This study explored the ecological functions and environmental effects of soil microorganisms in the black soil region by examining microbial carbon source metabolic capacity across four vegetation types (reed wetland, maize field, paddy field, aspen woodland) and three soil types (Histosols, Planosols, Gleysols) in the Naoli River Reserve, with soil samples collected at a depth of 0–20 cm. Using Biolog-ECO microplate technology, we assessed soil microbial carbon source metabolic activity, utilization patterns, and functional diversity. Structural equation modeling and random forest analysis were applied to explore the influence of environmental factors on microbial carbon metabolism. Results showed that microbial carbon metabolic activity was highest in maize fields and Histosols, exceeding that in paddy fields and Gleysols. Microorganisms preferred amino acids, polymers, and carboxylic acids over carbohydrates, amines, and phenolic acids. The Simpson index of microbial diversity was positively correlated with microbial biomass carbon and moisture content, while Chao1 and Ace indices were correlated with microbial biomass phosphorus. Key microbial phyla, such as Bacteroides and Monomonas, were closely related to carbon source utilization. The structural equation modeling indicated that microbial biomass carbon, microbial biomass nitrogen, and soil organic carbon were the main drivers of microbial carbon metabolism. The RF model identified i-erythritol as a key predictor of microbial carbon metabolism, and amines as the best predictor of average well color development (AWCD) changes. The McIntosh index was the most influential variable for AWCD variation. These findings provide a scientific basis for evaluating soil health and supporting sustainable black soil management.