Salinity is an important factor in carbon emissions from an inland lake in arid region

Saline lakes, serving as the ultimate destination for most hydrological systems, accumulate substantial amounts of nutrients and organic matter from basins, and act as vast carbon reservoirs. These lakes exhibit exceptionally active biogeochemical cycling processes of carbon dioxide (CO2) and methane (CH4), and constitute integral components of the global carbon cycle. However, understanding of greenhouse gas emissions from saline lakes remains unclear mostly due to scarce data. In this study, we obtained CO2 and CH4 diffusive fluxes and biogeochemical parameters during ice-free period of 2021 at Bosten Lake, which is a representative inland saline lake located in China's arid region. Results revealed that Bosten Lake was a significant source of atmospheric gas carbon emissions, with average diffusion emissions of 12.645 +/- 3.475 mmol m(-2) d(-1) for CO2 and 0.279 +/- 0.069 mmol m(-2) d(-1) for CH4. Temporally, field measurements found a positive correlation between conductivity (Spc, a proxy of salinity) and CO2 emissions (R-2 = 0.50, p < 0.01). Furthermore, the CH4 diffusive fluxes increased with the trophic state index (TSI, R-2 = 0.31, p < 0.01). Spatially, exogenous inputs led to the spatial heterogeneity of carbon emissions. Our results highlighted that temporal variations in salinity constitute a crucial factor influencing CO2 emissions, and the saline lake has greater global warming potential compared to freshwater. The study provides an in-depth analysis of greenhouse gas emissions and driving factors in saline lakes of arid regions, and supports a further understanding of the carbon cycle in different types of lakes.

Automated summary

Saline lakes are integral components of the global carbon cycle and play a significant role in greenhouse gas emissions. This study focuses on Bosten Lake, an inland saline lake in China, and reveals that it is a significant source of atmospheric carbon emissions. The emissions are influenced by temporal variations in salinity and trophic state. Additionally, spatial heterogeneity in carbon emissions is driven by exogenous inputs. This study provides valuable insights into greenhouse gas emissions from saline lakes in arid regions and contributes to a better understanding of the carbon cycle in different types of lakes.