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Balancing organic and inorganic carbon dynamics in enhanced rock weathering: Implications for carbon sequestration.
Glob. Change Biol. 31:e70186 (2025)
Enhanced rock weathering (ERW) is a promising strategy for CO2 removal via promoting inorganic carbon (IC) sequestration. However, knowledge gaps persist regarding its influence on the largest terrestrial carbon pool, soil organic carbon (SOC) and how these effects evolve as weathering progresses. This study investigated how basalt weathering influences soil carbon fluxes and organic matter (OM) turnover. Over a 6th-month incubation, we applied fresh basalt (fine-sized, olivine-rich) and weathered basalt (coarse- and fine-sized, olivine-depleted) to temperate cropland topsoil, incorporating with 13C-labelled straw. Fresh basalt increases soil pH via rapid H+ neutralization during olivine dissolution, releasing soluble Mg2+ and increasing bicarbonate alkalinity. Combined with continuous carbonic acid dissociation for olivine dissolution, they synergistically enhance dissolved inorganic carbon (DIC) accumulation in soil solution and effluent (~0.4%), promoting soil inorganic carbon (SIC) accrual via carbonate precipitation (~4%). However, rising pH concurrently induces significant SOC losses (~17%), resulting in net C losses of ~13%. As basalt weathering progresses (olivine-depleted), slower H+ neutralization and carbonic acid dissociation during less-reactive Ca-bearing mineral dissolution stabilize soil pH, limiting DIC formation. The released Ca2+ prioritizes SIC accrual via Ca-carbonate precipitation (~4%). Meanwhile, higher specific surface area (SSA) and exchangeable Ca2+ enhance retention and stabilization of both native and straw-derived OC, reducing net C losses (~6%). At both weathering stages, over 95% of total C remaining in soils and effluent exists in organic form. Straw inputs acidify soils by releasing additional free H+ during decomposition, competing with carbonic acid for olivine dissolution and reducing bicarbonate alkalinity, which limits the DIC and SIC accrual at both weathering stages. Since soils continuously receive OM input, understanding the balance between these interactive processes is crucial for optimizing long-term carbon sequestration strategies. Therefore, sustaining SOC by minimizing SOC losses should be prioritized for long-term carbon sequestration, besides IC accrual for ERW, particularly as weathering progresses.
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Publication type
Article: Journal article
Document type
Scientific Article
Keywords
13c Isotopic Tracing ; Basalt Weathering ; Carbon Sequestration ; Inorganic Carbon Formation ; Organic And Inorganic Carbon Pools ; Organic Carbon Turnover ; Rising Ph ; Soil Carbon Fluxes; Hydraulic Conductivity; Soil
Language
english
Publication Year
2025
HGF-reported in Year
2025
ISSN (print) / ISBN
1354-1013
e-ISSN
1365-2486
Journal
Global Change Biology
Quellenangaben
Volume: 31,
Issue: 4,
Article Number: e70186
Publisher
Wiley
Publishing Place
111 River St, Hoboken 07030-5774, Nj Usa
Reviewing status
Peer reviewed
Institute(s)
Research Unit Environmental Simulation (EUS)
POF-Topic(s)
30202 - Environmental Health
Research field(s)
Environmental Sciences
PSP Element(s)
G-504911-001
Grants
Bayerisches Staatsministerium für Umwelt und Verbraucherschutz
WOS ID
001468131700001
Scopus ID
105003128585
PubMed ID
40237220
Erfassungsdatum
2025-05-10