Aims: Land-use and land-cover (LULC) dynamics are central drivers of terrestrial Carbon fluxes. This study aimed to assess the spatial heterogeneity of Carbon storage in the Kojur Watershed and to determine how topographic factors influence Carbon sequestration across historical and projected timeframes.
Materials & Methods: LULC maps for 2003, 2013, and 2023 were generated using satellite imagery and the Land Change Modeler (LCM). Future scenarios for 2035 and 2050 were simulated using the Cellular Automata Markov (Ca-Markov) model under a business-as-usual assumption, which projected historical land-use transitions and socio-economic trends forward. The InVEST Carbon module estimated Carbon storage in four pools: aboveground biomass, belowground biomass, litter, and soil. Spatial clustering was analyzed using Moran’s I and Getis-Ord Gi* statistics.
Findings: Carbon storage showed a consistent, statistically significant clustered pattern across all years. Forests held the most Carbon (≈2.5-2.6 million tons), rangelands moderate (≈1.2-1.5 million tons), rainfed agriculture less (≈0.2-0.3 million tons), and residential areas minimal (<0.01 million tons). Moran’s I values (0.35-0.54) confirmed strong spatial dependence. Hotspot zones expanded from 28.93% in 2003 to 32.90% in 2050, while coldspots also grew slightly, indicating an increase in spatial polarization. Higher elevations and moderate slopes generally store more Carbon due to denser forest cover and reduced human activity.
Conclusion: The Kojur Watershed exhibits a stable, clustered pattern of Carbon storage. Hotspot zones serve as vital Carbon reservoirs for climate mitigation. Preserving these areas and restoring low-Carbon zones offer a strategic path for sustainable resource management and enhanced ecosystem services.