川西亚高山暗针叶林降水分配过程中氧稳定同位素特征

doi:10.17521/cjpe.2006.0012

摘要/Abstract

摘要：

该文应用氧稳定同位素对四川卧龙巴朗山不同降雨条件下亚高山暗针叶林中降水、林冠穿透水和壤中流的变化动态进行了示踪,结果表明: 1)降水δ¹⁸O与林冠穿透水δ¹⁸O的差值(用Δ表示)随着日降雨量的增大呈现偏正态结构。降水量<3.20 mm时,Δ<0;当降水量≥3.20 mm时,Δ>0;且当降水量=12.65 mm时,Δ值最大。这是由当时冠层蒸散过程和降水过程相互作用决定的。 2)低降水强度、日平均降水量小和降水连续性差时,壤中流弱且不连续,导致壤中流的氧同位素组成对降水响应速度慢;反之,壤中流强且连续,导致壤中流对降水响应速度加快。当降水量在< 10 mm时,这种响应在降雨后4 d发生;当降水量在10~20 mm时,日平均降水量较大和连续降雨时,这种响应在降雨后2~3 d发生;当降水量在20~30 mm时,这种响应在降水1~2 d发生。发育良好的原始亚高山暗针叶林森林植被对降水分配进行着有效的调控,使得暗针叶林植被储备着不同时期降水、穿透水、壤中流及地下水组成的混合体,使壤中流变化滞后,从而控制植被下游洪水发生。

关键词: 氧稳定同位素, 暗针叶林, 降水分配, 四川

Abstract:

The stable oxygen isotope, δ¹⁸O, is a very useful tracer tool to study the impacts of forests on the water cycle. The Wolong Natural Reserve is a key conservation area focusing on the protection of Panda, rare animals and alpine ecosystems. The Wolong Natural Reserve is located in the Mingjiang River headwaters and plays an important role in the conservation of soil and water in this watershed as well as the upper reaches of the Yangtze River. Although much research has been conducted on the water cycle, including changes in precipitation intensity, rainfall frequency, runoff dynamics and subsurface flow, little has been devoted to understanding rainfall water allocation in sub-alpine dark coniferous forests. Using a stable oxygen isotope technique, we studied changes in precipitation, throughfall and soilwater flow over time under different rainfall intensities in three plots in a sub-alpine dark conifer forest. The results showed that 1) there were no significant differences between rainfall δ¹⁸O and daily precipitation (r=0.612, p≥0.05,n=20). There was a significant linear relationship between the rainfall δ¹⁸O and throughfall δ¹⁸O defined by the following equations for the three plots: plot A: y₁=0.970 6x₁-2.254 2,R₁²=0.796 2, p<0.05,F=42.97; plot B: y₂=0.997 6x₂-1.632 1,R₁²=0.729 7, p<0.05,F=29.60; plot C: y₃=0.920 3x₃-2.728 9,R₃²=0.729 7, p<0.05,F=26.47. 2) The δ¹⁸O exceeded 0 when precipitation ≥ 3.20 mm, and the maximum δ¹⁸O value occurred when precipitation was 12.65 mm due to the interactions between canopy evaporation and precipitation. 3) There was limited soil water flow when rainfall intensity, daily precipitation or rainfall continuity was low resulting in a slow response of the precipitation δ¹⁸O signature on soil water. When soil water flow was strong and continuous, the precipitations δ¹⁸O signature showed up rapidly in the soil water flow. The δ¹⁸O of soil water showed the same rise and fall patterns of the rainfall δ¹⁸O when precipitation was less than 10 mm, but with 4-day time lag. When precipitation was between 10 mm to 20 mm, the time lag in the increase in the soil water δ¹⁸O occurred 2-3 days after raining, and, when precipitation was from 20 mm to 30 mm, the time lag was only 1-2 days after the rain fall event. The well-developed sub-alpine dark coniferous forest could effectively regulate rainfall by delaying the time, and rainfall became part of the subsurface water flow that helping to prevent downstream flooding. There were no significant differences in the δ¹⁸O between rainfall and throughfall (p=0.491>0.05), but there were a signficant differences between throughfall and soil waterδ¹⁸O (p=0.025<0.05). These results suggest that soil water flow was not directly supplied by the current rainfall event but was supplemented by a pre-rainfall event.

Key words: Oxygen stable isotope, Dark coniferous forest, Precipitation allocation, Sichuan

徐庆, 刘世荣, 安树青, 蒋有绪, 王中生, 刘京涛. 川西亚高山暗针叶林降水分配过程中氧稳定同位素特征. 植物生态学报, 2006, 30(1): 83-89. DOI: 10.17521/cjpe.2006.0012

XU Qing, LIU Shi-Rong, AN Shu-Qing, JIANG You-Xu, WANG Zhong-Sheng, LIU Jing-Tao. ALLOCATION OF PRECIPITATION IN A SUB-ALPINE DARK CONIFEROUS FOREST OF WESTERN SICHUAN USING STABLE OXYGEN ISOTOPES. Chinese Journal of Plant Ecology, 2006, 30(1): 83-89. DOI: 10.17521/cjpe.2006.0012

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链接本文: https://www.plant-ecology.com/CN/10.17521/cjpe.2006.0012

https://www.plant-ecology.com/CN/Y2006/V30/I1/83

图/表 8

表1 四川卧龙亚高山暗针叶林3个样地群落特征和生境特点

Table 1 The characteristics of communities and habitats of sub-alpine dark coniferous forest of Wolong, Sichuan

样地 Plots	群落类型 Community types	海拔 Elevation (m)	地理位置 Location	坡度 Slope (°)	土壤特性 Soil characteristics	叶面积指数 Leaf area index	郁闭度 Canopy coverage (%)
A	岷江冷杉-箭竹群落 Abies faxoniana-Bshania angiana	2 750	30°51'21″ N, 102°58'19″ E	50	山地暗棕壤 Mountain dark brown forest soil	3.15	75
B	岷江冷杉-箭竹群落 Abies faxoniana-Bshania fangiana	2 850	30°51'16 N, 102°58'20″ E	35	山地棕色暗针叶林土 Mountain brown coniferous forest soil	4.56	85
C	岷江冷杉-杜鹃群落 Abies faxoniana- Rhododen faberi	2 950	30°51'20″ N, 102°58'22″ E	40	山地棕色暗针叶林土 Mountain brown coniferous forest soil	3.93	90

图1 降水δ18O与降水量随日期的变化

Fig.1 The change of rainfall δ18O and precipitation

图2 林冠穿透水δ18O与降水δ18O的相关性

Fig.2 The relationship between throughfall δ18O and rainfall δ18O

图3 降水δ18O与林冠穿透水δ18O的差值(Δ)随降水量的变化

Fig.3 The change of different value (Δ) between rainfall δ18O and throughfall δ18O with precipitation

图4 温度和湿度随降水量的变化

Fig.4 The change of temperature and humidity with precipitation

图5 降水量与林内3个群落中林冠穿透水量的关系

Fig.5 The relationship between precipitation and throughfall in three plots

图6 降水δ18O与壤中流δ18O随日期的变化

Fig.6 The change of rainfall δ18O and soilflow δ18O over time

表2 降水、穿透水及壤中流的δ18O 均值比较

Table 2 Mean difference δ18O of rainfall, thoughtfall and soil flow

δ¹⁸O	降水 Rainfall	穿透水 Throughfall	壤中流 Soilflow
降水 Rainfall	-	1.872 5	-0.794 8
穿透水 Throughfall	-1.872 5	-	-2.667 4^*
壤中流 Soil flow	0.794 8	2.667 4^*	-

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