The Mechanisms Controlling the CO2 Outgassing of a Karst Spring–River–Lake Continuum: Evidence from Baotuquan Spring Drainage Area, Jinan City, Northern China

The significance of CO2 emissions at the water–air interface from inland water bodies in the global carbon cycle has been recognized and is being studied more and more. Although it is important to accurately assess CO2 emission flux in a catchment, little research has been carried out to investigate...

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Published inWater (Basel) Vol. 15; no. 14; p. 2567
Main Authors Liu, Wen, Zhang, Tao, Liu, Haoran, Ma, Pengfei, Teng, Yue, Guan, Qin, Yu, Lingqin, Liu, Chunwei, Li, Yiping, Li, Chuanlei, Li, Changsuo, Pu, Junbing
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.07.2023
Subjects
Automation
Carbon
Carbon cycle
Cellulose acetate
CO2 degassing
Drainage
Flow velocity
Groundwater
High density polyethylenes
Hydrology
karst spring–river–lake continuum
Lakes
photosynthesis
Precipitation
River ecology
water–air interface
United States > US
China
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Summary:The significance of CO2 emissions at the water–air interface from inland water bodies in the global carbon cycle has been recognized and is being studied more and more. Although it is important to accurately assess CO2 emission flux in a catchment, little research has been carried out to investigate the spatio-temporal variations in CO2 emissions in view of a water continuum. Here, we systematically compared the differences and control factors of CO2 degassing across the water–air interface of a spring–river–lake continuum in the discharge area of Baotuquan Spring in July 2017, which is a typical temperate karst spring area in Jinan city, northern China, using hydrogeochemical parameters, stable carbon isotope values, and CO2 degassing flux. Affected by the pCO2 concentration gradient between the water and ambient air, the spring water showed a high CO2 degassing flux (166.19 ± 91.91 mmol/(m2 d)). After the spring outlet, the CO2 degassing flux in the spring-fed river showed a slight increase (181.05 ± 155.61 mmol/(m2 d)) due to river flow rate disturbance. The river flow rate was significantly reduced by the “blockage” of the lake, which promoted the survival and reproduction of phytoplankton and provided favorable conditions for aquatic plant photosynthesis, increasing the plankton biomass in the lake to 3383.79 × 104/L. In addition, the significant decrease in the dissolved inorganic carbon (DIC) concentration and the increase in the δ13CDIC values in the lake also indicated that the photosynthesis of the lake’s aquatic plants resulted in a significant decrease in the pCO2 concentration, thus limiting the amount of CO2 off-gassing (90.56 ± 55.03 mmol/(m2 d)).
ISSN:2073-4441
2073-4441
DOI:10.3390/w15142567