March 3, 2026

Mineral ballast effect: dual potential of enhanced carbon sequestration and pollution reduction in karst lakes

Key Points

Enhanced carbon sequestration occurs through the coupling of minerals and organic matter, facilitating sedimentation.
The biological pump effect, driven by high levels of dissolved inorganic carbon, demonstrates significant ecosystem potential.
Phosphorus sequestration achieves long-term stability, reducing risks associated with water eutrophication in karst environments.
The findings highlight the need for innovative strategies in ecological carbon management and water quality improvement.

Abstract

喀斯特湖库系统受高溶解无机碳(DIC)背景驱动，表现出显著的水生生物泵(Biological Pump, BP)效应，但在展现高碳汇潜力的同时，面临水体富营养化风险，使得水环境质量与碳增汇目标深度交织。受限于喀斯特独特的区域地质背景，水体中天然压舱矿物效能不足，导致生成的内源有机碳(Autochthonous organic carbon, OCauto)极易在水柱中发生矿化损失。“压舱效应”通过矿物与有机质的结合，增加颗粒聚集体密度并显著提升下沉速度，不仅实现了有机碳向沉积物的快速转运，还通过物理-化学屏蔽作用有效降低了其在沉积环境的降解速率。同时，压舱矿物可携带表层藻类与磷元素共沉降，并通过促进磷由活性向更加惰性的形态转变，实现了长期的磷封存。本文系统综述了压舱效应作为喀斯特水体“减污降碳协同增效”策略的理论内涵，重点探讨了高钙背景下的矿物固碳机制与磷素长期稳定性，并明确了未来实际工程应用的前提约束与经济性，旨在为喀斯特地区生态固碳与水质安全治理双赢提供创新的科学路径。

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Mineral ballast effect: dual potential of enhanced carbon sequestration and pollution reduction in karst lakes

Key Points

Abstract

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