东北印度洋90°E海岭表层沉积物碳酸钙组成与影响因子*

doi:10.11978/2025001

Abstract

Abstract:

This study addresses the scientific question of the spatial differentiation mechanisms of calcium carbonate (CaCO₃) in surface sediments across the 90°E Ridge in the northeastern Indian Ocean, employing a multi-scale analytical approach to elucidate controlling factors and biogeochemical processes. Through bulk and size-fractionated ( > 150 μm, 63-150 μm, 38-63 μm, 25-38 μm, < 25 μm) CaCO₃ contribution analyses of surface sediments from 10 stations, combined with quantitative statistical analysis of scanning electron microscopy (SEM) microfeatures, the following findings were obtained: (1) The CaCO₃ content exhibits significant spatial variability (36.95%-74.76%, mean 56.05%), forming a tripartite gradient pattern of 30%-45%, 45%-60%, and 60%-75%. (2) In regions with water depths above 3000 m, the dominant CaCO₃ component is planktonic foraminiferal shells (> 150 μm, contributing > 65%), while stations near or above the lysocline are dominated by the < 25 μm fine-grained fraction (contribution > 58%). (3) Quantitative microfeature analysis reveals, for the first time, a co-deposition pattern of calcareous dinoflagellate fossils (relative abundance up to 73.68%) with coccoliths and foraminiferal fragments in the 25-38 μm fraction. Further investigations demonstrate that CaCO₃ distribution is governed by a ternary regulatory mechanism involving water depth-dependent dissolution effects, terrigenous clastic input, and siliceous biological dilution. This study innovatively establishes an integrated methodology of “grain-size separation-microscopic statistics-environmental interpretation”, which not only refines theoretical models of CaCO₃ distribution in seamount geomorphic units but also expands the understanding of deep-sea inorganic carbon reservoirs by identifying calcareous dinoflagellate fossils as a novel carbon source. The findings provide a critical case study for comparative research on CaCO₃ preservation mechanisms in global ridge systems and offer vital scientific insights for parameterizing marine carbon cycle models through improved algorithms for size-specific CaCO₃ flux calculations.

Key words: 90°E Ridge, surface sediments, calcium carbonate composition, particle size of calcium carbonates

CLC Number:

Q913

DU Shuhuan, XIANG Rong, SU Xiang, ZHANG Lanlan, PAN Zirui, XIE Jinwo, LUO Chuanxiu, WAN Sui. Calcium carbonate composition of surface sediments and influencing factors in the 90°E Ridge of the northeastern Indian Ocean^*[J].Journal of Tropical Oceanography, 2026, 45(1): 73-80.

Figures/Tables 6

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Tab. 1

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References 23

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样品号	经度	纬度	水深/m
22HN01	90°10′12″E	5°00′36″N	3573
22HN02	90°00′00″E	4°06′36″N	3830
22HN09	90°55′12″E	2°58′11″N	3083
23EI-01-BOX	89°33′36″E	4°40′48″N	3937
23EI-03	91°27′00″E	3°15′00″N	4157
23HN03	89°54′00″E	3°01′12″N	2553
23HN04	89°43′48″E	1°59′23″N	2746
23HN05	86°43′11″E	3°17′24″N	4208
23HN07	88°58′11″E	3°04′12″N	3733
23MG-04	90°14′23″E	3°58′11″N	2636

Calcium carbonate composition of surface sediments and influencing factors in the 90°E Ridge of the northeastern Indian Ocean^*

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[3]	, . null [J]. Journal of Tropical Oceanography, 2009, 28(3): 45-53.

Calcium carbonate composition of surface sediments and influencing factors in the 90°E Ridge of the northeastern Indian Ocean*

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Calcium carbonate composition of surface sediments and influencing factors in the 90°E Ridge of the northeastern Indian Ocean^*