Plant and Soil Responses to Concrete and Basalt Amendments Under Elevated CO 2 : Implications for Plant Growth, Enhanced Weathering and Carbon Sequestration

[Geoengineering News]

https://ideas.repec.org/a/gam/jagris/v15y2025i23p2435-d1802954.html

Authors: Haridian del Pilar León, Sara Martinez, María del Mar Delgado, José L. Gabriel, Sergio Alvarez

Abstract

The rise in greenhouse gases underscores the urgency of carbon dioxide removal (CDR) as a complement to emission reductions. Enhanced rock weathering (ERW) holds promise by coupling geochemical carbon sequestration with agronomic benefits, although integrative experimental evidence remains limited. This study evaluated two amendments (recycled concrete in wheat, C 3 , and basalt in maize, C 4 ) under ambient and elevated CO 2 conditions (~1000 ppm). Conducted in a greenhouse over 21 weeks using loam soils, the experiment evaluated four treatments comprising three different particle-size ranges (<2 mm, 2–6 mm, and 6–15 mm) and a control. Plant growth (height, total and partitioned biomass), grain quality (N and protein), and soil properties (pH, electrical conductivity, and carbonates) were measured. Elevated CO 2 enhanced biomass, particularly vegetative biomass in wheat (+42.6%) and root biomass in maize (+55%), without significantly increasing yield. In wheat, particle size was decisive: intermediate fractions (2–6 mm) yielded the best results. In maize, basalt effects were less consistent. Concrete amendments increased soil pH and carbonate content, especially with coarse particles and elevated CO 2 , whereas basalt-induced responses were slower and more variable. These findings confirm the potential of ERW as a dual climate–agronomic strategy while highlighting the need for long-term, field-scale validation.

Source: Ideas