To lock atmospheric
CO2 at anthropogenic timescale,
fast weathering silicates can be applied to soil to speed up natural
CO2 sequestration via enhanced weathering. Agricultural
lands offer large area for silicate application, but expected weathering
rates as a function of soil and crop type, and potential impacts on
the crops, are not well known. This study investigated the role of
plants on enhanced weathering of wollastonite (CaSiO3)
in soils. Using rooftop pot experiments with leguminous beans (Phaseolus vulgaris L.) and nonleguminous corn (Zea mays L.), CO2 sequestration was inferred
from total inorganic carbon (TIC) accumulation in the soil and thermogravimetric
analysis, and mineral weathering rate was inferred from alkalinity
of soil porewater. Soil amendment with wollastonite promoted enhanced
plant growth: beans showed a 177% greater dry biomass weight and corn
showed a 59% greater plant height and a 90% greater dry biomass weight.
Wollastonite-amended soil cultivated with beans showed a higher TIC
accumulation of 0.606 ± 0.086%, as compared to that with corn
(0.124 ± 0.053%). This demonstrates that using wollastonite as
a soil amendment, along with legume cultivation, not only buffers
the soil against acidification (due to microbial nitrogen fixation)
but also sequesters carbon dioxide (12.04 kg of CO2/tonne
soil/month, 9 times higher than the soil without wollastonite amendment).
Carbon dioxide (CO 2) is a major greenhouse gas, and its concentration in the atmosphere is increasing continuously, hence there is an urgent need to reduce its level in the atmosphere. Soils offer a large natural sink to store CO 2. This study focuses on sequestering CO 2 in the agricultural soils as inorganic carbon, which can be accomplished by adding alkaline-earth silicates. Wollastonite is used in this study as a soil amendment, to sequester CO 2 via the geochemical route of mineral carbonation. The first objective of the present study was to evaluate the effect of mixing a wide range of dosages of wollastonite, as a soil amendment, on the growth performance of two leguminous plants frequently used in agricultural sector: soybean and alfalfa. The plants were grown with different wollastonite dosages (3-20 kg•m −2 for soybean and 3-40 kg•m −2 for alfalfa), for a duration of 14 weeks in a microplot experiment in Ontario, Canada. The second objective was to find evidence of enhanced weathering of wollastonite in soil, in addition to the augmentation of inorganic carbon content in soil. For this, mineralogical assessment of the soils was performed using XRD and SEM-EDS analyses. Wollastonite increased the soybean yield by twofold in the plot amended with 10 kg•m −2. At all dosages, wollastonite increased the alfalfa growth in terms of height and above-ground biomass dry weight, as well as root biomass. The rate of CO 2 sequestration, at optimum wollastonite dosage, reached 0.08 kg CO 2 •m −2 •month −1. XRD and SEM-EDS analyses indicated accumulation of calcite in wollastonite-amended soil and formation of other weathering products. The results obtained from this study help to understand the impact of wollastonite soil amendment on agronomy, and will aid in implementing such negative emissions technology by informing farmers and industry alike that the use of wollastonite contributes toward global climate change mitigation while supporting crop yield. The findings of this study add to the existing body of knowledge on enhanced weathering as an atmospheric CO 2 removal technology, providing further evidence that wollastonite weathering in agricultural soils can lead to significant capacity for CO 2 sequestration as inorganic carbon, while concurrently promoting plant growth.
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