Vegetation Density Modulates Spatiotemporal Variations of CO2 Emission in Urban Aquatic Systems

Abstract

Urban aquatic systems serve as significant contributors to atmospheric carbon dioxide (CO₂) emissions, playing a critical role in greenhouse gas (GHG) budgets. Aquatic vegetation is widely implemented in urban water management for ecological restoration and landscape construction, while its spatial configuration and planting density critically regulate the CO₂ flux (FCO₂) at the water–air interface. This study examines spatiotemporal variations and environmental drivers of FCO₂ across different vegetation patterns in the Qingshangang (QSG) River and Lihu Lake (LH) continuum. The FCO₂ exhibited pronounced seasonality, with significantly higher emissions during the wet season (QSG: 74.76 ± 61.95 mmol/m²/d; LH: 62.81 ± 39.08 mmol/m²/d) compared to those during the dry season (QSG: 40.13 ± 44.89 mmol/m²/d; LH: 9.41 ± 15.02 mmol/m²/d). Structural equation model (SEM) identified dissolved oxygen (DO) and pH as key direct controls of FCO₂, while dissolved organic matter (DOM) contributed indirectly. Sites with dense emergent macrophytes exhibited significantly higher FCO₂ levels, highlighting vegetation density as a primary factor shaping spatial heterogeneity in CO₂ emissions. Our findings emphasize the need to consider vegetation spatial distribution in urban aquatic ecosystem design and management for greenhouse gas mitigation strategies.