A review of zooplankton and deep carbon fixation contributions to carbon cycling in the dark ocean

IF 2.7 3区 地球科学 Q2 GEOSCIENCES, MULTIDISCIPLINARY Journal of Marine Systems Pub Date : 2022-12-01 DOI:10.1016/j.jmarsys.2022.103800
Brenda J. Burd, Richard E. Thomson
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Abstract

Models of the marine carbon cycle assume that virtually all heterotrophic production in the open ocean is derived from near-surface carbon fixation (primary production) by phytoplankton. However, current carbon budget estimates show that respiration throughout the ocean far exceeds surface primary production. This disconnect can be grouped into two categories: Inaccurate estimates of water column respiration and carbon transport from metazoans; and missing primary production sources and.

heterotrophic processing in the dark ocean. In this review, we examine the contribution to the ocean carbon cycle of chemoautotrophic production, as well as secondary production and respiration from meso-zooplankton and micro-nekton below 400 m depth.

About one-third of epipelagic biomass in the ocean migrates diurnally, distributing dissolved organic carbon (DOC) and total nitrogen (TN), along with about 30–80% of the particulate organic carbon (POC) flux, from the upper ocean. Although mostly this occurs in the upper 400 m, migration depths can extend to 3000 m. In addition, up to 80% of the biomass of secondary consumers in the open ocean live part of their life cycle at depths up to 2000 m, contributing significantly to deep-sea respiration and particle flux, particularly over fall/winter in temperate-subarctic oceans, submarine canyons, and deep seas such as the Mediterranean. This active flux provides fresh organic input to the deep ocean at a time of year when surface primary productivity, and thus organic carbon (OC) flux to the deep ocean, is low. The complex spatial, temporal and depth scales of horizontal and vertical migration make modelling of the global oceanic carbon cycle extremely complex, requiring consideration of biomass movements throughout the entire water column over diurnal, lunar and seasonal cycles over broad geographic regions.

An additional 10 to 50% of surface primary production occurs within mid-depth oxygen minimum zones (OMZs), fuelled by ammonia excreted from vertically migrating zooplankton concentrated near OMZ boundaries. Crustal sources such as gas and methane seeps, hydrothermal vents and submarine volcanoes support active deep-sea food webs, as well as contributing to upper ocean productivity. Crustal sources are conservatively estimated to provide >30%, and probably up to 50%, of oceanic OC flux to the dark ocean. These estimates are still poorly constrained but can no longer be ignored in global oceanic carbon cycles.

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浮游动物和深海固碳对暗海洋碳循环的贡献
海洋碳循环模型假设,开放海洋中几乎所有的异养生产都来自浮游植物的近地表固碳(初级生产)。然而,目前的碳预算估计表明,整个海洋的呼吸作用远远超过了表面初级生产。这种脱节可以分为两类:对水柱呼吸和后生动物碳运输的估计不准确;缺少主要的生产来源。黑暗海洋中的异养加工。本文研究了400 m以下浮游动物和微型浮游动物的化学自养生产以及次生生产和呼吸对海洋碳循环的贡献。海洋中约三分之一的上层海洋生物量每日迁移,分布着来自上层海洋的溶解有机碳(DOC)和总氮(TN),以及约30-80%的颗粒有机碳(POC)通量。虽然这主要发生在400米以上,但迁移深度可以延伸到3000米。此外,开放海洋中高达80%的次级消费者的生物量在最深达2000米的深度中度过其生命周期的一部分,这对深海呼吸和颗粒通量做出了重大贡献,特别是在温带亚北极海洋、海底峡谷和地中海等深海的秋冬季节。这种活跃的通量在一年中表层初级生产力较低的时候为深海提供了新鲜的有机输入,因此流入深海的有机碳(OC)通量较低。水平和垂直迁移的复杂空间、时间和深度尺度使得全球海洋碳循环的建模极其复杂,需要考虑整个水柱在广泛地理区域的日、月和季节循环中的生物量运动。另外10%至50%的地表初级生产发生在中深度氧气最低带(OMZs)内,由集中在OMZ边界附近的垂直迁移浮游动物排泄的氨提供燃料。天然气和甲烷渗漏、热液喷口和海底火山等地壳来源支持着活跃的深海食物网,同时也促进了上层海洋的生产力。据保守估计,地壳源向暗海洋提供了30%,甚至可能高达50%的海洋OC通量。这些估计仍然缺乏约束,但在全球海洋碳循环中不能再被忽视。
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来源期刊
Journal of Marine Systems
Journal of Marine Systems 地学-地球科学综合
CiteScore
6.20
自引率
3.60%
发文量
81
审稿时长
6 months
期刊介绍: The Journal of Marine Systems provides a medium for interdisciplinary exchange between physical, chemical and biological oceanographers and marine geologists. The journal welcomes original research papers and review articles. Preference will be given to interdisciplinary approaches to marine systems.
期刊最新文献
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