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研究生: 桂思緹
Acabado, Cristy Sales
論文名稱: 黑潮流域海底山之克赫波(Kelvin-Helmholtz billows)對海洋上層生態系統的影響
The Response of Epipelagic Ecosystems to Kelvin-Helmholtz Billows over a Seamount in the Kuroshio
指導教授: 陳仲吉
Chen, Chung-Chi
張明輝
Chang, Ming-Huei
口試委員: 夏復國
Shiah, Fuh-Kwo
謝志豪
Hsieh, Chih-hao
町田龍二
Machida, Ryuji
陳仲吉
Chen, Chung-Chi
張明輝
Chang, Ming-Huei
口試日期: 2022/01/18
學位類別: 博士
Doctor
系所名稱: 生命科學系
Department of Life Science
論文出版年: 2022
畢業學年度: 110
語文別: 英文
論文頁數: 159
中文關鍵詞: 克赫波硝酸鹽通量海底山黑潮超微浮游生物浮游動物
英文關鍵詞: Kelvin-Helmholtz billows, Nitrate flux, Seamount, The Kuroshio, Picoplankton, Zooplankton
研究方法: 實驗設計法現象學調查研究比較研究觀察研究田野調查法
DOI URL: http://doi.org/10.6345/NTNU202200326
論文種類: 學術論文
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  • 克赫波可以驅動流經貧營養鹽黑潮在海底山周邊小尺度的海水混合。本研究目標主要探討不同之克赫波强度(或大小),包括「間歇小型」的小波狀況(small billow case; SBC)與「穩定大型」的大波狀况(large billow case; LBC)之克赫波對本海域硝酸鹽垂直通量的影響,並進一步瞭解其在海底山周遭生態系,不同環境條件下對超微型浮游生物及浮游動物組成之影響(第一章)。克赫波所造成之亂流動能耗散率 (turbulent kinetic energy dissipation rate; ε = O (10-7–10-6) W kg-1) 及渦流擴散率 (eddy diffusivities; Kρ = O (10-4–10-3) m2 s-1) 明顯高於無克赫波(時),利用在此波內 Kρ 所估算之平均硝酸鹽通量最大值為 10.0 mmol m-2 day-1,此值遠高於黑潮流域之平均值(第二章);在較淺層形成的克赫波所攜入的硝酸鹽通量,將豐富次表層海域的無機營養鹽濃度;而靠近海底山頂較深的克赫波,則將會更有效率的從更深層水體中垂直向上傳輸豐富的硝酸鹽。另一方面,海底山周遭海域的超微浮游生物主要以異營性細菌為主(>50%; 第三章);然而,由於聚球藻生物量的增加,在海底山測站超微浮游生物的結果顯示出與近岸海域相似的生物碳量;此結果建議在貧營養鹽水體的黑潮流域,其海底山及其周圍海域有類似沿岸海域海水的特性。另外,在冬季航次時黑潮有較強勁流速,其浮游動物生物量(SKC; 104.5 ml 100m-3)較夏季航次黑潮流速較弱時(WKC; 33.7 ml 100m-3)高出60%以上,但此差異可能主要是受到季節性的影響所致(第四章);另外,由浮游動物豐度的分布結果,顯示出海底山地形所形成的「阻塞效應」(blocking effect),會將它們聚集在海底山周遭與其側翼;然而,較強的黑潮海流時(例如SKC)可消除阻塞效應,並將浮游生物快速帶往下游。而在海底山周遭亦觀測到仔稚魚個體早期發育階段,顯見海底山有利於作為魚類產卵和繁殖的棲地。整體而言,本研究顯示黑潮流域海底山之克赫波,對海底山生態系统之養分循環與垂直混和,對此海域的生產力與下游能量具有重要貢獻,並顯示海底山在貧養鹽黑潮海域扮演生命綠洲的角色。

    Kelvin-Helmholtz (KH) billows can drive microscale turbulent mixing around seamounts in the oligotrophic Kuroshio. This study sought to describe the influence of billow intensity, i.e., “intermittent and small” (small billow case; SBC) and “steady and large” billows (large billow case; LBC), on vertical nitrate fluxes, and to illustrate the responses of picoplankton and zooplankton assemblages to the varying environmental conditions on seamounts (Chapter 1). KH billows led to turbulent kinetic energy dissipation rates (ε = O (10-7–10-6) W kg-1) and eddy diffusivities (Kρ = O (10-4–10-3) m2 s-1) that were significantly stronger than those outside the billow depths. The mean nitrate flux estimated using Kρ in the billow depths had a maximal value of 10.0 mmol m-2 day-1, which was much higher than estimates for the open ocean (Chapter 2). The nitrate flux associated with the shallow KH billows contributed to subsurface enrichment by entraining existing nutrients, while the flux of deeper billows closer to the summit were more effective in vertically transporting nitrates directly from the deeper water. On the other hand, the picoplankton around the seamount area was consistently dominated by heterotrophic bacteria (>50%; Chapter 3). The on-seamount station showed similar carbon biomass in comparison with those in onshore areas due to the increase in Synechococcus biomass. This suggests that a small area along the Kuroshio features coastal water-like properties near and around the seamount in oligotrophic waters. In addition, the zooplankton biomass was over 60% larger during the winter cruise when the Kuroshio’s velocity was strong (SKC; 104.5 ml 100m-3) than in the summer cruise when the Kuroshio was weaker (WKC; 33.7 ml 100m-3), and this variation was more likely influenced by the sampling season (Chapter 4). Furthermore, the distribution pattern of zooplankton concentrations revealed a seamount-induced “blocking effect”, which aggregates them within the impeding seamount and its flanks. However, a strong Kuroshio current can dismantle the blocking effect and quickly sweep the plankton away (i.e., SKC). Moreover, the high relative contributions of very early ontogenetic stages of larval fish underscored the importance of the seamount as an isolated habitat good for spawning and as a source of fish recruits. Overall, this study showed that KH billows make important contributions to seamount ecosystems, particularly in the cycling and vertical mixing of nutrients to make them available for local production and potential downstream transport. At the same time, this study exemplified the role of seamounts as the oasis of life in oligotrophic areas.

    Table of Contents Acknowledgments i 摘要 iv English Abstract vi Table of Contents viii List of Tables xii List of Figures xiii CHAPTER 1: GENERAL INTRODUCTION 1 1.1 The oligotrophic Kuroshio 1 1.2 Related studies on seamount biology 4 1.3 The goal of this research 7 CHAPTER 2: VERTICAL NITRATE FLUX INDUCED BY KELVIN-HELMHOLTZ BILLOWS OVER A SEAMOUNT IN THE KUROSHIO 9 Abstract 9 2.1 Introduction 10 2.2 Materials and Methods 12 2.2.1 Sampling stations and physical parameters 12 2.2.2 Nitrate and chlorophyll a analysis 14 2.2.3 Estimation of turbulent kinetic energy (ε), eddy diffusivity (Kρ), and vertical nitrate flux (FNO3) 15 2.3 Results 16 2.3.1 Oceanographic context and the relationship between TKE dissipation rates and KH instabilities 16 2.3.2 Vertical profiles of variables on the K seamount 18 2.3.3 KH billow-induced turbulence and vertical nitrate fluxes 19 2.4 Discussions 21 2.4.1 Hydrographic conditions and response to variable KH billow intensities over time 21 2.4.2 Importance of KH billows as a driver for vertical nitrate flux in the Kuroshio 23 2.4.3 Impact of KH billow-induced vertical nitrate flux to the oligotrophic Kuroshio’s enhanced productivity 25 2.5 Conclusions 27 2.6 Figures and Tables 30 CHAPTER 3: ASSESSMENT COMPARISON OF PICOPLANKTON COMMUNITIES BETWEEN A SEAMOUNT AND NON-SEAMOUNT REGIONS ALONG THE KUROSHIO 39 Abstract 39 3.1 Introduction 41 3.2 Materials and methods 43 3.2.1 Sampling stations and physical parameters 43 3.2.2 Nitrate and Chl a analysis 44 3.2.3 Picoplankton collection and enumeration 45 3.3 Results 46 3.3.1 Hydrographic conditions on the K seamount and along the KTV1 transect 46 3.3.2 The vertical distribution of picoplankton abundance 48 3.3.3 Picoplankton carbon biomass on and off the K seamount and along a non-seamount transect 49 3.4 Discussions 51 3.4.1 Comparison of the oceanographic conditions on the K seamount and a non-seamount transect 51 3.4.2 Picoplankton biomass and distribution in the non-seamount region 52 3.4.3 Picoplankton biomass and distribution on the K seamount 53 3.4.4 The influence of environmental factors on picoplankton communities 55 3.5 Conclusions 56 3.6 Figures 59 CHAPTER 4: VARIABILITY IN THE ZOOPLANKTON AND ICHTHYOPLANKTON AGGREGATION AND DISTRIBUTION OVER A SEAMOUNT IN THE KUROSHIO 69 Abstract 69 4.1 Introduction 71 4.2 Materials and methods 73 4.2.1 Oceanographic surveys and sampling stations 73 4.2.2 Physical, chemical, and chlorophyll a measurements 75 4.2.3 Zooplankton and ichthyoplankton sampling 76 4.3 Results 79 4.3.1 Hydrography and concentrations of nitrate and Chl a in WKC and SKC 79 4.3.2 Zooplankton distribution around (on and off) the seamount in WKC and SKC and in non-seamount regions 80 4.3.3 Ichthyoplankton aggregations on- and off-seamount 81 4.3.4 Ecological indices of zooplankton and ichthyoplankton around the seamount in varying environmental conditions 83 4.4 Discussions 85 4.4.1 The varying hydrographic environment on the K seamount 85 4.4.2 Zooplankton and ichthyoplankton abundance between seamount and non-seamount regions 86 4.4.3 The distribution patterns of zooplankton on- and off-seamount during the WKC and SKC 88 4.4.4 The distribution patterns of ichthyoplankton on- and off-seamount during the WKC and SKC 90 4.4.5 The response of the biological communities to varying environmental conditions 91 4.5 Conclusions 93 4.6 Figures and Tables 96 CHAPTER 5: GENERAL CONCLUSIONS 112 References 116 Appendices 137

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