海拔 Elevation/m	坡向 Aspect	坡度 Slope/(°)	平均胸径 Mean DBH/cm	平均树高 Mean height/m	林分密度 Stand density/(tree·hm^?2)
间伐样地Thinning plot	314	西West	28	15.6	13.4	783
不间伐样地Control plot	308	西West	30	16.5	15.3	900

样地类型Plot type	胸径DBH/cm
不间伐样地Control plot	16.7
	15.2
	14.5
	16.2
	16.0
	15.1
间伐样地Thinning plot	14.5
	16.8
	16.3
	15.5
	16.3
	14.9

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