CO2 emission response to different water conditions under simulated karst environment

Habitat degradation has been proven to result associated with drought in karst region in south China. However, how this drought condition relates to CO₂ efflux is not clear. In this study, we designed a simulated epikarst water–rock (limestone)–soil–plant columns, under varying water levels (treatme...

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Bibliographic Details
Published in:Environmental earth sciences 2015-07, Vol.74 (2), p.1091-1097
Main Authors: Yuqing, Huang, Yanyu, Li, Guangping, Xu, Chengxin, He, Ling, Mo, Zhongfeng, Zhang, Jianhua, Cao, Daxing, Gu, Chunlai, Zhang, Yigang, Wei, Fang, Wen
Format: Article
Language:English
Subjects:
Biogeosciences
Carbon dioxide
Carbon dioxide emissions
corrosion
Drought
Earth and Environmental Science
Earth Sciences
Environmental degradation
Environmental Science and Engineering
Geochemistry
Geology
greenhouse gas emissions
habitat destruction
Habitats
High temperature
Hydrology/Water Resources
Karst
karsts
Limestone
Low temperature
Moisture content
Simulation
soil quality
soil respiration
Soil surfaces
Soil water
soil water content
Studies
Summer
temperature
Terrestrial Pollution
Thematic Issue
Water content
Water levels
Water supply
Water treatment
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Summary:Habitat degradation has been proven to result associated with drought in karst region in south China. However, how this drought condition relates to CO₂ efflux is not clear. In this study, we designed a simulated epikarst water–rock (limestone)–soil–plant columns, under varying water levels (treatment), and monitored CO₂ concentration and efflux in soil in different seasons during 2011. The results showed that increased soil water greatly enhanced CO₂ concentrations. With which treatment with epikarst water (WEW) had higher CO₂ concentration than without epikarst water (WOEW). This was particularly high in low soil water treatment and during high temperature in the summer season. Under 30–40 % relative soil water content (RSWC), CO₂ concentration in WEW treatment was 1.44 times of WOEW; however, under 90–100 % RSWC, this value was smaller. Comparatively, soil surface CO₂ efflux (soil respiration) was 1.29–1.94 μmol m⁻² s⁻¹ in WEW and 1.35–2.04 μmol m⁻² s⁻¹ in WOEW treatment, respectively. CO₂ efflux increased with increasing RSWC, but it was not as sensitive to epikarst water supply as CO₂ concentration. WEW tended to weakly influence CO₂ efflux under very dry or very wet soil condition and under low temperature. High CO₂ efflux in WEW occurred under 50–80 % RSWC during summer. Both CO₂ concentrations and CO₂ efflux were very sensitive to temperature increase. As a result, at degraded karst environment, increased temperature may enhance CO₂ concentration and CO₂ emission; meanwhile, the loss of epikarst and soil water deficiency may decrease soil CO₂ concentration and CO₂ emission, which in turn may decrease karst corrosion.
ISSN:1866-6280
1866-6299
DOI:10.1007/s12665-015-4539-8