温度控制着海洋暮光带中的碳循环和生物进化。

Temperature controls carbon cycling and biological evolution in the ocean twilight zone.

机构信息

School of Earth and Environmental Sciences, Cardiff University, Cardiff, UK.

Department of Earth and Planetary Sciences, University of California, Riverside, CA, USA.

出版信息

Science. 2021 Mar 12;371(6534):1148-1152. doi: 10.1126/science.abb6643.

DOI:10.1126/science.abb6643

PMID:33707262

Abstract

Theory suggests that the ocean's biological carbon pump, the process by which organic matter is produced at the surface and transferred to the deep ocean, is sensitive to temperature because temperature controls photosynthesis and respiration rates. We applied a combined data-modeling approach to investigate carbon and nutrient recycling rates across the world ocean over the past 15 million years of global cooling. We found that the efficiency of the biological carbon pump increased with ocean cooling as the result of a temperature-dependent reduction in the rate of remineralization (degradation) of sinking organic matter. Increased food delivery at depth prompted the development of new deep-water niches, triggering deep plankton evolution and the expansion of the mesopelagic "twilight zone" ecosystem.

摘要

理论表明，海洋的生物碳泵——将有机物在海面产生并转移到深海的过程——对温度敏感，因为温度控制着光合作用和呼吸作用的速率。我们采用了数据与模型相结合的方法，研究了全球变冷的过去 1500 万年里，全球海洋的碳和营养物质再循环速率。我们发现，生物碳泵的效率随着海洋冷却而增加，这是由于沉降有机物的再矿化（降解）速率随温度相关而降低所致。食物在深层的输送增加促使新的深水区小生境的发展，引发了深海浮游生物的进化和中层带“暮光区”生态系统的扩张。

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温度控制着海洋暮光带中的碳循环和生物进化。

Temperature controls carbon cycling and biological evolution in the ocean twilight zone.

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