东阿拉伯海原核生物的时空动态

IF 3 4区环境科学与生态学 Q3 ENVIRONMENTAL SCIENCES

Environmental Monitoring and Assessment Pub Date : 2025-03-22 DOI:10.1007/s10661-025-13849-2

Shyla Hafza, Ammini Parvathi, P. M. Muhammed Iqbal, Valliyodan Sudheesh, C. K. Sherin, N. V. Harikrishnachari

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引用次数: 0

摘要

本文研究了阿拉伯海东部春季风间期（4 - 5月）、夏季风期（6 - 9月）和冬季风期（11 - 2月）原核生物丰度（PA）和生物量在理化参数上的空间和季节变化。显微技术估计的PA和生物量分布在春季风间期丰度最高，分别为2.29 ~ 4.41 × 106 Cells mL−1 ~ 8.39 ~ 21.82 μgL−1。夏季风后期（9月）浮游植物PA和生物量较高，分别为2.01 ~ 3.96 × 106 Cells mL−1 ~ 8.74 ~ 16.70 μgL-1，夏季风高峰期（8月）浮游植物丰度较高（叶绿素a ~ 14.57 mgm−3）。冬季季风，以低气压和浮游植物丰度开始。随着冬季季风的推进，对流混合促进了浮游植物的生长。腐烂释放溶解有机碳（DOC），导致1 - 2月PA升高，并在春季季风期（第一个峰值）达到峰值。随着夏季风的到来，上升流丰富了表层的营养物质，促进了8月份浮游植物的生长。随后的衰减阶段产生了较高的DOC，在夏季风结束时（第二次高峰）PA增强。然而，到11月，PA降至最低水平。基于距离的线性模型分析表明，温度和叶绿素a是影响上部光区PA的最主要因素，氨、溶解氧和DOC是相关因素。相比之下，营养物质是双光水体（200-2000米）的主要决定因素。本研究通过在阿拉伯海进行的大量采样工作，强调了在各种物理强迫下形成原核生物种群的物理化学和生物变量之间复杂的相互作用。图形抽象

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Spatial and temporal dynamics of prokaryotes in the Eastern Arabian sea

This study resolves the spatial and seasonal variations in prokaryotic abundance (PA) and biomass concerning physicochemical parameters during Spring Inter-Monsoon (April–May), Summer Monsoon (June–September), and Winter Monsoon (November–February) in the Eastern Arabian Sea. PA and biomass distribution estimated using microscopic techniques revealed their peak abundance during Spring Inter-Monsoon, ranging from 2.29–4.41 × 10⁶ Cells mL⁻¹ to 8.39–21.82 μgL⁻¹, respectively. Similarly, high PA and biomass were observed in late Summer Monsoon (September), ranging from 2.01–3.96 × 10⁶ Cells mL⁻¹ to 8.74–16.70 μgL^–1, respectively, which was preceded by a higher phytoplankton abundance (chlorophyll a- 14.57 mgm⁻³) during the peak Summer Monsoon (August). The Winter Monsoon, started with a low PA and phytoplankton abundance. As Winter Monsoon progressed, convective mixing promoted phytoplankton growth in the latter half until March. The decay released dissolved organic carbon (DOC), leading to a rise in PA from January to February, peaking during Spring Inter-Monsoon (first peak). With the advent of Summer Monsoon, upwelling enriched surface layers with nutrients to promote phytoplankton growth in August. The subsequent decaying phase generated higher DOC which enhanced PA by the end of Summer Monsoon (second peak). However, PA declined to its lowest levels by November. Distance-based linear model analysis indicated that temperature and chlorophyll a were the most influential factors affecting PA in the upper photic-zone, while ammonia, dissolved oxygen, and DOC were associated factors. In contrast, nutrients were the major determining factors in disphotic waters (200–2000 m). This study highlights the intricate interplay between physicochemical and biological variables in shaping prokaryotic populations during various physical forcings through intense sampling efforts in the Arabian Sea.

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来源期刊

Environmental Monitoring and Assessment 环境科学-环境科学

CiteScore

4.70

自引率

6.70%

发文量

1000

审稿时长

7.3 months

期刊介绍： Environmental Monitoring and Assessment emphasizes technical developments and data arising from environmental monitoring and assessment, the use of scientific principles in the design of monitoring systems at the local, regional and global scales, and the use of monitoring data in assessing the consequences of natural resource management actions and pollution risks to man and the environment.