Abstract
INTRODUCTION: Forest aboveground biomass (AGB) is a critical carbon reservoir, and forest aboveground carbon stock (AGCS) is an important indicator of ecosystem carbon sequestration potential. However, accurate regional-scale AGCS mapping remains challenging in data-scarce regions because sparse field samples and strong spatial heterogeneity can lead to unstable errors that are difficult to quantify in both traditional and machine-learning regression models. METHODS: To address this issue, we developed a Probabilistic Soft-Classification-Expectation Fusion (PSC-EF) framework for small-sample AGCS estimation in Huize County, China. The framework integrates Landsat 5 and ALOS PALSAR imagery with 42 field plots. It first uses a multi-source feature classifier to generate pixel-wise probability maps for three carbon-density classes, then reconstructs a continuous AGCS surface through expectation fusion, and finally quantifies uncertainty using variance propagation and bootstrap resampling. RESULTS: Under 2×2 spatial block cross-validation, PSC-EF achieved a root mean square error (RMSE) of 182.13 Mg C ha(-1), a mean absolute error (MAE) of 150.92 Mg C ha(-1), and a bias of -4.64 Mg C ha(-1) for continuous AGCS estimation. The probability maps showed a coherent low-to-high carbon gradient, and the total AGCS estimate for Huize County was consistent, with overlapping 95% confidence intervals derived from bootstrap resampling (4.54-5.18 × 10(7) Mg C) and variance propagation (4.84-4.85 × 10(7) Mg C). DISCUSSION: The PSC-EF framework enables continuous AGCS mapping from probabilistic class membership while providing uncertainty information suitable for spatial decision-making. This framework provides spatially explicit carbon stock estimates with quantified uncertainty, supporting local carbon management and offering a transferable approach for AGCS assessment in other data-scarce regions.