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台风浪涌后西太平洋透明胞外聚合物颗粒沉降速率和分布的环境影响

Environmental influences on sinking rates and distributions of transparent exopolymer particles after a typhoon surge at the Western Pacific.

机构信息

College of Food Engineering and Biotechnology, Tianjin University of Science and Technology University, TEDA, No 29, 13thAvenue, Tianjin, China.

Research Centre for Indian Ocean Ecosystem, Tianjin University of Science and Technology, Tianjin, 300457, China.

出版信息

Sci Rep. 2021 May 31;11(1):11377. doi: 10.1038/s41598-021-88477-0.

DOI:10.1038/s41598-021-88477-0
PMID:34059698
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8166891/
Abstract

A multidisciplinary approach was used to investigate the causes of the distributions and sinking rates of transparent exopolymer particles (TEPs) during the period of September-October (2017) in the Western Pacific Ocean (WPO); the study period was closely dated to a northwest typhoon surge. The present study discussed the impact of biogeophysical features on TEPs and their sinking rates (sTEP) at depths of 0-150 m. During the study, the concentration of TEPs was found to be higher in areas adjacent to the Kuroshio current and in the bottom water layer of the Mindanao upwelling zone due to the widespread distribution of cyanobacteria, i.e., Trichodesmium hildebrandti and T. theibauti. The positive significant regressions of TEP concentrations with Chl-a contents in eddy-driven areas (R = 0.73, especially at 100 m (R = 0.75)) support this hypothesis. However, low TEP concentrations and TEPs were observed at mixed layer depths (MLDs) in the upwelling zone (Mindanao). Conversely, high TEP concentrations and high sTEP were found at the bottom of the downwelling zone (Halmahera). The geophysical directions of eddies may have caused these conditions. In demonstrating these relations, the average interpretation showed the negative linearity of TEP concentrations with TEPs (R = 0.41 ~ 0.65) at such eddies. Additionally, regression curves (R = 0.78) indicated that atmospheric pressure played a key role in the changes in TEPs throughout the study area. Diatoms and cyanobacteria also curved the TEPs significantly (R = 0.5, P < 0.05) at the surface of the WPO. This study also revealed that TEP concentration contributes less to the average particulate organic carbon in this oligotrophic WPO.

摘要

采用多学科方法研究了 2017 年 9-10 月(秋季)西太平洋(WPO)中透明胞外聚合物颗粒(TEP)分布和沉降率的原因;研究期间与西北台风浪涌密切相关。本研究讨论了生物地球物理特征对 WPO 中 0-150m 深度处 TEP 及其沉降率(sTEP)的影响。研究期间,由于广泛分布的蓝细菌(即海链藻属 Trichodesmium hildebrandti 和 T. theibauti),在黑潮附近和棉兰老上升流区的底层水中发现 TEP 的浓度较高。在涡旋驱动区,TEP 浓度与 Chl-a 含量呈正显著回归(R=0.73,特别是在 100m 处(R=0.75)),支持这一假设。然而,在上升流区(棉兰老)的混合层深度(MLD)处观察到低 TEP 浓度和 TEPs。相反,在下降流区(哈马黑拉)的底部发现了高 TEP 浓度和高 sTEP。涡旋的地球物理方向可能导致了这些情况。在证明这些关系时,平均解释表明在这些涡旋中 TEP 浓度与 TEPs 呈负线性(R=0.41~0.65)。此外,回归曲线(R=0.78)表明大气压力在整个研究区域中对 TEPs 的变化起着关键作用。在 WPO 表面,硅藻和蓝细菌也对 TEPs 产生了显著影响(R=0.5,P<0.05)。本研究还表明,在贫营养的 WPO 中,TEP 浓度对平均颗粒有机碳的贡献较小。

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