造成纳米比亚仙女圈的原因是植物缺水,而不是白蚁食草

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2022-12-01 DOI:10.1016/j.ppees.2022.125698
Stephan Getzin , Sönke Holch , Hezi Yizhaq , Kerstin Wiegand
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引用次数: 7

摘要

纳米比亚的仙女圈在纳米布沙漠沿线的干旱草原上形成了一个引人注目的缺口格局。仙女圈的起源一直是争论不休的话题。要解开仙女圈之谜,需要在雨后的野外工作中把握好时机,因为新出现的草在几周内就完成了它们的生命周期。在这里,我们跟踪了2020年至2022年期间纳米布沿岸的降雨,并评估了草地触发降雨后不同时间间隔内fc内草地死亡的原因。为了确定白蚁的食草性是否为白蚁的原因,我们进行了草的挖掘和根、芽的观察。为了验证土壤差异是否可以解释草地死亡,我们在10个草地热点地区进行了入渗测量。最后,我们利用从旱季到雨季的连续土壤水分测量来研究新出现的草在空间和时间上如何影响土壤水分含量。一般来说,在最近接受过触发草降雨的研究地块中,FCs中死亡草的根100%未受损,根冠比显著更高,根系与FCs外周围基质草的根一样长,甚至更长。这表明干旱胁迫导致FCs中的草类将资源投入到根部以接触到渗透水。结果还表明,神仙圈草的死亡原因不是白蚁的食草性引起的。此外,我们发现纤维纤维和基质之间的水分渗透速率没有系统差异,因此植物枯萎不是由于纤维纤维内部的快速渗透造成的。然而,土壤水分测量表明,基质草在降雨后强烈地耗尽了FCs的上层土壤水分,这解释了为什么大多数草不能在FCs中建立并迅速死亡。研究表明,由于植物水分胁迫,仙女圈中的草在降雨后立即死亡,而不是白蚁活动。本研究结果与以往的野外调查、模式分析和理论模型相吻合,表明纳米比亚的仙女圈是一种由生态水文反馈引起的自组织植被现象。
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Plant water stress, not termite herbivory, causes Namibia’s fairy circles

The fairy circles of Namibia form a remarkable gap pattern in arid grassland along the Namib Desert. The origin of the fairy circles is subject to an ongoing debate. Solving the mystery of the fairy circles (FCs) requires the right timing in fieldwork after rainfall, as the newly appearing grasses complete their life cycle within only a few weeks. Here we followed the rains along the Namib between 2020 and 2022 and assessed the cause of the grass death within FCs at different time intervals after grass-triggering rainfall. To assess whether termite herbivory was the cause, we used grass excavations and observations on the roots and shoots. To test if edaphic differences may explain the grass death in FCs, we undertook infiltration measurements in 10 FC-hotspot regions. Finally, we used continuous soil-moisture measurements from the dry into the rainy seasons to examine how the newly emerging grasses affect the soil-water content in space and time. Generally, in study plots that received grass-triggering rainfall most recently, the roots of the dead grasses in FCs were in 100 % of the cases undamaged, root-shoot ratios were significantly greater, and the roots were as long or even longer as those of the surrounding matrix grasses outside of the FCs. This indicates that drought stress caused grasses in the FCs to invest resources into roots to reach the percolating water. The results also show that the cause of the grass death in fairy circles was not induced by termite herbivory. Also, we found no systematic differences in the rate of water infiltration between FCs and the matrix, hence the plant wilting cannot result from quicker percolation within FCs. However, the soil-moisture measurements indicate that the matrix grasses strongly depleted the upper soil water of the FCs after rainfall, which explains why most grasses cannot establish and quickly die in the FCs. The research shows that grass death in fairy circles occurs immediately after rainfall due to plant water stress but not due to termite activity. Our results conform with previous fieldwork, pattern analysis and theoretical modeling, suggesting that Namibia’s fairy circles are a self-organized vegetation phenomenon induced by ecohydrological feedbacks.

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