短讯：树冠滴水的集中影响--森林水土流失的热点地区

IF 2.8 2区地球科学 Q2 GEOGRAPHY, PHYSICAL

Earth Surface Dynamics Pub Date : 2023-12-11 DOI:10.5194/esurf-11-1275-2023

Ayumi Katayama, Kazuki Nanko, Seonghun Jeong, Tomonori Kume, Yoshinori Shinohara, Steffen Seitz

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引用次数: 0

摘要

摘要大型食草动物造成的地面植被退化经常导致森林生态系统的侵蚀率增加。从树冠滴落的高通过动能（TKE）可造成飞溅侵蚀。值得注意的是，来自结构介导的木质表面点的较大树冠滴水似乎会引起更高的 TKE，并产生集中的冲击位置，造成严重的土壤侵蚀焦点。然而，这些地点的 TKE 却鲜有报道。这项试点研究调查了集中冲击点的 TKE 强度，并将其与林冠下的一般 TKE 点和森林外的自由落体动能 (FKE) 进行了比较。我们在 2021 年日本常绿针叶树和落叶阔叶树混交林的无叶和落叶季节，使用飞溅杯测量了日本榉树下 7 个地点和林外 5 个地点的降水量、TKE 和 FKE。集中影响地点的 TKE 分别是山毛榉和 FKE 下一般地点的 15.2 倍和 49.7 倍。这项研究证实，林木表面的冠层滴水可能是温带森林生态系统土壤侵蚀的热点。集中影响位置的通流降水量分别是一般位置和自由落体位置的 11.4 倍和 8.1 倍。集中影响区每 1 毫米降水量的 TKE（此处称为 "单位 TKE"）（39.2 ± 23.7 J m-2 mm-1）远高于一般影响区（22.0 ± 12.7 J m-2 mm-1）和单位 FKE（4.5 ± 3.5 J m-2 mm-1）。无叶季节的单位 TKE 明显低于有叶季节，这是因为仅由木质组织引起的树冠滴流再分布较少。尽管如此，无叶季节集中影响位置的单位 TKE（36.4 J m-2 mm-1）仍然高于有叶季节的一般位置。这些结果表明，即使在无叶季节，集中冲击点的通流降水量和较大的通流水滴大小分布也会导致潜在的高沉积物剥离率。有必要在第一份报告的基础上进行更多的重复研究，以调查不同树种平均会出现多少个这样的集中影响点，从而更好地评估森林侵蚀风险的程度。

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Short communication: Concentrated impacts by tree canopy drips – hotspots of soil erosion in forests

Abstract. The degradation of ground vegetation cover caused by large grazing herbivores frequently results in enhanced erosion rates in forest ecosystems. Splash erosion can be caused by drop impacts with a high throughfall kinetic energy (TKE) from the tree canopy. Notably larger canopy drips from structurally mediated woody surface points appear to induce even higher TKE and generate concentrated impact locations causing severe focus points of soil erosion. However, TKE at these locations has rarely been reported. This pilot study investigated the intensity of TKE at a concentrated impact location and compared it with general TKE locations under the canopy and freefall kinetic energy (FKE) outside the forest. We measured precipitation, TKE and FKE using splash cups at seven locations under Japanese beech trees and five locations outside the forest during the leafless and leafed seasons in 2021 in a mixed forest with evergreen coniferous trees and deciduous broadleaved trees in Japan. The TKE at the concentrated impact location was 15.2 and 49.7 times higher than that at the general locations under the beech and FKE, respectively. This study confirmed that canopy drip from woody surfaces could be a hotspot of soil erosion in temperate forest ecosystems. Throughfall precipitation at the concentrated impact location was 11.4 and 8.1 times higher than that at general locations and freefall, respectively. TKE per 1 mm precipitation (here, “unit TKE”) at the concentrated impact location (39.2 ± 23.7 J m−2 mm−1) was much higher than that at general locations (22.0 ± 12.7 J m−2 mm−1) and unit FKE (4.5 ± 3.5 J m−2 mm−1). Unit TKE in the leafless season was significantly lower than in the leafed season because of fewer redistribution of canopy drips induced only by woody tissue. Nevertheless, unit TKE at the concentrated impact location in the leafless season (36.4 J m−2 mm−1) was still higher than at general locations in the leafed season. These results show that potentially high rates of sediment detachment can be induced not only by throughfall precipitation but also by larger throughfall drop size distributions at the concentrated impact location, even in the leafless season. Further studies with more replication building on this first report are necessary to investigate how many of these concentrated impact locations may occur on average with different tree species to better assess the extent of the erosion risk under forests.

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来源期刊

Earth Surface Dynamics GEOGRAPHY, PHYSICALGEOSCIENCES, MULTIDISCI-GEOSCIENCES, MULTIDISCIPLINARY

CiteScore

5.40

自引率

5.90%

发文量

审稿时长

20 weeks

期刊介绍： Earth Surface Dynamics (ESurf) is an international scientific journal dedicated to the publication and discussion of high-quality research on the physical, chemical, and biological processes shaping Earth''s surface and their interactions on all scales.