Self-filling enclosures to experimentally assess plankton response to pulse nutrient enrichments.

IF 1.9 3区环境科学与生态学 Q2 MARINE & FRESHWATER BIOLOGY

Journal of Plankton Research Pub Date : 2023-03-01 DOI:10.1093/plankt/fbac074

Pau Giménez-Grau, Lluís Camarero, Carlos Palacín-Lizarbe, Marc Sala-Faig, Aitziber Zufiaurre, Sergi Pla-Rabés, Marisol Felip, Jordi Catalan

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Abstract

Experimental nutrient additions are a fundamental approach to investigating plankton ecology. Possibilities range from whole-lake fertilization to flask assays encompassing a trade-off between closeness to the "real world" and feasibility and replication. Here we describe an enclosure type that minimizes the manipulation of planktonic communities during the enclosure filling. The enclosure (typically ~100 L volume) consists of a narrow translucent cylinder that can comprise the entire photic zone (or a large part of it in clear deep lakes, e.g. 20-m long) and holds a sediment trap at the bottom for recovering the sinking material. The enclosures are inexpensive and straightforward to build. Thus, many can be used in an experiment, favoring the diversity of treatments and the number of replicates. They also are lightweight with easy transport and use in lakes that cannot be reached by road. The enclosures are fundamentally aimed at investigating the short-term response of the planktonic community, integrated across the photic zone, to pulse perturbations using before and after comparisons and multiple replication and treatments. The pros and cons of the enclosure design are evaluated based on experience gained in Lake Redon, a high mountain ultraoligotrophic deep lake in the Pyrenees.

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实验评估浮游生物对脉冲营养物富集反应的自充式围栏。

实验添加营养物是研究浮游生物生态学的基本方法。可能性范围从整个湖泊施肥到烧瓶试验，包括接近“真实世界”与可行性和复制之间的权衡。在这里，我们描述了一种围护类型，在围护填充过程中最大限度地减少了浮游生物群落的操纵。外壳(通常约100升体积)由一个狭窄的半透明圆柱体组成，可以包含整个光区(或在清澈的深湖中的大部分，例如20米长)，并在底部容纳沉积物收集器，用于回收下沉的物质。这种外壳既便宜又容易制造。因此，可以在实验中使用许多，有利于处理的多样性和重复的数量。它们也很轻，便于运输和在无法通过公路到达的湖泊中使用。这些围栏的基本目的是研究浮游生物群落对脉冲扰动的短期反应，通过前后比较和多次复制和处理，将整个光带整合在一起。根据在比利牛斯山脉的高山超贫营养深湖雷东湖获得的经验，对围护设计的利弊进行了评估。

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来源期刊

Journal of Plankton Research 生物-海洋学

CiteScore

3.50

自引率

9.50%

发文量

审稿时长

1 months

期刊介绍： Journal of Plankton Research publishes innovative papers that significantly advance the field of plankton research, and in particular, our understanding of plankton dynamics.