Effects of soil moisture content on CO2 triggered soil physicochemical properties in a near-surface environment
- Authors
- Derakhshan-Nejad, Zahra; Lee, Woojin; Han, Seunghee; Choi, Jaeyoung; Yun, Seong-Taek; Lee, Giehyeon
- Issue Date
- 2020-04
- Publisher
- SPRINGER HEIDELBERG
- Citation
- JOURNAL OF SOILS AND SEDIMENTS, v.20, no.4, pp.2107 - 2120
- Abstract
- Purpose Carbon capture and storage (CCS) has been frequently discussed as a strategy for meeting CO2 emission reduction and its targets. However, some critical issues have been raised with regard to the potential hazards to near-surface environments by CO2 leakage. Hence, this study was conducted to examine the effects of soil moisture content on the potential risks associated with a high concentration of CO2 to change physicochemical properties of a near-surface soil. Materials and methods Soil samples for a batch experiment were collected from an abandoned gold mine, South Korea. Batch experiments were conducted in a specially designed CO2 glove box (95-99 vol.% CO2) at four different moisture contents (0, 15, 27.5 wt.%, and a suspension of soil to water ratio 1:10) and different reaction times up to 30 days. A control experiment was conducted at the ambient conditions open to the atmosphere otherwise the same conditions. Physicochemical properties of the soil samples (i.e., pH, mineralogy, organic matter (OM), inorganic carbon (IC), and cation exchange capacity (CEC)) as well as leachability of metal(loid)s were examined before and after the CO2 incubation. Results and discussion Results showed that the pH of the CO2-incubated partially wet (15 and 27.5 wt.%) and suspension samples rapidly decreased by about one unit (P < 0.01) in 2 h and gradually recovered in 10 days. It was noteworthy that CO2 was adsorbed to the dry soil (0 wt.%) and led to acidification as the soil pH dropped from 5.56 +/- 0.02 to 4.5 +/- 0.03. Soil organic matter content and cation exchange capacity decreased with increasing moisture content in the CO2-incubated samples. A noticeable increase in the leachability of Fe, Al, Ca, Mg, Mn, K, and Zn were observed in the CO2-incubated soil suspensions. In contrast, the leachability of metal(loid)s in the dry and partially wet samples were not remarkable, although the soil pH decreased significantly. Conclusions Our findings highlighted the effect of CO2 exposure on the soil acidification, even to soils in unsaturated zones, and stressed to monitor simultaneously soil physicochemical properties and metal(loid)s leaching induced by CO2 exposure in the near-surface environment.
- Keywords
- DISSOLVED ORGANIC-CARBON; ELEVATED CO2; METAL(LOID) MOBILIZATION; ELECTRICAL-CONDUCTIVITY; FOREST SOILS; DIOXIDE; MATTER; LEAKAGE; PH; CHEMISTRY; DISSOLVED ORGANIC-CARBON; ELEVATED CO2; METAL(LOID) MOBILIZATION; ELECTRICAL-CONDUCTIVITY; FOREST SOILS; DIOXIDE; MATTER; LEAKAGE; PH; CHEMISTRY; CO2 leakage; Soil moisture content; Near-surface environment; Soil acidification; Metal(loid)s leaching
- ISSN
- 1439-0108
- URI
- https://pubs.kist.re.kr/handle/201004/118795
- DOI
- 10.1007/s11368-020-02585-4
- Appears in Collections:
- KIST Article > 2020
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