{"title":"通过优先流动将茎流水通过土壤:一种带有人工示踪剂的双重标签方法","authors":"J. Pinos, M. Flury, J. Latron, P. Llorens","doi":"10.5194/hess-27-2865-2023","DOIUrl":null,"url":null,"abstract":"Abstract. Stemflow and its belowground funnelling along roots and macropores may play an important role in the soil moisture redistribution in forest environments. In this study, a stemflow experiment on Pinus sylvestris L. (Scots pine) used artificial tracers to view and quantify preferential flow after stemflow infiltration into the soil. A total of 41 L of water labelled with enriched deuterium and brilliant blue FCF were applied at a flow rate of 7 L h−1 to the stem of a pine tree, which corresponds to the stemflow caused by about 50 mm of rainfall. Time domain reflectometry (TDR) probes were installed around the tree trunk to measure the high-resolution volumetric water content. A total of 1 d after the stemflow discharge, soil pits were dug in the different cardinal directions and at varying distances from the tree. Photographs were taken for imaging analysis to quantify preferential flow metrics. Soil samples were taken from the different profiles to analyse the dye concentrations and isotopic compositions. We found that stemflow infiltrated through an annulus-shaped area around the tree base. We observed a heterogenous spatiotemporal soil moisture response to stemflow and the occurrence of shallow perched water tables around the tree trunk. Dye staining demonstrated that stemflow infiltrated primarily along the surface of coarse roots and through macropores. The dye coverage was less extensive close to the soil surface and increased with depth and with proximity to the tree trunk. Lateral flow was also observed, mainly in the shallow soil layers. Our analyses demonstrate the prevalence of preferential flow. Deuterium and brilliant blue FCF concentrations were\nsignificantly correlated. The tracer concentrations decreased with increasing distance from the tree trunk, indicating dilution and mixing with residual soil water. Macropores, coarse roots (living or decayed) and\nperched water tables produced a complex network regulating the preferential\nflow. Our results suggest that stemflow affects soil moisture distribution,\nand thus likely also groundwater recharge and surface runoff. Our study\nprovides insights into the soil hydrological processes that are regulated by stemflow belowground funnelling and improves our understanding of\nforest–water interactions.\n","PeriodicalId":13143,"journal":{"name":"Hydrology and Earth System Sciences","volume":" ","pages":""},"PeriodicalIF":5.7000,"publicationDate":"2023-08-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Routing stemflow water through the soil via preferential flow: a dual-labelling approach with artificial tracers\",\"authors\":\"J. Pinos, M. Flury, J. Latron, P. Llorens\",\"doi\":\"10.5194/hess-27-2865-2023\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Abstract. Stemflow and its belowground funnelling along roots and macropores may play an important role in the soil moisture redistribution in forest environments. In this study, a stemflow experiment on Pinus sylvestris L. (Scots pine) used artificial tracers to view and quantify preferential flow after stemflow infiltration into the soil. A total of 41 L of water labelled with enriched deuterium and brilliant blue FCF were applied at a flow rate of 7 L h−1 to the stem of a pine tree, which corresponds to the stemflow caused by about 50 mm of rainfall. Time domain reflectometry (TDR) probes were installed around the tree trunk to measure the high-resolution volumetric water content. A total of 1 d after the stemflow discharge, soil pits were dug in the different cardinal directions and at varying distances from the tree. Photographs were taken for imaging analysis to quantify preferential flow metrics. Soil samples were taken from the different profiles to analyse the dye concentrations and isotopic compositions. We found that stemflow infiltrated through an annulus-shaped area around the tree base. We observed a heterogenous spatiotemporal soil moisture response to stemflow and the occurrence of shallow perched water tables around the tree trunk. Dye staining demonstrated that stemflow infiltrated primarily along the surface of coarse roots and through macropores. The dye coverage was less extensive close to the soil surface and increased with depth and with proximity to the tree trunk. Lateral flow was also observed, mainly in the shallow soil layers. Our analyses demonstrate the prevalence of preferential flow. Deuterium and brilliant blue FCF concentrations were\\nsignificantly correlated. The tracer concentrations decreased with increasing distance from the tree trunk, indicating dilution and mixing with residual soil water. Macropores, coarse roots (living or decayed) and\\nperched water tables produced a complex network regulating the preferential\\nflow. Our results suggest that stemflow affects soil moisture distribution,\\nand thus likely also groundwater recharge and surface runoff. 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引用次数: 0
摘要
摘要在森林环境下,茎流及其沿根和大孔的地下漏斗可能在土壤水分再分配中起重要作用。本研究采用人工示踪剂对松木茎流进行试验,观察和量化其茎流入渗土壤后的优先流量。用浓缩氘和亮蓝色FCF标记的41 L水以7 L h−1的流速作用于松树的茎干,这相当于约50 mm降雨引起的茎流。在树干周围安装时域反射(TDR)探针,测量高分辨率的体积含水量。在茎流排出1 d后,在不同的基本方向和离树的不同距离上挖土坑。拍摄照片进行成像分析,以量化优先流量指标。从不同剖面提取土壤样本,分析染料浓度和同位素组成。我们发现茎流通过树基部周围的环形区域渗透。我们观察到土壤水分对茎流和树干周围浅栖息水位的时空响应具有异质性。染料染色表明茎流主要沿粗根表面和大孔渗透。接近土壤表面的染料覆盖度较低,随着深度和接近树干而增加。还观察到横向流动,主要在浅层土层。我们的分析证明了优惠流动的普遍存在。氘浓度与亮蓝色FCF浓度呈显著相关。示踪剂浓度随离树干距离的增加而降低,表明与土壤残馀水的稀释和混合。大孔、粗根(活着的或腐烂的)和悬空的地下水位形成了一个复杂的网络来调节优先流动。我们的研究结果表明,茎流影响土壤水分分布,因此可能也影响地下水补给和地表径流。我们的研究提供了对土壤水文过程的见解,土壤水文过程是由地下漏斗的茎流调节的,并提高了我们对森林-水相互作用的理解。
Routing stemflow water through the soil via preferential flow: a dual-labelling approach with artificial tracers
Abstract. Stemflow and its belowground funnelling along roots and macropores may play an important role in the soil moisture redistribution in forest environments. In this study, a stemflow experiment on Pinus sylvestris L. (Scots pine) used artificial tracers to view and quantify preferential flow after stemflow infiltration into the soil. A total of 41 L of water labelled with enriched deuterium and brilliant blue FCF were applied at a flow rate of 7 L h−1 to the stem of a pine tree, which corresponds to the stemflow caused by about 50 mm of rainfall. Time domain reflectometry (TDR) probes were installed around the tree trunk to measure the high-resolution volumetric water content. A total of 1 d after the stemflow discharge, soil pits were dug in the different cardinal directions and at varying distances from the tree. Photographs were taken for imaging analysis to quantify preferential flow metrics. Soil samples were taken from the different profiles to analyse the dye concentrations and isotopic compositions. We found that stemflow infiltrated through an annulus-shaped area around the tree base. We observed a heterogenous spatiotemporal soil moisture response to stemflow and the occurrence of shallow perched water tables around the tree trunk. Dye staining demonstrated that stemflow infiltrated primarily along the surface of coarse roots and through macropores. The dye coverage was less extensive close to the soil surface and increased with depth and with proximity to the tree trunk. Lateral flow was also observed, mainly in the shallow soil layers. Our analyses demonstrate the prevalence of preferential flow. Deuterium and brilliant blue FCF concentrations were
significantly correlated. The tracer concentrations decreased with increasing distance from the tree trunk, indicating dilution and mixing with residual soil water. Macropores, coarse roots (living or decayed) and
perched water tables produced a complex network regulating the preferential
flow. Our results suggest that stemflow affects soil moisture distribution,
and thus likely also groundwater recharge and surface runoff. Our study
provides insights into the soil hydrological processes that are regulated by stemflow belowground funnelling and improves our understanding of
forest–water interactions.
期刊介绍:
Hydrology and Earth System Sciences (HESS) is a not-for-profit international two-stage open-access journal for the publication of original research in hydrology. HESS encourages and supports fundamental and applied research that advances the understanding of hydrological systems, their role in providing water for ecosystems and society, and the role of the water cycle in the functioning of the Earth system. A multi-disciplinary approach is encouraged that broadens the hydrological perspective and the advancement of hydrological science through integration with other cognate sciences and cross-fertilization across disciplinary boundaries.
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