光合作用量子产量对浮游植物光吸收的依赖性:评估黑海初级生产力的方程

IF 0.7 Q4 OCEANOGRAPHY
T. Churilova, V. Suslin, H. M. Sosik
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引用次数: 3

摘要

意图在一次科学巡航中进行了研究,以表征水物理特性、叶绿素a浓度、光合作用辐照度曲线、浮游植物的光谱光吸收系数和光谱量子下流辐照度。根据这些结果,研究了光合量子产量对环境因素的依赖性,目的是调整为波罗的海开发的算法,以便将其应用于黑海。方法和结果。在透光带的几个深度进行了复杂的水物理和生物研究。光谱生物光学参数是根据美国国家航空航天局的最新协议(2018)进行测量的。在类似于原位的温度和光照条件下进行了确定光合作用与光照关系的实验。根据光合作用-光曲线参数(光合作用效率、光饱和参数)和浮游植物色素的光谱光吸收系数计算光合作用的量子产率。研究发现,由于浮游植物在季节分层期间对环境因素的适应,浮游植物的主要光合特性,包括最大光合量子产量和与光保护辅助色素相关的浮游植物吸收分数,在透光带内随深度而变化。揭示了光合作用量子产率与光合作用活性浮游植物色素吸收量子量之间的关系。这项研究的结果使我们有可能在为其他地区开发的方法的基础上,修改量子产率的计算公式,以专门适用于黑海的环境条件。结论。在黑海进行的综合研究,包括测量光合作用对光的依赖性、浮游植物的光谱光吸收系数和光谱下流辐照度作为透光带内光学深度的函数,首次揭示了计算光合量子产量的方程。这一新方程可用于根据现场测量结果和遥感数据,使用光谱方法计算黑海的初级产量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Dependence of the Photosynthetic Quantum Yield on Phytoplankton Light Absorption: Equations for Assessing Primary Production in the Black Sea
Purpose. Investigations were performed during a scientific cruise to characterize hydrophysical properties, chlorophyll a concentration, photosynthesis-irradiance curves, spectral light absorption coefficients by phytoplankton, and spectral quantum downwelling irradiance. From these results, the dependence of the photosynthetic quantum yield upon environmental factors was studied with the purpose of adapting an algorithm developed for the Baltic Sea so that it can be applied for the Black Sea. Methods and Results. Complex hydrophysical and biological studies were carried out at several depths within the euphotic zone. Spectral bio-optical parameters were measured in accordance with the latest NASA protocols (2018). Experiments to determine the photosynthesis-light relationship were performed under temperature and light conditions similar to those in situ. The quantum yield of photosynthesis was calculated from parameters of photosynthesis-light curves (photosynthesis efficiency, light saturation parameter) and the spectral light absorption coefficients by phytoplankton pigments. It was found out that the main photosynthetic characteristics of phytoplankton, including the maximum photosynthetic quantum yield and the fraction of phytoplankton absorption associated with photoprotective accessory pigments, varied with depth within the euphotic zone, due to phytoplankton acclimation to environment factors during the period of seasonal stratification. The relationship between the photosynthetic quantum yield and the quanta absorbed by photosynthetically active phytoplankton pigments was revealed. The results of this research made it possible to build on the approach developed for other regions and modify the equation for calculating the quantum yield to apply specifically for environmental conditions in the Black Sea. Conclusions. For the first time, comprehensive studies carried out in the Black Sea, including measurements of the photosynthesis-light dependence, spectral light absorption coefficients by phytoplankton and spectral downwelling irradiance as a function of optical depths within the euphotic zone, made it possible to reveal the equation for calculating photosynthetic quantum yield. This new equation can be applied for calculating primary production of the Black Sea using a spectral approach, based both on the results of in situ measurements and remote sensing data.
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来源期刊
Physical Oceanography
Physical Oceanography OCEANOGRAPHY-
CiteScore
1.80
自引率
25.00%
发文量
8
审稿时长
24 weeks
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