黄土塬区苹果园降雨入渗机制

doi:10.13287/j.1001-9332.201709.031

摘要/Abstract

摘要： 选取长武黄土塬区20年树龄苹果园,使用4 g·L^-1亮蓝溶液(Brilliant Blue FCF)进行染色示踪试验,分别采用喷洒、倾倒和树干径流模拟3种方式模拟雨量为50 mm的正常降雨入渗、雨量为50 mm的极端性暴雨入渗和树干径流方式的雨水入渗(18 L树干径流量).结果表明: 喷洒方式下染色平均深度为0.28 m,深度较浅,均匀入渗比平均值超过0.65,中位数超过0.7,说明水分入渗过程中均匀部分所占比重较大,活塞流是黄土塬区苹果园降雨入渗的主要机制;倾倒方式下染色平均深度为0.53 m,最大深度为0.59 m,深度较浅,表明在极端暴雨、激活大孔隙等优先路径的条件下,雨水很难短时间补给深层土壤水;树干径流模拟方式下染色最大深度为0.46 m,深度也较浅,表明雨水较难通过树干径流的方式沿着根系补给深层土壤水.活根系与腐烂根系染色比较分析发现,活根系(≥2 mm)不具有良好的导水能力,而腐烂根系(≥2 mm)形成的入渗通道则具有更好的导水能力.在土壤表层果树根系以水平根系为主,当表层根系腐烂时可能发生横向优先流,从而阻碍雨水对深层土壤水的补给.在黄土塬区苹果园,活塞流是深层土壤水降雨补给的主要机制,大孔隙和腐烂垂直根系等通道可能作为雨水补给深层土壤水的途径.

Abstract: Dye tracing experiments were carried out in apple orchards of 20 years old in Changwu tableland using Brilliant Blue FCF solution of 4 g·L^-1. Three water application methods (sprinkler, flood, stemflow simulation) were used to simulate regular 50 mm rainfall infiltration, intense 50 mm rainfall infiltration and stem flow infiltration (18 L of stemflow amount), respectively. The results showed that for sprinkler water application, the average dye-stained depth was 0.28 m and shallow. The average and median values of uniform infiltration fractions were larger than 0.65 and 0.7, respectively, indicating that the proportion of the uniform part was larger in the infiltration process, and piston flow was the main mechanism of rainfall infiltration in apple orchards on Loess Tableland. For flood water application, the average and maximum dye-stained depths were 0.53 m and 0.59 m, respectively. The depths were also shallow, indicating that it was difficult to recharge deep soil water for a short time under the conditions of intense rainfall and activation of macropores. For stemflow simulation water application, the maximum dye-stained depth was 0.46 m and also shallow, indicating that it was difficult for rainfall to recharge deep soil along the roots by stem flow.By comparing the dying of live and decayed roots, it was found that live roots (≥2 mm) had minor water conductivity, while the infiltration channels formed by degraded roots (≥2 mm) had better water conductivity. Most of the apple tree roots were horizontally distributed near the soil surface, and the lateral preferential flow was more likely to occur when these surface roots decomposed, thus preventing rainfall from infiltrating into the deep soil. In conclusion, piston flow was the main recharge mechanism of deep soil water recharge in apple orchards on Loess Tableland of China, and the channels such as soil macropores and degraded vertical roots might also be an approach to deep soil water recharge.

郑双科, 司炳成, 张志强, 李敏, 吴奇凡. 黄土塬区苹果园降雨入渗机制[J]. 应用生态学报, 2017, 28(9): 2870-2878.

ZHENG Shuang-ke, SI Bing-cheng, ZHANG Zhi-qiang, LI Min, WU Qi-fan. Mechanism of rainfall infiltration in apple orchards on Loess Tableland, China.[J]. Chinese Journal of Applied Ecology, 2017, 28(9): 2870-2878.

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