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Auteurs principaux: Lin, Xin, Li, Canru, Hutchins, David A, Luo, Haodong, Yan, Ningxin, Li, Yan, Jiang, Yuan, Cao, Zhimian, Dai, Minhan
Format: Artículo científico
Langue:en
Publié: Environmental science & technology 2026
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Accès en ligne:https://pubmed.ncbi.nlm.nih.gov/41863780/
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author Lin, Xin
Li, Canru
Hutchins, David A
Luo, Haodong
Yan, Ningxin
Li, Yan
Jiang, Yuan
Cao, Zhimian
Dai, Minhan
author_facet Lin, Xin
Li, Canru
Hutchins, David A
Luo, Haodong
Yan, Ningxin
Li, Yan
Jiang, Yuan
Cao, Zhimian
Dai, Minhan
Lin, Xin
Li, Canru
Hutchins, David A
Luo, Haodong
Yan, Ningxin
Li, Yan
Jiang, Yuan
Cao, Zhimian
Dai, Minhan
collection PubMed - marine biology
contents Olivine-Induced Alkalinity Enhancement Amplifies Phytoplankton Carbon Export Efficiency. Lin, Xin Li, Canru Hutchins, David A Luo, Haodong Yan, Ningxin Li, Yan Jiang, Yuan Cao, Zhimian Dai, Minhan Phytoplankton Carbon Diatoms Iron Compounds Silicates Carbon Dioxide Magnesium Compounds Ocean alkalinity enhancement (OAE) via olivine addition is a promising carbon dioxide (CO) removal strategy, yet its impact on phytoplankton-driven biogeochemical processes remains unclear. We investigated the effects of olivine on the diatom () and the coccolithophore (;calcifying and noncalcifying strains). Olivine addition increased total alkalinity across all cultures, although the increase was less pronounced in calcifying . Notably, olivine stimulated growth and particulate organic carbon production in and calcifying , while noncalcifying strains showed no significant response. Olivine addition dramatically accelerated sinking rates, which increased 9.36-fold for and 2.39-fold for calcifying . This enhancement was driven by distinct mechanisms: silicon-mediated ballasting in diatoms and extracellular polysaccharide-induced cell-olivine aggregation in coccolithophores, alongside minor silicon deposition on coccoliths. These results indicate that olivine-based OAE could increase CO drawdown through two independent mechanisms and may potentially strengthen the biological pump by accelerating organic matter export. Our findings suggest that olivine addition could serve as a potent approach for enhancing carbon export efficiency, with diatoms exhibiting a stronger response than coccolithophores, although its ecological impacts will require further investigation.
format Artículo científico
id pubmed_41863780
institution PubMed
language en
publishDate 2026
publisher Environmental science & technology
record_format pubmed
spellingShingle Olivine-Induced Alkalinity Enhancement Amplifies Phytoplankton Carbon Export Efficiency.
Lin, Xin
Li, Canru
Hutchins, David A
Luo, Haodong
Yan, Ningxin
Li, Yan
Jiang, Yuan
Cao, Zhimian
Dai, Minhan
Phytoplankton
Carbon
Diatoms
Iron Compounds
Silicates
Carbon Dioxide
Magnesium Compounds
Olivine-Induced Alkalinity Enhancement Amplifies Phytoplankton Carbon Export Efficiency. Lin, Xin Li, Canru Hutchins, David A Luo, Haodong Yan, Ningxin Li, Yan Jiang, Yuan Cao, Zhimian Dai, Minhan Phytoplankton Carbon Diatoms Iron Compounds Silicates Carbon Dioxide Magnesium Compounds Ocean alkalinity enhancement (OAE) via olivine addition is a promising carbon dioxide (CO) removal strategy, yet its impact on phytoplankton-driven biogeochemical processes remains unclear. We investigated the effects of olivine on the diatom () and the coccolithophore (;calcifying and noncalcifying strains). Olivine addition increased total alkalinity across all cultures, although the increase was less pronounced in calcifying . Notably, olivine stimulated growth and particulate organic carbon production in and calcifying , while noncalcifying strains showed no significant response. Olivine addition dramatically accelerated sinking rates, which increased 9.36-fold for and 2.39-fold for calcifying . This enhancement was driven by distinct mechanisms: silicon-mediated ballasting in diatoms and extracellular polysaccharide-induced cell-olivine aggregation in coccolithophores, alongside minor silicon deposition on coccoliths. These results indicate that olivine-based OAE could increase CO drawdown through two independent mechanisms and may potentially strengthen the biological pump by accelerating organic matter export. Our findings suggest that olivine addition could serve as a potent approach for enhancing carbon export efficiency, with diatoms exhibiting a stronger response than coccolithophores, although its ecological impacts will require further investigation.
title Olivine-Induced Alkalinity Enhancement Amplifies Phytoplankton Carbon Export Efficiency.
topic Phytoplankton
Carbon
Diatoms
Iron Compounds
Silicates
Carbon Dioxide
Magnesium Compounds
url https://pubmed.ncbi.nlm.nih.gov/41863780/