Chen Chaoqun, Dai Huimin, Liu Kai, Tang Yulei
Shenyang Center of China Geological Survey, Shenyang 110034, China.
Northeast Geological S&T Innovation Center of China Geological Survey, Shenyang 110034, China.
Sensors (Basel). 2025 Sep 2;25(17):5442. doi: 10.3390/s25175442.
The black soil region of northeast China is a critical global grain production base. The dynamic variations in soil organic carbon (SOC) are directly linked to the regional food security. To accurately monitor SOC content and evaluate the potential of integrating Landsat-9 and GF-1 satellite data for SOC inversion, we developed a machine learning framework that combines data from both satellite sources to model SOC. Using the typical black soil region of northeast China in the Tongken River Basin as the study area, we compared the MLR, PLSR, RF, and XGBoost algorithms. And XGBoost demonstrated the highest performance (R = 0.9130; RMSE = 0.3834%). Based on the optimal model, SOC in the study area was projected from 2020 to 2024. The multi-year average SOC exhibited an initial increase followed by a subsequent decline, with an overall increase of 22.78%. Spearman correlation analysis identified parent material as the dominant factor controlling SOC variation at the watershed scale (correlation coefficient = 0.38) while also modulating the influence of land use types on SOC dynamics. The "space-ground" multi-source collaborative inversion framework developed in this study offers a high-precision technical approach for the monitoring of SOC in black soil regions.
中国东北黑土区是全球重要的粮食生产基地。土壤有机碳(SOC)的动态变化直接关系到区域粮食安全。为了准确监测SOC含量并评估整合Landsat-9和GF-1卫星数据进行SOC反演的潜力,我们开发了一个机器学习框架,该框架结合了来自这两个卫星数据源的数据来建立SOC模型。以通肯河流域中国东北典型黑土区为研究区域,我们比较了多元线性回归(MLR)、偏最小二乘回归(PLSR)、随机森林(RF)和极端梯度提升(XGBoost)算法。结果表明,XGBoost算法性能最佳(R = 0.9130;RMSE = 0.3834%)。基于最优模型,对研究区域2020年至2024年的SOC进行了预测。多年平均SOC呈先增加后下降趋势,总体增加了22.78%。Spearman相关性分析表明,母质是控制流域尺度SOC变化的主导因素(相关系数 = 0.38),同时也调节了土地利用类型对SOC动态的影响。本研究构建的“天地”多源协同反演框架为黑土区SOC监测提供了一种高精度技术方法。
