模拟干旱条件下晋西黄土区刺槐林土壤水分运移特征

doi:10.11707/j.1001-7488.LYKX20250247

摘要/Abstract

摘要：

目的: 季节性干旱是限制林木生长的重要因素，林木高强度水分利用易引发土壤干层问题。在模拟干旱条件下，探究晋西黄土区刺槐人工林土壤水分运移特征，为基于水分条件的植被恢复提供理论支撑。方法: 在晋西黄土区选择20年生刺槐人工林作为观测地，设置对照（保持原状）、干旱（减少50%降水）、极端干旱（减少100%降水）3个梯度的原位控制试验，运用烘干法、土壤张力计法测定刺槐人工林在降水后次日9点及典型晴天的土壤含水量、土壤水势，结合零通量面法探究不同干旱梯度下刺槐人工林土壤水分运移特征。结果: 1）在对照样地，暴雨事件使0~60 cm土层土壤含水量增加，增幅随土壤深度增加而递减，其中0~10 cm土层的雨后含水量达32.42%±8.63%，增幅为60.4%；中雨和小雨事件使0~50 cm土层土壤含水量增加，深层（>60 cm）土壤含水量无明显响应。在干旱样地，浅层（0~30 cm）土壤含水量的雨后增幅有限（暴雨后峰值12.25%±3.51%）；极端干旱样地的土壤含水量无变化。2）在对照样地，暴雨事件后15~30 cm土壤水势显著升高，增加25 kPa，增幅与降水量呈强正相关（r = 0.781）；大雨和中雨事件对土壤水势的影响较小。在干旱样地，土壤水势与降水量相关性较弱（r = 0.710）；极端干旱样地的土壤水势与降水量无显著相关性。3）不同干旱程度样地的零通量面分布存在差异。暴雨事件对对照样地的影响显著，暴雨后水分运移方向由向上运移转为向下运移，零通量面下移至60 cm；干旱样地的土壤水分主要向45~60 cm深层运移；极端干旱样地则为浅层持续蒸散，深层（80~100 cm）土壤水分向上运移，零通量面位置保持稳定。在中雨和小雨事件前后，各干旱梯度样地的土壤水分运移方向整体不发生改变。结论: 晋西黄土区刺槐人工林土壤水分动态表现出显著的垂直分异特征，土壤含水量和土壤水势变化幅度随土壤深度增加和干旱处理加剧而减小，土壤水分运移方向受土壤深度与干旱程度的协同调控。暴雨是浅层土壤水分有效补给的重要因素之一，随干旱程度加剧，当浅层土壤含水量不足时，刺槐根系可吸收更深层土壤水以满足自身蒸腾耗水需求。本研究揭示干旱条件下晋西黄土区刺槐人工林土壤水分运移特征，为该区植被配置优化提供了理论支撑。

关键词: 土壤水分, 土壤水势, 干旱胁迫, 刺槐人工林, 晋西黄土区

Abstract:

Objective: Seasonal drought is a significant factor limiting tree growth, and high-intensity water use by trees can easily lead to soil dry layer formation. This study investigates the characteristics of soil water movement in Robinia pseudoacacia plantations in the loess region of western Shanxi under simulated drought conditions, aiming to provide theoretical support for optimized vegetation allocation in this area. Method: A 20-year-old R. pseudoacacia plantation in the western Loess Plateau was selected for an in-situ controlled experiment with three gradients: control (natural conditions), dry (50% precipitation reduction), and extremely dry (100% precipitation reduction). Soil water content (SWC) and soil water potential (SWP) were measured at 9:00 on the day after rainfall events and on typical sunny days using the oven-drying method and soil tensiometers, respectively. The zero flux plane (ZFP) method was applied to analyze soil water transport patterns under different drought gradients. Result: 1) In the control plot, torrential rain events increased the soil moisture content in the 0–60 cm layer, with the increase diminishing with soil depth. The post-rain moisture content in the 0–10 cm layer reached 32.42%±8.63%, rate of increase: 60.4%. Moderate and light rainfall only transiently affected shallow SWC, while deep soil layers (>60 cm) showed no response. Dry treatment exhibited limited SWC increases in shallow layers (only after torrential rainfall, peaking at 12.25% ± 3.51%), and extremely dry treatment showed no SWC changes. 2) After torrential rainfall, SWP in the shallow layer (15–30 cm) of the normal treatment significantly increased by 25 kPa, showing a strong positive correlation with rainfall (r = 0.781). Moderate and heavy rainfall had minimal effects. Dry treatment showed weaker SWP responses (r = 0.710), while extremely dry treatment exhibited no significant correlation. 3) The distribution of zero flux planes (ZFPs) varied with different drought treatments. In the normal plot, precipitation significantly influenced the ZFP position: after torrential rainfall, water transport in the normal treatment shifted from upward evaporation to downward infiltration, with ZFP descending to 60 cm. In dry treatment, water primarily migrated to deeper layers (45–60 cm). Extremely dry treatment maintained continuous evaporation in the surface layer (0–30 cm) and upward water movement in deep layers (80–100 cm), with stable ZFP positions. Under moderate and light rainfall, the overall direction of soil water movement across all gradients remained unchanged before and after the rainfall. Conclusion: Soil water dynamics in R. pseudoacacia plantations in the Loess Plateau of western Shanxi Province exhibit significant vertical stratification. The variability of SWC and SWP decreases with soil depth and drought intensity. Soil water transport direction is jointly influenced by depth and drought severity. Torrential rainfall drives shallow soil water recharge, but as drought intensifies and shallow water becomes insufficient, R. pseudoacacia roots absorb deeper soil water to meet transpiration demands. This study reveals the characteristics of soil water movement in R. pseudoacacia plantations under drought conditions, providing theoretical support for optimized vegetation allocation in the region.

Key words: soil water content, soil water potential, drought stress, Robinia pseudoacacia plantations, Loess Plateau of western Shanxi Province

中图分类号:

S714.2

殷晓晴,马岚,牛凤娇. 模拟干旱条件下晋西黄土区刺槐林土壤水分运移特征[J]. 林业科学, 2025, 61(10): 49-59.

Xiaoqing Yin,Lan Ma,Fengjiao Niu. Soil Water Transport Characteristics of Robinia pseudoacacia Plantations in the Loess Plateau of Western Shanxi Province under Simulated Drought Conditions[J]. Scientia Silvae Sinicae, 2025, 61(10): 49-59.

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样地 Sample plot	树高 Tree height/m	胸径 DBH/cm	冠幅 Crown area/m²	土壤密度 Soil density/ (g·cm^?3)
对照样地Control plot	10.72±1.08	12.29±0.51	8.19±3.93	1.29±0.05
干旱样地 Dry plot	11.02±0.70	12.07±0.61	6.51±2.55
极端干旱样地 Extremely dry plot	10.99±0.65	12.24±0.49	7.28±2.74

样地 Sample plot	小雨 Light rain (2024?07?06)	中雨 Moderate rain (2024?07?17)	大雨 Heavy rain (2024?07?25)	暴雨 Torrential rain (2024?07?31)	暴雨 Torrential rain (2024?08?10)	中雨 Moderate rain (2024?08?19)	中雨 Moderate rain (2024?08?21)	中雨 Moderate rain (2024?08?27)	合计 Total
对照样地 Control plot	8.0	11.8	27.0	50.3	70.0	18.8	20.7	18.8	221.2
干旱样地 Dry plot	4.0	5.9	13.5	25.2	35.0	9.4	10.4	9.4	110.6
极端干旱样地 Extremely dry plot	0	0	0	0	0	0	0	0	0

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