Global Warming Potential Induced by Albedo and Greenhouse Gases Across Different Land Uses of the Saline-Alkaline Agropastoral Ecotone in the Songnen Plain

Land-use change contributes significantly to climate change mitigation through biophysical changes (albedo, α) and biogeochemical (greenhouse gases, GHG) emissions (here refers to methane, CH4, and nitrous oxide, N2O). While the impact of grassland–cropland conversion on global warming potential (GWP) is well-documented globally, research remains scarce in the saline-alkaline agropastoral transition zone (APTZ) of the western Songnen Plain, Northeast China, an ecotone uniquely characterized by soil-crusting and seasonal inundation. We conducted in situ bi-weekly measurements of N2O and CH4 fluxes (June–September) to acquire growing season GWPN2O and GWPCH4, alongside α. The study compared an undisturbed fenced meadow (FMD) with three adjacent land-use types, clipped meadow (CMD), saline-alkaline meadow (SAL), and paddy rice field (PDY), converted from FMD from 2018 to 2022. Annual α-induced GWP (GWPΔα) was positive across all converted sites (CMD, SAL, and PDY), indicating a warming effect due to lower α compared to FMD. The PDY exhibited the highest CH4 emission (5.04 kg CO2 m−2 yr−1), exceeding other land uses by three orders of magnitude (p < 0.05). Conversely, N2O emissions remained consistently minimal and stable across all sites. When integrating the net ecosystem exchange of CO2 (NEE), the PDY functioned as a net warming source. In contrast, the warming effects of α and non-CO2 GHGs were effectively offset by the NEE in other land uses. Machine learning identified soil water content (SWC) as the dominant predictor of α across all land uses in growing season. However, a mechanistic divergence was observed, i.e., α in low saline-alkali ecosystems (FMD, CMD and PDY) was shaped by coupled biotic and soil moisture controls, whereas in the degraded SAL ecosystem, α is almost exclusively abiotic-driven. These findings demonstrate that land-use conversion in the Songnen Plain governs complex land-surface feedbacks through distinct pathways. This study provides a quantitative framework for integrating ...