Linking prescribed fire, nutrient deposition and cyanobacteria dominance through pyroeutrophication in a subtropical lake ecosystem from the mid Holocene to present

IF 3.3 2区地球科学 Q2 ENVIRONMENTAL SCIENCES Anthropocene Pub Date : 2023-11-07 DOI:10.1016/j.ancene.2023.100420

Matthew N. Waters , Joseph M. Smoak , Richard S. Vachula

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Abstract

Prescribed fire (Rx-fire) is a common management tool for many forested ecosystems and promotes tree and forest soil health. Although burned materials from Rx-fire areas can enter adjacent aquatic environments, very few studies have focused on the water quality impacts of increased nutrients on aquatic primary producer communities. Here, we applied paleolimnological techniques on a 170-cm sediment core collected from Ditch Pond, AL, USA, a subtropical lake system located in the Conecuh National Forest where Rx-fire has been the primary management tool for ∼90 years. Macroscopic charcoal, nutrients (C, N, P) and photosynthetic pigments were measured throughout the core which spans from the middle Holocene until modern day. Our research questions were: 1) What were the sedimentary nutrient and stoichiometric changes associated with the Rx-Fire period beginning in 1937 CE? and 2) Did these nutrient changes alter historic algae/cyanobacteria groups? Following the onset of Rx-fire, nutrients (C, N, P) increased in deposition in the lake with P showing the greatest proportional increase at over 300%, suggesting that P inputs from Rx-fire are a primary artifact of burning. Photosynthetic pigments showed that increases in nutrients from Rx-fire caused extensive increases in total primary producer abundance and cyanobacteria dominance, called pyroeutrophication. These data suggest a greater need to understand the implications of fire-associated nutrients on aquatic primary producers wherever fire (but especially Rx-fire) is occurring, as well as an increase in collaboration between forest and aquatic ecosystem managers.

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全新世中期至今亚热带湖泊生态系统热富营养化过程中明火、营养物沉积和蓝藻优势的关联

规定火(Rx-fire)是许多森林生态系统的常用管理工具，可促进树木和森林土壤健康。虽然来自rx火区的燃烧物质可以进入邻近的水生环境，但很少有研究关注营养增加对水生初级生产者群落的水质影响。在这里，我们应用了古湖泊学技术对从美国AL的Ditch Pond收集的170 cm沉积物岩芯进行了研究，该岩芯是位于Conecuh国家森林的亚热带湖泊系统，Rx-fire作为主要管理工具已经有90年了。宏观木炭，营养物质(C, N, P)和光合色素在整个岩心中进行了测量，从全新世中期到现代。我们的研究问题是:1)与1937年开始的Rx-Fire期相关的沉积营养和化学计量学变化是什么?2)这些营养变化是否改变了历史上的藻类/蓝藻群?Rx-fire发生后，湖泊沉积物中的营养物质(C、N、P)增加，其中P的增加比例最大，超过300%，表明Rx-fire的P输入是燃烧的主要人工产物。光合色素表明，Rx-fire带来的营养物质的增加导致初级生产者总丰度和蓝藻优势度的广泛增加，称为热富营养化。这些数据表明，更需要了解与火有关的营养物质对发生火灾(特别是火灾)的水生初级生产者的影响，以及加强森林和水生生态系统管理人员之间的合作。

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来源期刊

Anthropocene Earth and Planetary Sciences-Earth and Planetary Sciences (miscellaneous)

CiteScore

6.30

自引率

0.00%

发文量

审稿时长

102 days

期刊介绍： Anthropocene is an interdisciplinary journal that publishes peer-reviewed works addressing the nature, scale, and extent of interactions that people have with Earth processes and systems. The scope of the journal includes the significance of human activities in altering Earth’s landscapes, oceans, the atmosphere, cryosphere, and ecosystems over a range of time and space scales - from global phenomena over geologic eras to single isolated events - including the linkages, couplings, and feedbacks among physical, chemical, and biological components of Earth systems. The journal also addresses how such alterations can have profound effects on, and implications for, human society. As the scale and pace of human interactions with Earth systems have intensified in recent decades, understanding human-induced alterations in the past and present is critical to our ability to anticipate, mitigate, and adapt to changes in the future. The journal aims to provide a venue to focus research findings, discussions, and debates toward advancing predictive understanding of human interactions with Earth systems - one of the grand challenges of our time.